CN203743911U - Light-emitting apparatus, bulb lamp and lighting apparatus - Google Patents
Light-emitting apparatus, bulb lamp and lighting apparatus Download PDFInfo
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- CN203743911U CN203743911U CN201390000101.8U CN201390000101U CN203743911U CN 203743911 U CN203743911 U CN 203743911U CN 201390000101 U CN201390000101 U CN 201390000101U CN 203743911 U CN203743911 U CN 203743911U
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21K—NON-ELECTRIC LIGHT SOURCES USING LUMINESCENCE; LIGHT SOURCES USING ELECTROCHEMILUMINESCENCE; LIGHT SOURCES USING CHARGES OF COMBUSTIBLE MATERIAL; LIGHT SOURCES USING SEMICONDUCTOR DEVICES AS LIGHT-GENERATING ELEMENTS; LIGHT SOURCES NOT OTHERWISE PROVIDED FOR
- F21K9/00—Light sources using semiconductor devices as light-generating elements, e.g. using light-emitting diodes [LED] or lasers
- F21K9/20—Light sources comprising attachment means
- F21K9/23—Retrofit light sources for lighting devices with a single fitting for each light source, e.g. for substitution of incandescent lamps with bayonet or threaded fittings
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21V—FUNCTIONAL FEATURES OR DETAILS OF LIGHTING DEVICES OR SYSTEMS THEREOF; STRUCTURAL COMBINATIONS OF LIGHTING DEVICES WITH OTHER ARTICLES, NOT OTHERWISE PROVIDED FOR
- F21V19/00—Fastening of light sources or lamp holders
- F21V19/001—Fastening of light sources or lamp holders the light sources being semiconductors devices, e.g. LEDs
- F21V19/003—Fastening of light source holders, e.g. of circuit boards or substrates holding light sources
- F21V19/0045—Fastening of light source holders, e.g. of circuit boards or substrates holding light sources by tongue and groove connections, e.g. dovetail interlocking means fixed by sliding
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21V—FUNCTIONAL FEATURES OR DETAILS OF LIGHTING DEVICES OR SYSTEMS THEREOF; STRUCTURAL COMBINATIONS OF LIGHTING DEVICES WITH OTHER ARTICLES, NOT OTHERWISE PROVIDED FOR
- F21V3/00—Globes; Bowls; Cover glasses
- F21V3/02—Globes; Bowls; Cover glasses characterised by the shape
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21Y—INDEXING SCHEME ASSOCIATED WITH SUBCLASSES F21K, F21L, F21S and F21V, RELATING TO THE FORM OR THE KIND OF THE LIGHT SOURCES OR OF THE COLOUR OF THE LIGHT EMITTED
- F21Y2105/00—Planar light sources
- F21Y2105/10—Planar light sources comprising a two-dimensional array of point-like light-generating elements
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21Y—INDEXING SCHEME ASSOCIATED WITH SUBCLASSES F21K, F21L, F21S and F21V, RELATING TO THE FORM OR THE KIND OF THE LIGHT SOURCES OR OF THE COLOUR OF THE LIGHT EMITTED
- F21Y2105/00—Planar light sources
- F21Y2105/10—Planar light sources comprising a two-dimensional array of point-like light-generating elements
- F21Y2105/12—Planar light sources comprising a two-dimensional array of point-like light-generating elements characterised by the geometrical disposition of the light-generating elements, e.g. arranging light-generating elements in differing patterns or densities
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21Y—INDEXING SCHEME ASSOCIATED WITH SUBCLASSES F21K, F21L, F21S and F21V, RELATING TO THE FORM OR THE KIND OF THE LIGHT SOURCES OR OF THE COLOUR OF THE LIGHT EMITTED
- F21Y2107/00—Light sources with three-dimensionally disposed light-generating elements
- F21Y2107/90—Light sources with three-dimensionally disposed light-generating elements on two opposite sides of supports or substrates
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F21—LIGHTING
- F21Y—INDEXING SCHEME ASSOCIATED WITH SUBCLASSES F21K, F21L, F21S and F21V, RELATING TO THE FORM OR THE KIND OF THE LIGHT SOURCES OR OF THE COLOUR OF THE LIGHT EMITTED
- F21Y2115/00—Light-generating elements of semiconductor light sources
- F21Y2115/10—Light-emitting diodes [LED]
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L2224/00—Indexing scheme for arrangements for connecting or disconnecting semiconductor or solid-state bodies and methods related thereto as covered by H01L24/00
- H01L2224/01—Means for bonding being attached to, or being formed on, the surface to be connected, e.g. chip-to-package, die-attach, "first-level" interconnects; Manufacturing methods related thereto
- H01L2224/42—Wire connectors; Manufacturing methods related thereto
- H01L2224/44—Structure, shape, material or disposition of the wire connectors prior to the connecting process
- H01L2224/45—Structure, shape, material or disposition of the wire connectors prior to the connecting process of an individual wire connector
- H01L2224/45001—Core members of the connector
- H01L2224/45099—Material
- H01L2224/451—Material with a principal constituent of the material being a metal or a metalloid, e.g. boron (B), silicon (Si), germanium (Ge), arsenic (As), antimony (Sb), tellurium (Te) and polonium (Po), and alloys thereof
- H01L2224/45138—Material with a principal constituent of the material being a metal or a metalloid, e.g. boron (B), silicon (Si), germanium (Ge), arsenic (As), antimony (Sb), tellurium (Te) and polonium (Po), and alloys thereof the principal constituent melting at a temperature of greater than or equal to 950°C and less than 1550°C
- H01L2224/45144—Gold (Au) as principal constituent
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L2224/00—Indexing scheme for arrangements for connecting or disconnecting semiconductor or solid-state bodies and methods related thereto as covered by H01L24/00
- H01L2224/01—Means for bonding being attached to, or being formed on, the surface to be connected, e.g. chip-to-package, die-attach, "first-level" interconnects; Manufacturing methods related thereto
- H01L2224/42—Wire connectors; Manufacturing methods related thereto
- H01L2224/47—Structure, shape, material or disposition of the wire connectors after the connecting process
- H01L2224/48—Structure, shape, material or disposition of the wire connectors after the connecting process of an individual wire connector
- H01L2224/4805—Shape
- H01L2224/4809—Loop shape
- H01L2224/48091—Arched
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L2224/00—Indexing scheme for arrangements for connecting or disconnecting semiconductor or solid-state bodies and methods related thereto as covered by H01L24/00
- H01L2224/73—Means for bonding being of different types provided for in two or more of groups H01L2224/10, H01L2224/18, H01L2224/26, H01L2224/34, H01L2224/42, H01L2224/50, H01L2224/63, H01L2224/71
- H01L2224/732—Location after the connecting process
- H01L2224/73251—Location after the connecting process on different surfaces
- H01L2224/73265—Layer and wire connectors
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L2924/00—Indexing scheme for arrangements or methods for connecting or disconnecting semiconductor or solid-state bodies as covered by H01L24/00
- H01L2924/0001—Technical content checked by a classifier
- H01L2924/00011—Not relevant to the scope of the group, the symbol of which is combined with the symbol of this group
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L2924/00—Indexing scheme for arrangements or methods for connecting or disconnecting semiconductor or solid-state bodies as covered by H01L24/00
- H01L2924/15—Details of package parts other than the semiconductor or other solid state devices to be connected
- H01L2924/181—Encapsulation
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L33/00—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L33/48—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof characterised by the semiconductor body packages
- H01L33/50—Wavelength conversion elements
- H01L33/505—Wavelength conversion elements characterised by the shape, e.g. plate or foil
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01L—SEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
- H01L33/00—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof
- H01L33/48—Semiconductor devices having potential barriers specially adapted for light emission; Processes or apparatus specially adapted for the manufacture or treatment thereof or of parts thereof; Details thereof characterised by the semiconductor body packages
- H01L33/50—Wavelength conversion elements
- H01L33/507—Wavelength conversion elements the elements being in intimate contact with parts other than the semiconductor body or integrated with parts other than the semiconductor body
Landscapes
- Engineering & Computer Science (AREA)
- Physics & Mathematics (AREA)
- Microelectronics & Electronic Packaging (AREA)
- Optics & Photonics (AREA)
- General Engineering & Computer Science (AREA)
- Led Device Packages (AREA)
- Fastening Of Light Sources Or Lamp Holders (AREA)
- Non-Portable Lighting Devices Or Systems Thereof (AREA)
Abstract
A light-emitting apparatus is provided with a substrate (21), a plurality of first light-emitting elements (LED(22a)), a first wavelength conversion member (WC1), and a second wavelength conversion member (WC2). The first light-emitting elements (LED(22a)) are arranged in a row on the substrate (21); the first wavelength conversion member (WC1) is arranged on the substrate (21) in a linear shape and converts the wavelength of light emitted by the first light-emitting elements; the second wavelength conversion member (WC2) arranged on the substrate (21) in a linear shape is parallel to the first wavelength conversion member (WC1) and converts the wavelength of light emitted by first light-emitting elements; the first light-emitting elements are arranged in the first wavelength conversion member (WC1); light-emitting elements that can emit light of which the wavelength is converted by the second wavelength conversion member (WC2) are not arranged in the second wavelength conversion member (WC2).
Description
Technical field
The utility model relates to light-emitting device, bulb-shaped lamp and lighting device, for example, relate to the light-emitting device that has used semiconductor light-emitting elements, and has used bulb-shaped lamp and the lighting device of this light-emitting device.
Background technology
The semiconductor light-emitting elements such as LED (Light Emitting Diode: light emitting diode) are owing to having feature efficient and that the life-span is long, therefore wait in expectation and can serve as the new light source of various lamps, the research and development of the LED lamp using LED as light source are also in continuous progress.
There is the LED lamp (bulb-shaped LED lamp) of the bulb-shaped of replacement bulb shape fluorescent lamp or incandescent lamp bulb as LED lamp, or the LED lamp of the Straight of alternative straight-pipe fluorescent lamp (Straight LED lamp) etc.For example, bulb-shaped LED lamp is in the past disclosed in patent documentation 1.And, Straight LED lamp is in the past disclosed in patent documentation 2.
In LED lamp, adopt the LED module (light-emitting device) that multiple LED are installed on substrate as light source.
(prior art document)
(patent documentation)
Patent documentation 1 TOHKEMY 2006-313717 communique
Patent documentation 2 TOHKEMY 2009-043447 communiques
Brief summary of the invention
The problem that invention will solve
Inquiring in recent years in the characteristics of luminescence and imitating in appearance the bulb-shaped LED lamp of the formation of incandescent lamp bulb.For example, the formation of a kind of bulb-shaped LED lamp of proposition is to use the enclosed globe shade (glass bulb) of the hollow adopting in incandescent lamp bulb, and LED module is remained on to the center in this enclosed globe shade.For example, adopt from the opening of enclosed globe shade and extend to the center of enclosed globe shade the pillar (plug) arranging, LED module is fixed on to the top of this pillar.LED module for example possesses: substrate, be arranged on surperficial multiple LED chips of substrate and many of sealing in the lump for every row LED chip containing fluorophor resin (wire resin) with multiple row.
But needing in bulb-shaped lamp has higher light beam, therefore studying more LED chip is being installed.Can there is heat from LED chip self because of luminous in LED chip, it will cause the temperature rise of LED chip, like this, not only can cause the light output of LED chip reduce but also can cause the life-span to reduce.Therefore, need the heat expeditiously LED chip being occurred to dispel the heat at LED module.In this case, the area of the substrate of LED chip can be installed by increase, guarantee the thermal diffusivity of LED module.
But, if be only the area that increases substrate, except the region (non-illuminating part) containing the region (illuminating part) of fluorophor resin that is formed for sealing LED chip will increase, thereby the problem of appearance is on substrate, occur significantly forming the region (illuminating part) containing fluorophor resin of sealing LED chip and do not have formation poor containing the light and shade between the region (non-illuminating part) of fluorophor resin.
Especially the wire for sealing LED chip containing fluorophor resin be formed many on substrate in the situation that, if the area of substrate is increased, two of wire intervals containing fluorophor resin broaden, thereby occur brightness irregularities.Therefore,, if this LED module is used as to the light source of the bulb-shaped lamp of above-mentioned formation, the inhomogeneous meeting of the brightness of light source becomes remarkable.
Utility model content
First object of the present utility model is, a kind of poor light-emitting device, bulb-shaped lamp and lighting device of light and shade that can suppress on substrate is provided.
And, LED light fixture in the past has seal member wavelength conversion layer, that contain fluorophor converting as the light wavelength that LED is sent, by LED being sealed with seal member, the blue light for example sending from LED becomes white light and is penetrated via seal member.The characteristic having in this fluorophor is that the conversion efficiency in the time of temperature rise, this light wavelength being converted reduces.
At this, in the situation that LED light fixture has dimming function, control the light modulation of LED by being fed into the big or small variation of electric current of LED.,, when this light modulation is controlled, in LED, be supplied to large electric current or little electric current.Like this, be supplied to large electric current in LED, owing to there is heat from LED, therefore this heat can cause the conversion efficiency of fluorophor to reduce.Therefore,, in the light modulation of LED controlled, the color of the light penetrating from seal member changes.
As previously discussed, in LED lamp in the past, be that the color of the light of ejaculation changes in light modulation by the problem occurring in controlling.
Second object of the present utility model is, even if provide a kind of in the controlled situation of light modulation, light-emitting device, bulb-shaped lamp and the lighting device that also can control the variation of the color of the light penetrating.
The adopted means of dealing with problems
In order to reach the first above-mentioned object, an embodiment of related the first light-emitting device of the utility model is to possess: substrate; The first light-emitting component, is configured on described substrate; The first wavelength transform component, is arranged on described substrate, and the light wavelength that described the first light-emitting component is sent converts; And second wave length transform component, with the adjacent setting of described the first wavelength transform component, the light wavelength that described the first light-emitting component is sent converts, in described the first wavelength transform component, there is described the first light-emitting component, in described second wave length transform component, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by this second wave length transform component.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, described the first light-emitting component, on described substrate, be configured with multiplely with row shape, described the first wavelength transform component is configured to wire on described substrate, described second wave length transform component is configured to side by side wire with described the first wavelength transform component on described substrate.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, described the first wavelength transform component comprises the first wavelength shifter and comprises the first seal member of this first wavelength shifter, the light wavelength that described the first wavelength shifter is sent multiple described the first light-emitting components converts, described the first seal member is configured to wire, and multiple described the first light-emitting components are sealed in the lump, described second wave length transform component comprises second wave length coversion material and comprises the first illusory seal member of this second wave length coversion material, the light wavelength that described second wave length coversion material sends multiple described the first light-emitting components converts.
And, also can be, an embodiment of related the first light-emitting device of the utility model is that the concentration of the described second wave length coversion material in described the first illusory seal member is, below the concentration of described the first wavelength shifter in described the first seal member.
And, can be also that an embodiment of related the first light-emitting device of the utility model is that the length of described the first illusory seal member is, below the length of described the first seal member.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, described the first wavelength shifter and described second wave length coversion material are fluorophor particle, and described the first seal member and described the first illusory seal member are resin.
And, can be also that an embodiment of related the first light-emitting device of the utility model is to have non-luminous electronic component in described the first illusory seal member.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, it is semicircle that the shape of this first wavelength transform component in the section vertical with the length direction of described the first wavelength transform component is essentially, multiple described the first light-emitting components are configured to row, and each of multiple described the first light-emitting components is located substantially on the center of the width of described the first wavelength transform component.
And, can be also that an embodiment of related the first light-emitting device of the utility model is that this light-emitting device also possesses: multiple the second light-emitting components along the column direction of multiple described the first light-emitting components, are configured shape in column on described substrate; And three-wavelength transform component, on described substrate, be configured to wire, the light wavelength that multiple described the second light-emitting components are sent converts, in described three-wavelength transform component, there are multiple described the second light-emitting components, described second wave length transform component is arranged between described the first wavelength transform component and described three-wavelength transform component, and the light wavelength of also multiple described the second light-emitting components being sent converts.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, described the first wavelength transform component comprises the first wavelength shifter and comprises the first seal member of this first wavelength shifter, the light wavelength that described the first wavelength shifter is sent multiple described the first light-emitting components converts, described the first seal member is configured to wire, and multiple described the first light-emitting components are sealed in the lump, described second wave length transform component comprises second wave length coversion material and comprises the first illusory seal member of this second wave length coversion material, the light wavelength that described second wave length coversion material sends multiple described the first light-emitting components and multiple described the second light-emitting component converts, described three-wavelength transform component comprises three-wavelength coversion material and the second seal member that comprises this three-wavelength coversion material, the light wavelength that described three-wavelength coversion material sends multiple described the second light-emitting components converts, described the second seal member is configured to wire, and multiple described the second light-emitting components are sealed in the lump.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, multiple described the first light-emitting components and multiple described the second light-emitting component are the light-emitting components that can send the light of same color, the concentration of the described second wave length coversion material in described the first illusory seal member is, below the concentration of described the first wavelength shifter in described the first seal member, and below the concentration of described three-wavelength coversion material in described the second seal member.
And, also can be, an embodiment of related the first light-emitting device of the utility model is that the concentration of described the first wavelength shifter in described the first seal member is almost consistent with the concentration of the described three-wavelength coversion material in described the second seal member.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, described the first wavelength shifter, described second wave length coversion material and described three-wavelength coversion material are fluorophor particle, and described the first seal member, described the first illusory seal member and described the second seal member are resin.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, it is semicircle that the shape of this first wavelength transform component in the section vertical with the length direction of described the first wavelength transform component is essentially, it is semicircle that the shape of this three-wavelength transform component in the section vertical with the length direction of described three-wavelength transform component is essentially, multiple described the first light-emitting components and multiple described the second light-emitting component are configured to respectively row, each of multiple described the first light-emitting components is located substantially on the center of the width of described the first wavelength transform component, each of multiple described the second light-emitting components is located substantially on the center of the width of described three-wavelength transform component.
And, also can be that an embodiment of related the first light-emitting device of the utility model is that this light-emitting device also possesses: multiple the 3rd light-emitting components and multiple the 4th light-emitting component, along the column direction of multiple described the second light-emitting components, on described substrate, be configured shape in column, the 4th wavelength conversion parts, adjacent with described three-wavelength transform component and on described substrate, be arranged to wire, the light wavelength that multiple described the 3rd light-emitting components are sent converts, the 5th wavelength conversion parts are configured to side by side wire with described the 4th wavelength conversion parts on described substrate, and the light wavelength that multiple described the 3rd light-emitting components and multiple described the 4th light-emitting component are sent converts, and the 6th wavelength conversion parts, adjacent with described the 5th wavelength conversion parts and on described substrate, be arranged to wire, the light wavelength that multiple described the 4th light-emitting components are sent converts, in described the 4th wavelength conversion parts, there are multiple described the 3rd light-emitting components, in described the 6th wavelength conversion parts, there are multiple described the 4th light-emitting components, described the 5th wavelength conversion parts are arranged between described the 4th wavelength conversion parts and described the 6th wavelength conversion parts, in described the 5th wavelength conversion parts, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by the 5th wavelength conversion parts.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, described the 4th wavelength conversion parts comprise the 4th wavelength shifter and comprise the 3rd seal member of the 4th wavelength shifter, the light wavelength that described the 4th wavelength shifter is sent multiple described the 3rd light-emitting components converts, described the 3rd seal member is configured to wire, and multiple described the 3rd light-emitting components are sealed in the lump, described the 5th wavelength conversion parts comprise the 5th wavelength shifter and comprise the second illusory seal member of the 5th wavelength shifter, the light wavelength that described the 5th wavelength shifter is sent multiple described the 3rd light-emitting components and multiple described the 4th light-emitting component converts, described the 6th wavelength conversion parts comprise the 6th wavelength shifter and comprise the 4th seal member of the 6th wavelength shifter, the light wavelength that described the 6th wavelength shifter is sent multiple described the 4th light-emitting components converts, described the 4th seal member is configured to wire, and multiple described the 4th light-emitting components are sealed in the lump.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, this light-emitting device also possesses the 7th wavelength conversion parts, the 7th wavelength conversion parts are arranged between described three-wavelength transform component and described the 4th wavelength conversion parts, described the 7th wavelength conversion parts comprise the 7th wavelength shifter and comprise the 3rd illusory seal member of the 7th wavelength shifter, the light wavelength that described the 7th wavelength shifter is sent multiple described the second light-emitting components and multiple described the 3rd light-emitting component converts, in described the 7th wavelength conversion parts, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by the 7th wavelength conversion parts.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, this light-emitting device also possesses the 8th wavelength conversion parts, the 8th wavelength conversion parts are arranged at least both sides of the length direction of one of them of following wavelength conversion parts, these wavelength conversion parts refer to: described the first wavelength transform component, described three-wavelength transform component, described the 4th wavelength conversion parts, and described the 6th wavelength conversion parts, described the 8th wavelength conversion parts comprise the 8th wavelength shifter and comprise the 4th illusory seal member of the 8th wavelength shifter, the 8th wavelength shifter converts at least one of them light wavelength of sending of following light-emitting component, these light-emitting components refer to: multiple described the first light-emitting components, multiple described the second light-emitting components, multiple described the 3rd light-emitting components, and multiple described the 4th light-emitting components, in described the 8th wavelength conversion parts, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by the 8th wavelength conversion parts.
And, in order to reach second object, an embodiment of related the first light-emitting device of the utility model is, described the first wavelength transform component with cover described the first light-emitting component at least a portion mode and be configured, described second wave length transform component is configured in, compared with described the first wavelength transform component, on the position away from described the first light-emitting component, described the first light-emitting component is modulated light by the big or small variation of the electric current being supplied to, the second wave length converted quantity of the degree that the light wavelength that described the first light-emitting component is sent in described second wave length transform component converts is shown, the first wavelength converted quantity of the degree converting than the light wavelength that described the first light-emitting component is sent illustrating in described the first wavelength transform component is large.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, described the first wavelength transform component is the seal member that described the first light-emitting component is sealed, and described second wave length transform component is the resin that is configured in the side of described the first wavelength transform component on described substrate.
And, can be also, an embodiment of related the first light-emitting device of the utility model is, the first wavelength transform component is high described in the concentration ratio of the contained fluorophor particle of described second wave length transform component.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, described substrate has light transmission, described light-emitting device also possesses three-wavelength transform component, and this three-wavelength transform component is the luminescent coating being formed between described substrate and described the first light-emitting component, and described three-wavelength transform component is constituted as, more, away from described the first light-emitting component, the light wavelength converted quantity that described the first light-emitting component sends is just larger.
And, can be also, an embodiment of related the first light-emitting device of the utility model is, and described three-wavelength transform component is constituted as, and more away from described the first light-emitting component, the thickness of this three-wavelength transform component is just thicker.
And, also can be that an embodiment of related the first light-emitting device of the utility model is that described three-wavelength transform component is constituted as, more away from described the first light-emitting component, the concentration of the contained fluorophor particle of this three-wavelength transform component is just higher.
And, also can be, an embodiment of related the first light-emitting device of the utility model is, described substrate has light transmission, described the first wavelength transform component and described second wave length transform component are between described substrate and described the first light-emitting component, to be formed the luminescent coating of one.
And, can be also, an embodiment of related the first light-emitting device of the utility model is, the first wavelength transform component is thick described in the Thickness Ratio of described second wave length transform component.
And, can be also, an embodiment of related the first light-emitting device of the utility model is, the concentration of the contained fluorophor particle of described second wave length transform component is higher than described the first wavelength transform component.
And an embodiment of related the first bulb-shaped lamp of the utility model is to possess: above-mentioned any the first light-emitting device と, the enclosed globe shade of light transmission; And extending to the inner space of described enclosed globe shade the pillar arranging, described light-emitting device is configured in described enclosed globe shade, and is fixed on described pillar.
And, also can be, an embodiment of related the first bulb-shaped lamp of the utility model is, be positioned at the mode of top one side of described enclosed globe shade with the first surface of described substrate, described light-emitting device is fixed on described pillar, and the first surface of described substrate refers to the face that is equipped with multiple described the first light-emitting components.
And, can be also, in an embodiment of the first related bulb-shaped lamp of the utility model, to possess: the first above-mentioned light-emitting device that comprises the 8th wavelength conversion parts; The enclosed globe shade of light transmission; And extend to the inner space of described enclosed globe shade the pillar arranging, described the first light-emitting device is configured in described enclosed globe shade, and be fixed on described pillar, described the first light-emitting device also possesses: multiple the 5th light-emitting components, be configured in second of described substrate with row shape, the second face of described substrate is and the face of the contrary side of described first surface of described substrate; And the 9th wavelength conversion parts, being configured to wire at described the second face, the light wavelength that multiple described the 5th light-emitting components are sent converts, and has multiple described the 5th light-emitting components in described the 9th wavelength conversion parts.
And, also can be, an embodiment of related the first bulb-shaped lamp of the utility model is, described light-emitting device also possesses the tenth wavelength conversion parts, the tenth wavelength conversion parts are configured to side by side wire with described the 9th wavelength conversion parts on described second, the light wavelength that multiple described the 5th light-emitting components are sent converts, in described the tenth wavelength conversion parts, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by the tenth wavelength conversion parts.
And, also can be, in an embodiment of the first related bulb-shaped lamp of the utility model, described the 9th wavelength conversion parts comprise the 9th wavelength shifter and comprise the 5th seal member of the 9th wavelength shifter, the light wavelength that described the 9th wavelength shifter is sent multiple described the 5th light-emitting components converts, described the 5th seal member is configured to wire, and multiple described the 5th light-emitting components are sealed in the lump, described the tenth wavelength conversion parts comprise the tenth wavelength shifter and comprise the 5th illusory seal member of the tenth wavelength shifter, the light wavelength that described the tenth wavelength shifter is sent multiple described the 5th light-emitting components converts.
And, also can be, in an embodiment of the first related bulb-shaped lamp of the utility model, described substrate is made up of main substrate and auxiliary substrate, the surface of described main substrate is provided with multiple described the first light-emitting components, the surface of described auxiliary substrate is provided with multiple described the 5th light-emitting components, described main substrate and described auxiliary substrate are configured to, the back side of described main substrate is relative with the back side of described auxiliary substrate, the back side of described main substrate refers to the face that multiple described the first light-emitting components are not set, the back side of described auxiliary substrate refers to the face that multiple described the 5th light-emitting components are not set.
And an embodiment of related the first lighting device of the utility model is to possess any above-mentioned first bulb-shaped lamp.
In order to reach second above-mentioned object, an embodiment of related the second light-emitting device of the utility model is to possess: substrate; Be configured in the light-emitting component on described substrate; The first wavelength transformation component, with cover described light-emitting component at least a portion mode and be configured, the light wavelength that described light-emitting component is sent converts; Second wave length transformation component, be configured in compared with described the first wavelength transformation component, on the position away from described light-emitting component, and the light wavelength that described light-emitting component is sent converts, described light-emitting component has the big or small variation of electric current that is supplied to and modulated light, the second wave length converted quantity that the degree that the light wavelength that described light-emitting component is sent in described second wave length transformation component converts is shown, the first wavelength converted quantity of the degree converting than the light wavelength that described light-emitting component is sent illustrating in described the first wavelength transformation component is large.
And, also can be, an embodiment of related the second light-emitting device of the utility model is, described the first wavelength transformation component is the seal member that described the first light-emitting component is sealed, and described second wave length transformation component is the resin that is configured in the side of described the first wavelength transformation component on described substrate.
And, can be also that, in an embodiment of the second related light-emitting device of the utility model, the first wavelength transformation component is high described in the concentration ratio of the contained fluorophor particle of described second wave length transformation component.
And, also can be, in an embodiment of the second related light-emitting device of the utility model, described substrate has light transmission, described light-emitting device also possesses three-wavelength transformation component, and this three-wavelength transformation component is the luminescent coating being formed between described substrate and described light-emitting component, and described three-wavelength transformation component is constituted as, more, away from described the first light-emitting component, the light wavelength converted quantity that described the first light-emitting component sends is just larger.
And, can be also, in an embodiment of the second related light-emitting device of the utility model, described three-wavelength transformation component is constituted as, and more away from described the first light-emitting component, the thickness of this three-wavelength transform component is just thicker.
And, also can be that, in an embodiment of the second related light-emitting device of the utility model, described three-wavelength transformation component is constituted as, more away from described the first light-emitting component, the concentration of the contained fluorophor particle of this three-wavelength transform component is just higher.
And, also can be that, in an embodiment of the second related light-emitting device of the utility model, described substrate has light transmission, described the first wavelength transformation component and described second wave length transformation component are between described substrate and described light-emitting component, to be formed the luminescent coating of one.
And, can be also that, in an embodiment of the second related light-emitting device of the utility model, the first wavelength transformation component is thick described in the Thickness Ratio of described second wave length transformation component.
And, can be also that, in an embodiment of the second related light-emitting device of the utility model, the first wavelength transformation component is high described in the concentration ratio of the contained fluorophor particle of described second wave length transformation component.
And, can be also in an embodiment of second related bulb-shaped lamp of the utility model, to possess: above-mentioned any the second light-emitting device; The enclosed globe shade of hollow, for receiving described the second light-emitting device; Lamp holder, accepts for making the luminous electric power of described the second light-emitting device; And drive circuit, the electric power of being accepted by described lamp holder is supplied to described light-emitting component, and described light-emitting component is carried out to light modulation.
And an embodiment of related the second lighting device of the utility model is to possess above-mentioned bulb-shaped lamp.
Invention effect
By the embodiment separately of the first related light-emitting device of the utility model, the first bulb-shaped lamp and the first lighting device, can suppress light and shade on the substrate of the first light-emitting device poor.
By the embodiment separately of the second related light-emitting device of the utility model, the second bulb-shaped lamp and the second lighting device, even in the controlled situation of light modulation, also can suppress the variation of the color of the light being penetrated.
Brief description of the drawings
Fig. 1 is the side view of the related bulb-shaped lamp of embodiment 1 of the present utility model.
Fig. 2 is the decomposition diagram of the related bulb-shaped lamp of embodiment 1 of the present utility model.
Fig. 3 is the profile of the related bulb-shaped lamp of embodiment 1 of the present utility model.
Fig. 4 shows the formation of the LED module in the related bulb-shaped lamp of embodiment 1 of the present utility model, (a) is top view, (b), (c), (d) and (e) be profile.
Fig. 5 is the amplification profile of the LED in the LED module of the related bulb-shaped lamp of embodiment 1 of the present utility model.
Fig. 6 shows the formation of the LED module periphery in the related bulb-shaped lamp of embodiment 1 of the present utility model, (a) is top view, is (b) and (c) profile.
Fig. 7 is the figure of the action effect of the LED module for the related bulb-shaped lamp of embodiment 1 of the present utility model is described, (a) be a part of amplification profile of the LED module of comparative example 1, (b) be a part of amplification profile of the LED module of comparative example 2, (c) be the amplification profile of a part for the LED module in embodiment 1.
Fig. 8 A is the plane of the LED module in the related bulb-shaped lamp of the variation 1 of embodiment 1 of the present utility model.
Fig. 8 B is the plane of the LED module in the related bulb-shaped lamp of the variation 2 of embodiment 1 of the present utility model.
Fig. 9 shows the formation of the LED module periphery in the related bulb-shaped lamp of the variation 3 of embodiment 1 of the present utility model, (a) is top view, (b), (c) and (d) be profile.
Figure 10 shows the formation of the LED module periphery in the related bulb-shaped lamp of the variation 4 of embodiment 1 of the present utility model, (a) is top view, (b), (c) and (d) be profile.
Figure 11 is the outward appearance perspective view of the related bulb-shaped lamp of embodiment 2 of the present utility model.
Figure 12 is the decomposition diagram of the related bulb-shaped lamp of embodiment 2 of the present utility model.
Figure 13 shows a section of the formation of the related bulb-shaped lamp of embodiment 2 of the present utility model.
Figure 14 shows other section of the formation of the related bulb-shaped lamp of embodiment 2 of the present utility model.
Figure 15 shows the formation of the related LED module of embodiment 2 of the present utility model, (a) is top view, is (b) profile.
Figure 16 is a part of amplification profile of the formation of seal member in the related LED module of embodiment 2 of the present utility model and wavelength conversion parts.
Figure 17 is the figure for the effect that the related LED module of embodiment 2 of the present utility model realizes is described.
Figure 18 shows the formation of the related LED module of the variation 1 of embodiment 2 of the present utility model, (a) is top view, is (b) profile.
Figure 19 is the amplification profile of the LED Zhou side in the related LED module of the variation 1 of embodiment 2 of the present utility model.
Figure 20 is the amplification profile of the major part of the related LED module of the variation 1 of embodiment 2 of the present utility model.
Figure 21 is the figure of the effect that realizes of the related LED module of variation 1 for embodiment 2 of the present utility model is described.
Figure 22 shows the formation of the related LED module of the variation 2 of embodiment 2 of the present utility model, (a) is top view, is (b) profile.
Figure 23 is the amplification profile of the major part of the related LED module of the variation 2 of embodiment 2 of the present utility model.
Figure 24 is the amplification profile of the major part of the related LED module of the variation 3 of embodiment 2 of the present utility model.
Figure 25 is the amplification profile of the major part of the related LED module of the variation 4 of embodiment 2 of the present utility model.
Figure 26 shows the formation of the related LED module of variation 1 of the present utility model, (a) is plane, is (b) profile on the A-A ' line of (a).
Figure 27 is the figure of the assemble method for the related LED module of variation 1 of the present utility model is described.
Figure 28 is the perspective view that the formation of the related LED module of variation 2 of the present utility model is shown.
Figure 29 is other the plane of formation of first example that the related LED module of variation 2 of the present utility model is shown.
Figure 30 is other the plane of formation of second example that the related LED module of variation 2 of the present utility model is shown.
Figure 31 is other the plane of formation of the 3rd example that the related LED module of variation 2 of the present utility model is shown.
Figure 32 is other the plane of formation of the 4th example that the related LED module of variation 2 of the present utility model is shown.
Figure 33 is the profile that the formation of first example of the related LED module of other variation of the present utility model is shown.
Figure 34 is the profile that the formation of second example of the related LED module of other variation of the present utility model is shown.
Figure 35 is the profile that the formation of the 3rd example of the related LED module of other variation of the present utility model is shown.
Figure 36 is the profile of the related bulb-shaped lamp of other variation of embodiment 1 of the present utility model.
Figure 37 is the summary section of the related lighting device of embodiment of the present utility model.
Detailed description of the invention
Below utilize accompanying drawing to be described in detail embodiment of the present utility model.And below the embodiment of explanation is a preferred example of the present utility model.Allocation position and the connected mode etc. of the numerical value shown in following embodiment, shape, material, inscape, inscape is an example, is not to limit purport of the present utility model.Therefore,, for the inscape of not recording in the independent claims that upper concept of the present utility model is shown among the inscape in following each embodiment and variation, illustrate as inscape arbitrarily.
And each figure is ideograph, it is not rigorous diagram.And, in each figure, give identical symbol for being essentially identical component parts, and the repetitive description thereof will be omitted or simplify.
(embodiment 1)
Below embodiment 1 of the present utility model is described.
[entirety of bulb-shaped lamp forms]
First, referring to figs. 1 through Fig. 3, the entirety of the related bulb-shaped lamp 1 of embodiment 1 of the present utility model is formed and described.
Fig. 1 is the side view of the related bulb-shaped lamp of present embodiment 1.Fig. 2 is the decomposition diagram of the related bulb-shaped lamp of present embodiment 1.Fig. 3 is the profile of the related bulb-shaped lamp of present embodiment 1.
And in Fig. 2 and Fig. 3, the top of paper is the front (top) of bulb-shaped lamp 1, the below of paper is the rear (below) of bulb-shaped lamp 1, and the left and right of paper is the side of bulb-shaped lamp 1.At this, in this manual, " rear " refer to, taking the substrate of LED module as benchmark, the direction of lamp holder one side, " front " refer to, taking the substrate of LED module as benchmark, the direction of a side contrary to lamp holder, " side " refer to, with the direction of the main surface parallel of the substrate of LED module.And in Fig. 3, the chain-dotted line of drawing along the above-below direction of paper represents the lamp axle J (central shaft) of bulb-shaped lamp 1.Lamp axle J refers to, becomes the axle of pivot in the time bulb-shaped lamp 1 being installed to the socket of lighting device (not shown), consistent with the rotating shaft of lamp holder.And the definition of above-mentioned direction and bulb-shaped lamp 1 are installed to the orientation independent while lighting a lamp utensil, be installed to light a lamp utensil in the situation that at bulb-shaped lamp 1, no matter which direction all can above or below becoming.The definition of this direction is also same later.
Bulb-shaped lamp 1 is the bulb-shaped LED lamp (LED bulb) that becomes the substitute of replacement bulb shape fluorescent lamp or incandescent lamp bulb.Bulb-shaped lamp 1 possesses: the enclosed globe shade 10 of light transmission, as the LED module 20 of light source, the lamp holder 30 of accepting electric power from lamp outside, pillar 40, supporting station 50, resin enclosure 60, lead-in wire 70 and lamp circuit 80.
Bulb-shaped lamp 1 has formed peripheral device by enclosed globe shade 10, resin enclosure 60 (the first housing department 61), lamp holder 30.And the formation of the bulb-shaped lamp 1 in present embodiment is that the brightness that is equivalent to 60W shape is suitable.
Below, each inscape of the related bulb-shaped lamp 1 of present embodiment is elaborated.
[enclosed globe shade]
Enclosed globe shade 10 is for receiving LED module 20, and is to make the light transmission cover to lamp outside from the light printing opacity of LED module 20.Incide the light of the LED module 20 of the inner surface of enclosed globe shade 10, be fetched to the outside of enclosed globe shade 10 through enclosed globe shade 10.
Enclosed globe shade 10 in present embodiment is that transparent material forms by the light for from LED module 20.Can be to be for example the glass bulb (clear lamp) of transparent fused silica system to visible ray as this enclosed globe shade 10.In this case, can be from the outside of enclosed globe shade 10 the visual LED module 20 to being incorporated in enclosed globe shade 10.
As shown in Figure 2, being shaped as of enclosed globe shade 10, one end is closed as spherical, and the other end has peristome 11.Particularly, being shaped as of enclosed globe shade 10, a part for the ball of hollow is extended and is narrowed along with the direction of the central part to away from ball, is formed with peristome 11 on the position of the central part away from ball.As the enclosed globe shade 10 of this shape, can adopt the glass bulb identical with the shape of general incandescent lamp bulb.For example, can adopt the glass bulbs such as A shape, G shape or E shape as enclosed globe shade 10.
And it is transparent that enclosed globe shade 10 also can need not to be visible ray, but can make enclosed globe shade 10 have light diffusion function.For example, the resin or the Chinese white etc. that contain silica or calcium carbonate light diffusion material are filled to inner surface or the outer surface of enclosed globe shade 10, thereby form milky optical diffusion film.And, be also not limited to glass material as the material of enclosed globe shade 10, also can adopt the resinous wood of the formations such as the synthetic resin such as propylene (PMMA) or polycarbonate (PC).
[LED module]
LED module 20 has LED (LED chip), is by carrying out luminous light emitting module (light-emitting device) by 70 electric power that are fed into LED that go between, can emitting the light of the wavelength (color) of regulation.LED module 20 is maintained in the inner space of enclosed globe shade 10 by pillar 40.
LED module 20 is preferably configured in the center (position, inner space that for example, the internal diameter of enclosed globe shade 10 is large) of the ball shape being formed by enclosed globe shade 10.Like this, by LED module 20 being configured to the center of enclosed globe shade 10, thereby the light distribution characteristic of bulb-shaped lamp 1 has become with utilization in the past the approximate light distribution characteristic of the general incandescent lamp bulb of heater winding.
In addition, treat aftermentioned for the detailed formation of LED module 20.
[lamp holder]
Lamp holder 30 is power receiving sections of accepting the luminous electric power of LED for making LED module 20 for outside from bulb-shaped lamp 1.Lamp holder 30 is accepted alternating current by two contacts, and the electric power of accepting at lamp holder 30 is imported into the electric power input part of lamp circuit 80 via lead-in wire.For example, lamp holder 30 has been supplied to alternating current from source power supply (AC100V).Particularly, lamp holder 30 is installed in the socket of ligthing paraphernalia (lighting device), and accepts alternating current from socket.Accordingly, bulb-shaped lamp 1 (LED module 20) is lit a lamp.
Lamp holder 30 is the metal end cylindrical shell shapes (lid shape) that have, the shell portion that is male thread by outer peripheral face and be installed in the contact chip portion of shell portion by insulation division.Be formed with for screwing up the portion that screws up at the socket of lighting device at the outer peripheral face of lamp holder 30, be formed with the portion that screws up for screwing up resin enclosure 60 at the inner peripheral surface of lamp holder 30.
The kind of lamp holder 30 does not have special restriction, in the present embodiment the Edison screw of screw-type (E type) lamp holder.As.Adopt lamp holder 30 for example can list E26 shape or E17 shape, or E16 shape etc.And, also can adopt plug-type lamp holder as lamp holder 30.
[pillar]
Pillar 40 is the metal plugs (metal mainstay) that nearby extend setting to the inner space of enclosed globe shade 10 from the peristome 11 of enclosed globe shade 10, has the function as the holding member at the interior maintenance LED module 20 of enclosed globe shade 10.One end of pillar 40 is connected with LED module 20, and the other end is connected with supporting station 50.
Pillar 40 plays a role as thermal component, rejects heat to lamp holder 30 1 sides for the heat that makes to occur at LED module 20.Therefore, by metal material high pyroconductivity is used as to pillar 40, for example pyroconductivity is about to 237[W/mK] aluminium (Al), copper (Cu) or iron (Fe) form pillar 40 as main component, thereby can improve radiating efficiency by pillar 40.Consequently, can suppress the luminous efficiency of the LED causing because of temperature rise and the reduction in life-span.As the metal material of pillar 40, except aluminium alloy, also can adopt copper etc.And, as pillar 40, also can form metal film on the surface of the pillar being formed by resin etc.
Pillar 40 is to be for example configured by one-body molded by main shaft part 41 and fixed part 42.Main shaft part 41 is that sectional area is certain cylindrical member.One end of main shaft part 41 is connected with fixed part 42, and the other end is connected with supporting station 50.Fixed part 42 has the stationary plane of fixed L ED module 20, and the back side of the substrate of this stationary plane and LED module 20 joins.Fixed part 42 also has the jut outstanding from stationary plane, and this jut is chimeric with the through hole of substrate that is arranged on LED module 20.LED module 20 is for example adhered by resin stickers such as silicones with the stationary plane of fixed part 42.
And in the present embodiment, the back side of the substrate 21 in LED module 20 is fixed on pillar 40 in the mode of joining with pillar 40.Accordingly, owing to can improving the radiating efficiency of LED module 20, therefore can suppress the reduction of luminous efficiency and the reduction in life-span of the LED causing because of temperature rise.
[supporting station]
Supporting station (support plate) the 50th, for the parts of support column 40, is fixed on resin enclosure 60.Supporting station 50 is connected with the openend of the peristome 11 of enclosed globe shade 10, with stop up enclosed globe shade 10 peristome 11 mode and be configured.Particularly, the disc-shaped part that supporting station 50 has stage portion by periphery forms, the openend butt of the peristome 11 of this stage portion and enclosed globe shade 10.And in this stage portion, supporting station 50 is fixed by sticker with the openend of the peristome 11 of resin enclosure 60 and enclosed globe shade 10.
Supporting station 50 is same with pillar 40, by being made up of the high metal material of the pyroconductivities such as aluminium, thereby can the hot radiating efficiency of the LED module 20 that is transmitted to pillar 40 be improved via supporting station 50.Consequently, can suppress the reduction of luminous efficiency and the reduction in life-span of the LED causing because of temperature rise.And supporting station 50 also can be one-body molded by same mould with pillar 40.
[resin enclosure]
Resin enclosure 60 is except pillar 40 and lamp holder 30 are insulated, and is the insulation crust (circuit retainer) for receiving lamp circuit 80, is made up of large footpath the first housing department 61 cylindraceous and path second housing cylindraceous portion 62.Resin enclosure 60 is for example formed by polybutylene terephthalate (PBT).
The outer surface of the first housing department 61 exposes in outside, and the heat that is transmitted to resin enclosure 60 is mainly dispelled the heat from the first housing department 61.The mode that second housing portion 62 contacts with the inner peripheral surface of lamp holder 30 with outer peripheral face and being configured, is formed with the portion that screws up for screwing up with lamp holder 30 at the outer peripheral face of second housing portion 62.
[lead-in wire]
Article two, lead-in wire 70 is that lead-in wire for the electric power that LED module 20 is lit a lamp is supplied to LED module 20 from lamp circuit 80 is right, is made up of the metal cords of the wire-shaped such as copper cash.Each lead-in wire 70 is configured in the inner space of enclosed globe shade 10, and one end is electrically connected with the outside terminal of LED module 20, and the other end is connected with the electric power efferent of lamp circuit 80, that is to say with lamp holder 30 and is electrically connected.
Article two, lead-in wire 70 is to be made up of the heart yearn of metal and the insulative resin of coated this heart yearn, for example, be vinyl line, thereby is to be connected by not being coated by insulative resin the heart yearn exposing on surface with the electrical connection of LED module 20.Now, can be also that it is coated that two lead-in wires 70 be can't help insulative resin from the outstanding part in the surface of substrate 21 and the heart yearn of the part below the outstanding 3mm in the back side from substrate 21.
In addition, treat about lead-in wire 70 and the annexation of LED module after detailed description.
[lamp circuit]
Lamp circuit 80 is drive circuits (circuit unit) that the LED for making LED module 20 lights a lamp, and is covered by resin enclosure 60.Lamp circuit 80 comprises for being converted to galvanic circuit by supply with the alternating current coming from lamp holder 30, by two lead-in wires 70, the direct current after conversion is supplied to the LED of LED module 20.
Lamp circuit 80 is for example made up of circuit substrate and the multiple components (electronic component) that are installed in circuit substrate.Circuit substrate is that metal wiring is patterned and the printed circuit board (PCB) that forms, and the multiple components that are installed in this circuit substrate are electrically connected to each other.In the present embodiment, circuit substrate is for example with interarea and the orthogonal state of lamp axle and be configured.And, component is for example the semiconductor elements such as various capacity cells, resistive element, convertor circuit element, coil part, choking-winding (choke transformer), noise filter, diode or integrated circuit component etc., and lamp circuit 80 is selected rightly and is configured among these components.
And bulb-shaped lamp 1 also can possess lamp circuit 80.For example, directly direct current is supplied to bulb-shaped lamp 1 from ligthing paraphernalia or battery etc. in the situation that, bulb-shaped lamp 1 also can possess lamp circuit 80.And lamp circuit 80 is not limited only to smoothing circuit, also can selects rightly light adjusting circuit and booster circuit etc., and combine to form.
[the detailed formation of LED module]
Then, utilize Fig. 4 to describe the detailed formation of LED module 20.Fig. 4 shows the formation of the LED module in the related bulb-shaped lamp of present embodiment 1.And, (a) of Fig. 4 is the plane while seeing LED module 20 from top, (b) of Fig. 4 is the profile of this LED module 20 at A-A ' the line place of (a), (c) of Fig. 4 is the profile of this LED module 20 at B-B ' the line place of (a), (d) of Fig. 4 is the profile of this LED module 20 at C-C ' the line place of (a), and (e) of Fig. 4 is the profile of this LED module 20 at D-D ' the line place of (a).
LED module 20 be main forwards and side emit the light emitting module (light-emitting device) of light, be lip-deep COB (Chip On Board: the chip on board) structure that bare chip is directly mounted to substrate 21.
As shown in Figure 4, LED module 20 possesses: substrate 21, be arranged on the first ML1 of main light emission portion and the second ML2 of main light emission portion on substrate 21, be arranged on the first secondary illuminating part SL1 between the first ML1 of main light emission portion and the second ML2 of main light emission portion on substrate 21, be arranged on the 3rd ML3 of main light emission portion and the 4th ML4 of main light emission portion on substrate 21 and be arranged on the second secondary illuminating part SL2 between the 3rd ML3 of main light emission portion and the 4th ML4 of main light emission portion on substrate 21.And in addition LED module 20 also possesses metal wiring 26, wire 27 and terminal 28.
As Fig. 4 (a) and (b), the first ML1 of main light emission portion comprises: be configured in the multiple LED22a (the first light-emitting component) on the surface (first surface) of substrate 21 and the first wavelength transform component WC1 that the light wavelength that LED22a was sent is converted with row shape.That is, the first ML1 of main light emission portion is the illuminating part self with light-emitting component, in the first wavelength transform component WC1, has multiple LED22a.
At the first ML1 of main light emission portion, multiple LED22a are configured to row with linearity, and the first wavelength transform component WC1 is arranged on the surface of substrate 21 with linearity along the orientation (column direction) of multiple LED22a.
The first wavelength transform component WC1 comprises: the first wavelength shifter (not shown) that the light wavelength that LED22a is sent converts and the first seal member 23a that comprises this first wavelength shifter and multiple LED22a are sealed together.The first seal member 23a is configured to the mode of multiple LED22a of linearity with covering, and is arranged on the surface of substrate 21 with linearity.
As shown in Fig. 4 (e), the shape semicircular in shape substantially of this first wavelength transform component WC1 in the section vertical with the length direction of the first wavelength transform component WC1 (the first seal member 23a).And each of multiple LED22a is configured to, be located substantially on the center of the width of the first wavelength transform component WC1.; along the row center line of the column direction of multiple LED22a (line at the center by each LED22a), substantially consistent with the center line of the trend of the length direction along the first wavelength transform component WC1 (line at the width center by the first wavelength transform component WC1).
The second wave length transform component WC2 that the light wavelength that the first secondary illuminating part SL1 is sent by the LED22b in the LED22a in the first ML1 of main light emission portion and the second ML2 of main light emission portion converts forms.The first secondary illuminating part SL1 self does not possess LED, to carry out luminous illuminating part by the light of the LED from the first secondary illuminating part SL1 outside, as shown in Fig. 4 (c), in second wave length transform component WC2, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by this second wave length transform component WC2.In the present embodiment, the first secondary illuminating part SL1 is only made up of second wave length transform component WC2.
The second wave length transform component WC2 of the first secondary illuminating part SL1 comprises: the second wave length coversion material (not shown) that the light wavelength that LED22a and LED22b both sides are sent converts and the first illusory seal member 24a that comprises this second wave length coversion material.The first illusory seal member 24a can be made up of the encapsulant identical with the first seal member 23a and the second seal member 23b, identical with the first seal member 23a and the second seal member 23b in appearance.Second wave length transform component WC2 (the first illusory seal member 24a) is arranged between the first seal member 23a and the second seal member 23b on substrate 21 with linearity.
The formation of the second ML2 of main light emission portion is identical with the first ML1 of main light emission portion.In the present embodiment, the second ML2 of main light emission portion is made up of the three-wavelength transform component WC3 that is configured in surperficial multiple LED22b (the second light-emitting component) of substrate 21 with row shape and the light wavelength that LED22b was sent is converted., the second ML2 of main light emission portion is identical with the first ML1 of main light emission portion, is the illuminating part self with light-emitting component, in three-wavelength transform component WC3, has multiple LED22b.
In the second ML2 of main light emission portion, multiple LED22b are same with LED22a, be configured to row with linearity, and three-wavelength transform component WC3 is arranged on the surface of substrate 21 with linearity along the orientation (column direction) of multiple LED22b.
Three-wavelength transform component WC3 comprises: the three-wavelength coversion material (not shown) that the light wavelength that LED22b is sent converts and the second seal member 23b that comprises this three-wavelength coversion material and multiple LED22b are sealed together.The second seal member 23b, to cover the mode of the multiple LED22b that are configured to linearity, is arranged on the surface of substrate 21 with linearity.
As shown in Fig. 4 (e), being shaped as of this three-wavelength transform component WC3 in the section vertical with the length direction of three-wavelength transform component WC3 (the second seal member 23b) is slightly semicircle.And each of multiple LED22b is configured to, be located substantially on the center of the width of three-wavelength transform component WC3.; along the row center line of the column direction of multiple LED22b (line at the center by each LED22b), substantially consistent with the center line of the trend of the length direction along three-wavelength transform component WC3 (line at the center of the width by three-wavelength transform component WC3).
The formation of the 3rd ML3 of main light emission portion is same with the first ML1 of main light emission portion.In the present embodiment, the 3rd ML3 of main light emission portion is by being configured in surperficial multiple LED22c (the 3rd light-emitting component) of substrate 21 and the 4th wavelength conversion parts WC4 that the light wavelength that LED22c was sent is converted with row shape., the 3rd ML3 of main light emission portion is same with the first ML1 of main light emission portion, is the illuminating part self with light-emitting component, in three-wavelength transform component WC3, has multiple LED22c.
In the 3rd ML3 of main light emission portion, multiple LED22c are same with LED22a, are configured to row with linearity, and the 4th wavelength conversion parts WC4 is arranged on the surface of substrate 21 with linearity along the orientation (column direction) of multiple LED22c.
As shown in Fig. 4 (e), it is semicircle that the shape of the 4th wavelength conversion parts WC4 in the section vertical with the length direction of the 4th wavelength conversion parts WC4 (the 3rd seal member 23c) is essentially.And each of multiple LED22c is configured to, be located substantially on the center of the width of the 4th wavelength conversion parts WC4.; along the row center line of multiple LED22c column directions (line at the center by each LED22c), substantially consistent with the center line of the trend of the length direction along the 4th wavelength conversion parts WC4 (line at the width center by the 4th wavelength conversion parts WC4).
The 4th wavelength conversion parts WC4 comprises: the 4th wavelength shifter (not shown) that the light wavelength that LED22c is sent converts and the 3rd seal member 23c that comprises the 4th wavelength shifter and multiple LED22c are sealed together.The 3rd seal member 23c, to cover the mode of the multiple LED22c that are configured to linearity, is arranged on the surface of substrate 21 with linearity.
The 5th wavelength conversion parts WC5 that the light wavelength that the second secondary illuminating part SL2 is sent by the LED22d in the LED22c in the 3rd ML3 of main light emission portion and the 4th ML4 of main light emission portion converts forms.The second secondary illuminating part SL2 is same with the first secondary illuminating part SL1, self does not have LED, be to carry out luminous illuminating part by the light of the LED from the second secondary illuminating part SL2 outside, in the 5th wavelength conversion parts WC5, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by the 5th wavelength conversion parts WC5.
In the present embodiment, the second secondary illuminating part SL2 does not have LED, different from the first secondary illuminating part SL1, as shown in Fig. 4 (d), in the 5th wavelength conversion parts WC5, there is the Zener diode 25 as non-luminous electronic component (semi-conductor electricity sub-element etc.).For anti-non-return withstand voltage low LED22a to 22d, by the electric power (static etc.) against direction polarity, and destroyed, LED22a to 22d is configured to be connected in parallel with reversed polarity Zener diode 25.In the present embodiment, on substrate 21, be equipped with a Zener diode 25.
The 5th wavelength conversion parts WC5 of the second secondary illuminating part SL2 comprises: the 5th wavelength shifter (not shown) that the light wavelength that LED22c and LED22d both sides are sent converts and the second illusory seal member 24b that comprises the 5th wavelength shifter.The second illusory seal member 24b can be made up of the encapsulant identical with the 3rd seal member 23c and the 4th seal member 23d, and the 3rd seal member 23c and the 4th seal member 23d are identical in appearance.The 5th wavelength conversion parts WC5 (the second illusory seal member 24b) is arranged between the first seal member 23a and the second seal member 23b on substrate 21 with linearity.
Zener diode 25 in the second secondary illuminating part SL2 is sealed by the second illusory seal member 24b.And, in the second illusory seal member 24b, except Zener diode, can be also other non-luminous semi-conductor electricity sub-element.
The formation of the 4th ML4 of main light emission portion is same with the 3rd ML1 of main light emission portion.In the present embodiment, the 4th ML4 of main light emission portion is by be configured in surperficial multiple LED22d (the 4th light-emitting component) of substrate 21 and the 6th wavelength conversion parts WC6 that the light wavelength that LED22d was sent is converted with row shape.That is, the 4th ML4 of main light emission portion is same with the 3rd ML3 of main light emission portion, is the illuminating part self with light-emitting component, in the 4th wavelength conversion parts WC4, has multiple LED22d.
In the 4th ML4 of main light emission portion, multiple LED22d are same with LED22a, be configured to row with linearity, and the 6th wavelength conversion parts WC6 is along multiple LED22d orientations (column direction), on the surface of substrate 21, is configured to linearity.
The 6th wavelength conversion parts WC6 comprises: the 6th wavelength shifter (not shown) that the light wavelength that LED22d is sent converts and the 4th seal member 23d that comprises the 6th wavelength shifter and multiple LED22d are sealed together.The 4th seal member 23d, to cover the mode of the multiple LED22d that are configured to linearity, is configured to linearity on the surface of substrate 21.
As shown in Fig. 4 (e), the shape of the 6th wavelength conversion parts WC6 in the section vertical with the length direction of the 6th wavelength conversion parts WC6 (the 4th seal member 23d) is roughly semicircle.And each of multiple LED22d is configured to, be located substantially on the center of the width of the 6th wavelength conversion parts WC6.; multiple LED22d are along the row center line of column direction (line at the center by each LED22d), substantially consistent with the center line of the length direction trend along the 6th wavelength conversion parts WC6 (line at the width center by the 6th wavelength conversion parts WC6).
In the LED module 20 with this formation, six wavelength conversion parts are set up in parallel, and these six articles of wavelength conversion parts are: the first wavelength transform component WC1 (the first seal member 23a), second wave length transform component WC2 (the first illusory seal member 24a), three-wavelength transform component WC3 (the second seal member 23b), the 4th wavelength conversion parts WC4 (the 3rd seal member 23c), the 5th wavelength conversion parts WC5 (the second illusory seal member 24b) and the 6th wavelength conversion parts WC6 (the 4th seal member 23d).In addition, in the present embodiment, these wavelength conversion parts are arranged side by side each other in the longitudinal direction.
And, the second wave length transform component WC2 (the first illusory seal member 24a) being configured between the first wavelength transform component WC1 (the first seal member 23a) and three-wavelength transform component WC3 (the second seal member 23b), preferably comes near configuration with the degree not contacting with each other with the first wavelength transform component WC1 (the first seal member 23a) and three-wavelength transform component WC3 (the second seal member 23b).Equally, the 5th wavelength conversion parts WC5 (the second illusory seal member 24b) being configured between the 4th wavelength conversion parts WC4 (the 3rd seal member 23c) and the 6th wavelength conversion parts WC6 (the 4th seal member 23d), preferably comes near configuration with the degree not contacting with each other with the 4th wavelength conversion parts WC4 (the 3rd seal member 23c) and the 6th wavelength conversion parts WC6 (the 4th seal member 23d).
And in the present embodiment, three article of first wavelength transform component WC1 to the three-wavelength transform component WC3 uniformly-spaced arranged.Equally, three article of the 4th wavelength conversion parts WC3 to the six wavelength conversion parts WC6 also uniformly-spaced arranged.
Below each component parts of LED module 20 is described in detail.
[substrate]
Substrate 21 can adopt light-transmitting substrate or non-light transmittance substrate.Substrate 21 is for example the ceramic substrate that is made up of the ceramic material of aluminium oxide or aluminium nitride etc., resin substrate, glass substrate, flexible base, board or by the metal substrate (taking metal as main substrate) of resin-coating etc.Substrate 21 is installation base plates (for the substrate of LED is installed) of the rectangle for LED22a, 22b and 32 are installed.Substrate 21 adopts the substrate that Area comparison is large in order to ensure thermal diffusivity, for example, the length on long limit is being made as to L1, and the length of minor face is made as L2, and thickness is made as in the situation of d, for example, can be L1=30mm, L2=18mm, d=1mm.
Substrate 21 can by the transmitance of the light that LED22a to 22d is sent low, for example full transmitance is that white substrate or the metal substrates etc. such as white alumina substrate below 10% form.And, substrate 21 can by the light reflectivity with the light that LED22a to 22d is sent be more than 50%, with Al
2o
3(aluminium oxide), MgO, SiO and TiO
2any form for substrate of main component.Like this, by being used as substrate 21 with the low substrate of light transmission rate, thereby can suppress see through substrate 21 and from the back side penetrate light, therefore can suppress irregular colour even.And, by adopting cheap white substrate, thereby can realize cost degradation.
In addition, as substrate 21, also can adopt the light-transmitting substrate that light transmission rate is high.For example, as substrate 21, can adopt the full transmitance of visible ray is more than 80% substrate, or is transparent to visible ray, and what transmitance was very high can see through the substrate of seeing from a contrary side.As this light-transmitting substrate, can adopt transparent resin substrate that the light transparent ceramic substrate being made up of multicrystal aluminium oxide or aluminium nitride, the transparent glass substrate being made up of glass, the quartz wafer being made up of crystal, the sapphire substrate being made up of sapphire or transparent resin material form etc.Like this, by adopting the high light-transmitting substrate of light transmission rate to be used as substrate 21, even therefore in the case of LED chip being only installed to the surface of substrate 21 and the one party at the back side, the light transmission substrate 21 that also can make LED chip send, therefore the face of, LED chip being never installed also can be emitted light.
Be equipped with a through hole 21a for connecting substrate 21 at the central portion of substrate 21.This through hole 21a is for being fixed on pillar 40 by LED module 20, and the jut 42b of pillar 40 is entrenched in through hole 21a.Through hole 21a and jut 42b rectangular shaped when from plane, have position for determining substrate 21 or towards the function of position specified part.And, even without through hole 21a, also can LED module 20 be fixed to pillar 40 by sticker.Therefore, through hole 21a also can be set.
And, be provided with two through hole 21b for connecting substrate 21 at the both ends of the long side direction of substrate 21.These two through hole 21b are configured for the terminal 28 that the lead-in wire 70 of power supply use is connected with LED module 20.
[LED]
LED22a to 22d carrys out luminous semiconductor light-emitting elements by the electric power specifying.LED22a to 22d is provided with multiple on the surface of substrate 21 (first surface) respectively.And multiple LED22a to 22d arrange with identical interval respectively on the long side direction of substrate 21.Multiple LED22a to 22d are for being connected in series in each element line, and element line is each other for being connected in parallel.
In the present embodiment, LED22a to 22d all adopts identical LED, for example, be the blue led chip that sends blue light in the time of energising.As blue led chip, the material that by InGaN is for example forms, and adopts the gallium nitride based semiconductor light-emitting elements that centre wavelength is 440nm to 470nm.
At this, utilize the LED22a to 22d that Fig. 5 adopts present embodiment to describe.Fig. 5 is the amplification profile of LED (LED chip) periphery in the LED module 20 of the related bulb-shaped lamp 1 of embodiment 1 of the present utility model.And although show the periphery of LED22a in Fig. 5, the periphery of LED22b to 22d is also same formation.
As shown in Figure 5, LED22a has: sapphire substrate 122a and be laminated on sapphire substrate 122a each other by the different multiple nitride semiconductor layer 122b that form that form.
Both ends on nitride semiconductor layer 122b are equipped with cathode electrode 122c and anode electrode 122d.And, on cathode electrode 122c, be provided with wire joint portion 122e, on anode electrode 122d, be provided with wire joint portion 122f.For example, in adjacent LED22a, the anode electrode 122d of the cathode electrode 122c of a side LED22a and the opposing party's LED22a, is connected by wire 27 via wire joint portion 122e and 122f.
LED22a, in the relative mode in the face of sapphire substrate 122a mono-side and the surface of substrate 21 or the back side, is fixed on substrate 21 by the chips incorporate material 122g of light transmission.In chips incorporate material 122g, can adopt silicones that contains the filler being formed by oxidized metal etc.By use translucent material in chips incorporate material 122g, thereby the loss of the light penetrating from the side of LED22a can be reduced, and the shadow causing because of chips incorporate material 122g can be suppressed.
[seal member]
The first seal member 23a, the second seal member 23b, the 3rd seal member 23c and the 4th seal member 23d, except each element line of LED22a to 22d is sealed in the lump, also seal metal wiring 26.In addition, the first illusory seal member 24a does not seal LED and metal wiring.And although the second illusory seal member 24b does not seal LED, zener diode 25 and metal wiring 26 seal.
The first seal member 23a is made up of the insulative resin material that contains fluorophor particle as the first wavelength shifter.Equally, the second seal member 23b is made up of the insulative resin material that contains fluorophor particle as three-wavelength coversion material, the 3rd seal member 23c is made up of the resin material of the insulating properties that contains fluorophor particle as the 4th wavelength shifter, and the 4th seal member 23d is made up of the resin material of the insulating properties that contains fluorophor particle as the 6th wavelength shifter.
The first illusory seal member 24a is made up of the resin material of the insulating properties that contains fluorophor particle as second wave length coversion material.Equally, the second illusory seal member 24b is made up of the resin material of the insulating properties that contains fluorophor particle as the 5th wavelength shifter.
The light stimulus that fluorophor particle in each seal member of the first seal member 23a to the four seal member 23d and the illusory seal member 24b of the first illusory seal member 24a to the second is sent by LED22a to 22d, thus the light of desirable color (wavelength) emitted.In the present embodiment, the first seal member 23a, the second seal member 23b, the 3rd seal member 23c, the 4th seal member 23d, the first illusory seal member 24a and the second illusory seal member 24b are identical formation, are made up of identical fluorophor particle and identical sealed resin material.
As fluorophor particle, be to send the blue led chip of blue light at LED22a to 22d, in order to radiate white light from each seal member, and adopt the fluorophor particle that is sodium yellow by blue light wavelength conversion.The yellow fluorophor particle that for example, can adopt YAG (yttrium, aluminium, garnet) to be as fluorophor particle.Accordingly, a part for the blue light that LED22a to 22d sends, is sodium yellow by the yellow fluorophor particle containing in each seal member by wavelength conversion., yellow fluorophor particle comes luminous using blue light as exciting light.And, (the there is no wavelength conversion) blue light not absorbed by yellow fluorophor particle, with by yellow fluorophor particle by the sodium yellow of wavelength conversion, in each seal member, be diffused and mixed, thereby penetrate from each seal member as white light.
In each seal member with this formation, for example, can, by by containing the gluey seal member material not hardened of wavelength shifter, apply and make it to harden to form by distributor.
And, as the material of each seal member, can adopt the organic materials such as transparent resin material or fluorine resin such as silicones.In the present embodiment, as the first seal member 23a to the four seal member 23d and the illusory seal member 24b of the first illusory seal member 24a to the second, can adopt the fluorophor particle of regulation is distributed to silicones and form containing fluorophor resin.And, as the material of seal member, except resin, can also adopt inorganic material such as the glass that low melting point glass or sol-gal process make etc.And, in each seal member, also can be dispersed the photodiffusion materials such as silicon particle.
[metal wiring]
Metal wiring 26 is the conductive wires for the luminous electric current of LED is flow through, and is above formed by pattern with the shape of regulation on the surface of substrate 21 (first surface).
Metal wiring 26 has been formed multiple, be used at each LED element line, to between multiple LED22a, between multiple LED22b, be connected in series between multiple LED22c and between multiple LED22d, each of multiple metal wirings 26 is Xing Cheng Wei Island shape between adjacent LED.And metal wiring 26 is connected in parallel each other for each element line to LED22a to 22d, formed by pattern with the shape of regulation at the both ends of substrate 21.
And metal wiring 26 is for being connected in parallel that to make Zener diode 25 and LED22a to 22d be reversed polarity, and formed by pattern with the shape of regulation.
Metal wiring 26 adopts identical metal material to be formed by while pattern.As the metal material of metal wiring 26, for example, can adopt silver (Ag), tungsten (W) or copper (Cu) etc.And, also can implement the electroplating processes of nickel (Ni) or gold (Au) etc. on the surface of metal wiring 26.And metal wiring 26 also can be made up of different metal materials, also can be formed by different operation.
And, for the metal wiring 26 exposing from the seal member of each wavelength conversion parts, except terminal 28, resin molding (resin coating film) coating that the glass-film (glass coating film) preferably being formed by glass material or resin material form.Like this, can improve the insulating properties in LED module 20.
[wire]
Wire 27 is for connecting LED22a to 22d and metal wiring 26, and the electric wire of Zener diode 25 and metal wiring 26, for example, be golden wire.As the explanation of Fig. 5, by this wire 27, be arranged on the wire joint portion 122e above of LED22a and each metal wiring 26 being formed with being adjacent to the both sides of LED22a of 122f and be combined by wire.
In order not make wire 27 expose from the seal member of each wavelength conversion parts, thereby wire 27 is all embedded in seal member.
[terminal]
Terminal 28 is and lead-in wire 70 external connecting electrodes that weld, and is to surround the mode of through hole 21b and the connecting pad that forms with the shape of regulation on the surface of substrate 21.Terminal 28 is integrated shaping with metal wiring 26, adopts the metal material identical with metal wiring 26, is formed with metal wiring 26 by pattern simultaneously.
And terminal 28 is power supplies of LED module 20, in order to make LED22a to 22d luminous, accept electric power from the outside of LED module 20, the electric power of acceptance is supplied to each LED22a to 22d by metal wiring 26 and wire 27.
[annexation of LED module and pillar and lead-in wire]
Then, utilize Fig. 6 to describe LED module 20 and the annexation of pillar 40 and lead-in wire 70.Fig. 6 shows the formation of the LED module periphery in the related bulb-shaped lamp of present embodiment 1.And, (a) of Fig. 6 is the state to remove enclosed globe shade 10 in bulb-shaped lamp 1, plane during from top LED module 20, (b) of Fig. 6 is the profile of this bulb-shaped lamp 1 on the X-X ' line of (a), and (c) of Fig. 4 is the profile of this bulb-shaped lamp 1 on the Y-Y ' line of (a).
As Fig. 6 (a) and (b), at the chimeric jut 42b that has pillar 40 of the through hole 21a of substrate 21.Accordingly, with the position of substrate 21 and towards the state being prescribed, LED module 20 is fixed to pillar 40.
LED module 20 is electrically connected by electric conductivity adhesion parts 29 physically with lead-in wire 70.Electric conductivity adhesion parts 29 are by terminal 28 and the electric conductivity stickers such as 70 scolding tin that are connected or silver paste agent that go between.Electric conductivity adhesion parts 29, in the mode of the side of one end of coated lead-in wire 70 on the surface at terminal 28, join and are set up with terminal 28 and lead-in wire 70 both sides.Electric conductivity adhesion parts 29 are set up in the mode of the opening of the face side of substrate 21 to stop up through hole 21b.
At this, electric conductivity adhesion parts 29 can be coated by insulative resin.And this insulative resin is low to the light transmission rate of the light sending from LED22a to 22d, for example, it can be the white resin below 10%.
LED module 20 is connected with two lead-in wires 70 by electric conductivity adhesion parts 29.Now, lead-in wire 70 is electrically connected with terminal 28, first, and lead-in wire 70 insertions of the openings with the rear side from through hole 21b, the mode passing from the opening of the face side of through hole 21b and being configured.Afterwards, in the mode of joining with face side part and terminal 28 both sides of this lead-in wire 70, electric conductivity adhesion parts 29 are set.
And in the LED module 20 shown in Fig. 6, modes that lead-in wire 70 exposes from the surface of electric conductivity adhesion parts 29 with front end and being set up, can be completely coated by the electric conductivity parts of adhering.In this case, because lead-in wire 70 and the contact area of electric conductivity adhesion parts 29 increase, thereby can make both reinforcements that is connected and fixed.
[action effect]
Then, utilize Fig. 7 to describe the action effect of the related LED module 20 of present embodiment.Fig. 7 is the figure of the action effect of the LED module 20 for the related bulb-shaped lamp 1 of embodiment 1 of the present utility model is described, (a) be a part of amplification profile of the LED module 200 of comparative example 1, (b) being a part of amplification profile of the LED module 201 of comparative example 2, is (c) a part of amplification profile of the LED module 20 in embodiment 1.
As shown in Fig. 7 (a), the formation of the LED module 200 of comparative example 1 is, the first seal member 23a (containing fluorophor resin) of sealing LED 22a is adjacent with the second seal member 23b (containing fluorophor resin) of sealing LED 22b, as shown in the embodiment, do not form the first illusory seal member 24a.
In the LED module 200 of comparative example 1, if the area of substrate 21 increases, the interval of the first seal member 23a and the second seal member 23b becomes large.Consequently, the region (non-illuminating part) that does not form the first seal member 23a and the second seal member 23b increases, thereby cause in substrate 21, form the region (illuminating part) of the first seal member 23a and the second seal member 23b and do not form that between the region (non-illuminating part) of the first seal member 23a and the second seal member 23b, obvious light and shade to occur poor, thereby occur brightness irregularities.
Therefore, shown in the related LED module 201 of comparative example 2 as shown in Fig. 7 (b), the formation that can consider is to carry out all LED (LED22a and LED22b) on covered substrate 21 with seal member 23A (containing fluorophor resin).For example, the mode that becomes rectangle with the flat shape of seal member 23A forms seal member 23A.
But, in this formation, owing to becoming plane above seal member 23A, will inject to outside light (light being sent by LED22a, 22b and the light sending from the fluorophor particle) ratio that (interface of seal member 23A and air layer) reflected on seal member 23A increases from the inside of seal member 23A.Like this, the ratio that injects to outside light from the inside of seal member 23A will reduce, thereby causes light to take out Efficiency Decreasing.Therefore,, in the LED module with this formation, can not realize high beam.
To this, LED module 20 in present embodiment shown in Fig. 7 (c) is, between the first seal member 23a (the first ML1 of main light emission portion) and the second seal member 23b (the second ML2 of main light emission portion), the first illusory seal member 24a (the first secondary illuminating part SL1) is set.
Accordingly, the light that LED22a from the first ML1 of main light emission portion penetrates, can be encouraged by the fluorophor particle of the first seal member 23a (the first wavelength transform component WC1) that covers self, and also can be by the fluorophor particle excitation of the first illusory seal member 24a (second wave length transform component WC2) adjacent with the first seal member 23a.Equally, the light that LED22b from the second ML2 of main light emission portion penetrates, can be encouraged by the fluorophor particle of the second seal member 23b (three-wavelength transform component WC3) that covers self, and also can be by the fluorophor particle excitation of the first illusory seal member 24a (second wave length transform component WC2) adjacent with the second seal member 23b.
In the present embodiment, LED22a and 22b are the blue led chip that sends blue light, and the fluorophor particle (wavelength shifter) in the first seal member 23a, the second seal member 23b and the first illusory seal member 24a is yellow fluorophor particle.Therefore, the blue light sending from the first ML1 of main light emission portion (the first seal member 23a), the second ML2 of main light emission portion (the second seal member 23b) and the first secondary illuminating part SL1 (the first illusory seal member 24a), by the sodium yellow after yellow fluorophor particle wavelength conversion with do not mixed by the blue light of yellow fluorophor particle wavelength conversion, thereby emit the white light as mixed light.
Like this, not only can be luminous by LED module 20, the first seal member 23a and the second seal member 23b in present embodiment, and also the first illusory seal member 24a also can be luminous., the first illusory seal member 24a can be played a role as doubtful illuminating part.Consequently, because the first seal member 23a, the second seal member 23b and the first illusory seal member 24a can play a role as illuminating part, therefore, for the formation of Fig. 7 (a), light and shade in substrate 21 can be suppressed poor, and brightness irregularities can be suppressed.
And, in LED module 20 in the present embodiment shown in (c) of Fig. 7, article three, each section shape of seal member (containing fluorophor resin) is dome-type section (being almost semicircle), therefore in the ejaculation light from seal member to outside, can suppress total reflection at the interface of seal member and air layer.Therefore,, in the LED module 20 of present embodiment, there will not be the light shown in (b) of Fig. 7 to take out the reduction of efficiency.
And, in bulb-shaped lamp 1 in the present embodiment, owing to having adopted the LED module 20 shown in (c) of Fig. 7 as light source, therefore, can realize the few bulb-shaped lamp of brightness irregularities in light source.
And, in LED module 20 in the present embodiment, concentration by the fluorophor particle (three-wavelength coversion material) in concentration and/or the second seal member 23b of the fluorophor particle (the first wavelength shifter) in concentration and the first seal member 23a of the fluorophor particle (second wave length coversion material) in the first illusory seal member 24a is adjusted, thereby can carry out color adjustment.In this case, preferably below the concentration of the fluorophor particle of the concentration of the fluorophor particle in the first illusory seal member 24a in the first seal member 23a and the second seal member 23b.Below, this point is described.
In the first seal member 23a, the second seal member 23b and the first illusory seal member 24a, if the concentration of the fluorophor particle in each seal member is identical, be formed on the first seal member 23a of both sides of the first central illusory seal member 24a and the light that the second seal member 23b both sides' LED emits and can incide this first illusory seal member 24a, the white light jaundice (yellow compared with the light of Strong) that the white light of emitting from the first illusory seal member 24a like this, can be emitted than the first seal member 23a and the second seal member 23b.Like this, between the first illusory seal member 24a and the first seal member 23a and the second seal member 23b, can there is the inhomogeneous of color.
Therefore, by making the concentration of the fluorophor particle in concentration ratio the first seal member 23a and the second seal member 23b of the fluorophor particle in the first illusory seal member 24a little, thereby can make the wavelength conversion efficiency in the first illusory seal member 24a less than the wavelength conversion efficiency in the first seal member 23a and the second seal member 23b.Accordingly, can be suppressed at the first illusory seal member 24a and generate sodium yellow, thereby can make light that the first illusory seal member 24a emits closer to white.Like this, can suppress the irregular colour one between the first illusory seal member 24a and the first seal member 23a and the second seal member 23b.
For example, the concentration of the fluorophor particle in the first illusory seal member 24a can be set as the fluorophor particle in the first seal member 23a and the second seal member 23b concentration 15% to 40%.
And, for the inhibition (color adjustment) of the irregular colour one in the first seal member 23a, the second seal member 23b and the first illusory seal member 24a, also the concentration of the fluorophor particle to each seal member is not adjusted, but the height of each seal member is adjusted.For example, the concentration of the fluorophor particle in the first seal member 23a, the second seal member 23b and the first illusory seal member 24a is made as identical, be lower than the height of the first seal member 23a and the second seal member 23b by the height setting of the first illusory seal member 24a, can make like this wavelength conversion Efficiency Decreasing of the first illusory seal member 24a.Accordingly, can be suppressed at the first illusory seal member 24a and generate sodium yellow.Consequently, can suppress the irregular colour one between the first illusory seal member 24a and the first seal member 23a and the second seal member 23b.
Or, length by each seal member to the first seal member 23a, the second seal member 23b and the first illusory seal member 24a is adjusted, and also can carry out the color adjustment (inhibition of irregular colour one) in the first seal member 23a, the second seal member 23b and the first illusory seal member 24a.For example, the concentration of the fluorophor particle in the first seal member 23a, the second seal member 23b and the first illusory seal member 24a is made as identical, by the length setting of the first illusory seal member 24a below the length of the first seal member 23a and the second seal member 23b, the irregular colour one between such first illusory seal member 24a と the first seal member 23a and the second seal member 23b.
And, in Fig. 7 (c), although the first ML1 of main light emission portion (the first seal member 23a), the second ML2 of main light emission portion (the second seal member 23b) and the first secondary illuminating part SL1 (the first illusory seal member 24a) are illustrated, the 3rd ML3 of main light emission portion (the 3rd seal member 23c), the 4th ML4 of main light emission portion (the 4th seal member 23d) and the second secondary illuminating part SL2 (the second illusory seal member 24b) are also same.
And, in the present embodiment, to existing the first secondary illuminating part SL1 (the first illusory seal member 24a) to be illustrated between the first ML1 of main light emission portion (the first seal member 23a) and the second ML2 of main light emission portion (the second seal member 23b), but, only in the case of existing, the one party of the first ML1 of main light emission portion (the first seal member 23a) and the second ML2 of main light emission portion (the second seal member 23b) and the first secondary illuminating part SL1 (the first illusory seal member 24a) also can be suitable for., also can be applicable to be only a main light emission portion and a situation that secondary illuminating part is adjacent to the utility model.Like this, by making secondary illuminating part adjacent with main light emission portion, thereby it is poor to suppress light and shade on substrate.
(variation of embodiment 1)
The variation of the LED module 20 then, bulb-shaped lamp 1 being possessed describes.
(variation 1 of embodiment 1)
Then, utilize Fig. 8 A to describe the variation 1 of embodiment 1.Fig. 8 A is the plane of the LED module 20A in the variation 1 of embodiment 1 of the present utility model.
As shown in Figure 8 A, the formation of the LED module 20A in this variation, compared with the LED module 20 shown in Fig. 4, has also been set up the 3rd secondary illuminating part SL3.
The 7th wavelength conversion parts WC7 that the light wavelength that the 3rd secondary illuminating part SL3 is sent by the LED22c in the LED22b in the second ML2 of main light emission portion and the 3rd ML3 of main light emission portion converts forms.; the 3rd secondary illuminating part SL3 is same with the first secondary illuminating part SL1; self does not have LED; but carry out luminous illuminating part by the light of the LED from the 3rd secondary illuminating part SL3 outside; in the 7th wavelength conversion parts WC7, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by the 7th wavelength conversion parts.In this variation, the 3rd secondary illuminating part SL3 is only made up of the 7th wavelength conversion parts WC7.
The 7th wavelength conversion parts WC7 comprises the 7th wavelength shifter (not shown) that light wavelength that LED22b and these both sides of LED22c are sent converts and the 3rd illusory seal member 24c that comprises the 7th wavelength shifter.The 3rd illusory seal member 24c is identical with the first illusory seal member 24a and the second illusory seal member 24b, is made up of encapsulant, also identical with the first illusory seal member 24a and the second illusory seal member 24b in appearance.
In this variation, the 3rd illusory seal member 24c (the 7th wavelength conversion parts WC7) is arranged between the second seal member 23b (three-wavelength transform component WC3) and the 3rd seal member 23c (the 4th wavelength conversion parts WC4) with linearity on substrate 21.,, in this variation, in the LED module 20 shown in Fig. 4, in the mode in the space between landfill the second seal member 23b and the 3rd seal member 23c, as the 3rd secondary illuminating part SL3, the 3rd illusory seal member 24c is set.
More than, by the LED module 20A in this variation, between the second seal member 23b (the second ML2 of main light emission portion) and the 3rd seal member 23c (the 3rd ML3 of main light emission portion), the 3rd illusory seal member 24c (the 3rd secondary illuminating part SL3) is set.Accordingly, the region between the second seal member 23b and the 3rd seal member 23c also can generate doubtful illuminating part.Consequently, for the LED module 20 in Fig. 4, can further suppress light and shade in substrate 21 poor, and can further suppress brightness disproportionation one.
And, in this variation, also can regulate by the concentration of the fluorophor particle to each seal member, or the height of each seal member is adjusted, suppress the heterogeneity of color.
(variation 2 of embodiment 1)
Then, utilize Fig. 8 B to describe the variation 2 of embodiment 1.Fig. 8 B is the plane of the LED module 20B in the variation 2 of embodiment 1 of the present utility model.
As shown in Figure 8 B, the formation of the LED module 20B in this variation, compared with the LED module 20 shown in Fig. 4, has also been set up fourth officer illuminating part SL4.
In this variation, be provided with four fourth officer illuminating part SL4, the 8th wavelength conversion parts WC8 that the light wavelength that each fourth officer illuminating part SL4 is sent by the LED22a to 22d at the both ends of the length direction (length direction) in the first ML1 to the of main light emission portion four ML4 of main light emission portion converts forms.; fourth officer illuminating part SL4 is same with the first secondary illuminating part SL1; self does not have LED; but carry out luminous illuminating part by the light sending from the LED of fourth officer illuminating part SL4 outside; in the 8th wavelength conversion parts WC8, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by the 8th wavelength conversion parts WC8.In this variation, fourth officer illuminating part SL4 is only made up of the 8th wavelength conversion parts WC8.
The 8th wavelength conversion parts WC8 comprises the 8th wavelength shifter (not shown) that light wavelength that LED22a to 22d is sent converts and the 4th illusory seal member 24d that comprises the 8th wavelength shifter.The 4th illusory seal member 24d is made up of the encapsulant identical with the first illusory seal member 24a, also identical with the first illusory seal member 24a in appearance.
In this variation, article four, the 4th illusory seal member 24d (the 8th wavelength conversion parts WC8) to be to clip in the longitudinal direction the mode of the first seal member 23a to the four seal member 23d, and is arranged on the two ends of the first seal member 23a to the four seal member 23d.Article four, the length direction of the length direction of the 4th illusory seal member 24d and the first seal member 23a to the four seal member 23d is almost orthogonal.That is, in this variation, in the LED module 20 shown in Fig. 4, in the mode in the space of the both sides of the length direction of landfill the first seal member 23a to the four seal member 23d, the 4th illusory seal member 24d is set, using as fourth officer illuminating part SL4.
Above, by the LED module 20B in this variation, both sides at the first seal member 23a (the first ML1 of main light emission portion) to the length direction of the 4th seal member 23d (the 4th ML4 of main light emission portion), are provided with the 4th illusory seal member 24d (fourth officer illuminating part SL4).Accordingly, also can generate doubtful illuminating part at the first seal member 23a (the first ML1 of main light emission portion) to the region of the both sides of the length direction of the 4th seal member 23d (the 4th ML4 of main light emission portion).Consequently, for the LED module 20 in Fig. 4, can further suppress light and shade in substrate 21 poor, and can further suppress the heterogeneity of brightness.
And the formation of this variation also can be applicable to the LED module 20A in Fig. 8 A.And, in this variation, also can regulate by the concentration of the fluorophor particle to each seal member, or the height adjustment of each seal member is suppressed to irregular colour one.
(variation 3 of embodiment 1)
Then, utilize Fig. 9 to describe the related bulb-shaped lamp of the variation 3 of embodiment 1.(a) of Fig. 9 is in the related bulb-shaped lamp of this variation, plane with the state of removing enclosed globe shade during from top LED module, (b) of Fig. 9 is the profile of this bulb-shaped lamp on the X-X ' line of (a), (c) of Fig. 9 is the profile of this bulb-shaped lamp on the Y-Y ' line of (a), and (d) of Fig. 9 is the profile of this bulb-shaped lamp on the Z-Z ' line of (a).
LED module 20C in this variation is compared with the LED module 20 shown in Fig. 4, also be formed with light-emitting component and seal member at the back side of substrate 21 (the second face), wherein possess: main towards front and side emit main LED module (the first light emitting module) 20a of light, and main towards rear and side emit secondary LED module (the second light emitting module) 20b of light.
If Fig. 9 (a) is to as shown in (d), main LED module (main light emission module) 20a possesses: substrate 21, multiple LED22a to 22d, the first seal member 23a to the four seal member 23d, the first illusory seal member 24a and the second illusory seal member 24b, Zener diode 25 (not shown), metal wiring 26, wire 27, terminal 28 and electric conductivity adhesion parts 29.
In addition, secondary LED module (secondary light emitting module) 20b possesses: substrate 21, upper multiple LED32a (the 5th light-emitting component) and the multiple LED32b (the 6th light-emitting component) arranging at the back side of substrate 21 (the second face), the 5th seal member 33a (the 9th wavelength conversion parts) that comprises fluorophor particle (the 9th wavelength shifter) and multiple LED32a are sealed in the lump, comprise fluorophor particle (the tenth wavelength shifter) the five illusory seal member 34a (ten wavelength conversion parts) adjacent with the 5th seal member 33a, the 6th seal member 33b (the 11 wavelength conversion parts) that comprises fluorophor particle (the 11 wavelength shifter) and multiple LED32b are sealed in the lump, comprise fluorophor particle (the 12 wavelength shifter) the six illusory seal member 34b (ten two wavelength conversion parts) adjacent with the 6th seal member 33b, metal wiring 36, wire 37, terminal 38, and electric conductivity adhesion parts 39.
And, in this variation, to consider, these two modules of main LED module 20a and secondary LED module 20b are synthesized a LED module.In this case, a LED module is made up of multiple LED at a substrate 21, the surface that is installed in respectively this substrate 21 and the back side, the seal member that the row of each LED are sealed in the lump and illusory seal member., substrate 21 is the shared substrates of main LED module 20a and secondary LED module 20b.
In this variation, because the formation of main LED module 20a is identical with the LED module 20 shown in Fig. 4, therefore the description thereof will be omitted.
In secondary LED module 20b, multiple LED32a, the 32b of rear side are configured with identical interval respectively on the long side direction of substrate 21.Multiple LED32a, 32b are for being connected in series in each element line, and each element is classified as and is connected in parallel.The LED32a of rear side and 32b be in the mode of sandwich substrate 21, relative with the LED22a of face side and 23d and put.LED32a in this variation and 32b are identical with LED22a to 22d, are blue led chip.
And the 5th seal member 33a of rear side and the 6th seal member 33b be in the mode of sandwich substrate 21, relative with the first seal member 23a and the 4th seal member 23d and be formed linearity.The 5th seal member 33a and the 6th seal member 33b are identical with the formation of the first seal member 23a to the four seal member 23d, and each element line of LED32a and 32b is sealed in the lump and metal wiring 36 is sealed.
In this variation, the 5th seal member 33a and the 6th seal member 33b are identical with the first seal member 23a to the four seal member 23d, adopt in silicones, disperse regulation fluorophor particle containing fluorophor resin.
And the 5th illusory seal member 34a of rear side and the 6th illusory seal member 34b be in the mode of sandwich substrate 21, relative with the first illusory seal member 24a and the second illusory seal member 24b and be formed linearity.The formation of the 5th illusory seal member 34a and the 6th illusory seal member 34b is identical with the first illusory seal member 24a, and self does not possess LED, is to carry out luminous illuminating part by the light sending from outside LED.
Particularly, the 5th illusory seal member 34a is the silicones (containing fluorophor resin) that comprises the fluorophor particle (wavelength shifter) that light wavelength that LED32a is sent converts.And the 6th illusory seal member 34b is the silicones (containing fluorophor resin) that contains the fluorophor particle (wavelength shifter) that light wavelength that LED32b is sent converts.
And, in this variation, the formation of metal wiring 36, wire 37, terminal 38 and electric conductivity adhesion parts 39, identical with metal wiring 26, wire 27, terminal 28 and electric conductivity adhesion parts 29, therefore description thereof is omitted.
Above, by the LED module 20C in this variation, be not only the surface of substrate 21, the back side of substrate 21 has also formed the seal member (illuminating part) with LED, therefore, not only enclosed globe shade top side can be emitted light, and lamp holder one side also can be emitted light.Accordingly, the light distribution characteristic at large luminous intensity distribution angle can be realized, thereby the bulb-shaped LED lamp with the light distribution characteristic more approximate with incandescent lamp bulb can be realized.
And, in this variation, can with adjacent the 5th illusory seal member 34a and the 6th illusory seal member 34b of arranging of main light emission portion (LED32a, 32b and the 5th, the 6th seal member 33a, 33b) of rear side that is arranged on substrate 21.Accordingly, even in the rear side of substrate 21, also can generate and the 5th seal member 33a and the adjacent doubtful illuminating part of the 6th seal member 33b.Consequently, be not only the face side of substrate 21, even overleaf side also can to suppress light and shade poor, and can suppress the brightness disproportionation one of the rear side of substrate 21.
And, in this variation, in the 5th seal member 33a and the 5th illusory seal member 34a, and, in the 6th seal member 33b and the 6th illusory seal member 34b, also can regulate by the concentration of the fluorophor particle to each seal member, or the height adjustment of each seal member is suppressed to irregular colour one.
(variation 4 of embodiment 1)
Then, utilize Figure 10 to describe the related bulb-shaped lamp of the variation 4 of embodiment 1.(a) of Figure 10 be in the related bulb-shaped lamp of this variation with the state of removing enclosed globe shade from above plane when LED module, (b) of Figure 10 is the profile of this bulb-shaped lamp on the X-X ' line of (a), (c) of Figure 10 is the profile of this bulb-shaped lamp on (a) Y-Y ' line, and (d) of Figure 10 is the profile of this bulb-shaped lamp on the Z-Z ' line of (a).
In bulb-shaped lamp in above-mentioned variation 3, on two faces by the surface at a substrate 21 and the back side, light source is set and makes the distribution of light source luminescent, thereby formed these two modules of main LED module 20a and secondary LED module 20b, light can go out from the enclosed globe shade top side of bulb-shaped lamp and lamp holder side-draw.To this, in this variation, be, on the surface of two substrates, light-emitting component be set respectively respectively and make the luminous distribution of light-emitting component, the back side of two substrates is affixed to substrate 21 of incompatible formation.Even in this formation, also can be from the enclosed globe shade top side of bulb-shaped lamp 1 and the bright dipping of lamp holder side-draw.Therefore, the difference of the bulb-shaped lamp 1 of the bulb-shaped lamp 1 that this variation is related and above-mentioned embodiment 1 is, on the surface separately of the substrate 21 of LED module, have and possess light-emitting component and make two substrates of the luminous distribution of light-emitting component by sticker adhesion.Below, by with the difference of the bulb-shaped lamp 1 of above-mentioned embodiment 1 centered by be elaborated.
LED module 20D in this variation is same with the LED module 20C in variation 3, possess: main forwards and side emit light main LED module (the first light emitting module) 20a and main rearward and side emit secondary LED module (the second light emitting module) 20b of light, LED module 20D in this variation is different from variation 3, and substrate 21 forms by the substrate 21X (first substrate) as main substrate with as the substrate 21Y (second substrate) of auxiliary substrate.
If Figure 10 (a) is to as shown in (d), main LED module 20a possesses: substrate 21X (first substrate), be arranged on substrate 21X lip-deep multiple LED22a to 22d, be arranged on substrate 21X the first surperficial seal member 23a to the four seal member 23d, be arranged on the first surperficial illusory seal member 24a and the second illusory seal member 24b of substrate 21X.And main LED module 20a possesses: the Zener diode 25 (not shown), metal wiring 26, wire 27, terminal 28 and the electric conductivity adhesion parts 29 that are arranged on substrate 21X.
And secondary LED module (secondary light emitting module) 20b possesses: substrate 21Y, the lip-deep multiple LED32a that are arranged on substrate 21Y and 32b, lip-deep the 5th seal member 33a that is arranged on substrate 21Y and the 6th seal member 33b, with the 5th seal member 33a and adjacent the 5th illusory seal member 34a of the 6th seal member 33b and the 6th illusory seal member 34b, metal wiring 36, wire 37, terminal 38 and electric conductivity adhesion parts 39.
Substrate 21X and 21Y have identical formation and shape each other, are adhered by sticker 90 in the back side each other, thereby form a substrate 21.Substrate 21X and 21Y can adopt the formation identical with above-mentioned substrate 21.
Both ends at the long side direction of substrate 21X are equipped with two through hole 21Xb for connecting substrate 21X, and, be equipped with two through hole 21Yb for connecting substrate 21Y at the both ends of the long side direction of substrate 21Y.Through hole 21Xb is configured for connecting the terminal 28 of power supply with lead-in wire 70 and main LED module 20a, and through hole 21Yb is configured for connecting the terminal 38 of power supply with lead-in wire 70 and secondary LED module 20b.Through hole 21Xb and 21Yb are connected configuration, thereby form the through hole 21b of substrate 21.Therefore through hole 21Xb and 21Yb that, lead-in wire 70 can break-through connects mutually.
Be equipped with a through hole 21Xa who connects substrate 21X at the central portion of substrate 21X, and, be provided with a through hole 21Ya who connects substrate 21Y at the central portion of substrate 21Y.Through hole 21Xa and 21Ya are used for making main LED module 20a and secondary LED module 20b to be fixed to pillar 40, be configured in the mode connecting each other, thus a through hole 21a of formation substrate 21.Therefore, the jut 42b of pillar 40 is entrenched in the through hole 21Xa and the 21Ya that connect each other.Through hole 21a and jut 42b as previously discussed, as the position for determining substrate 21 or towards position specified part play a role.
Sticker 90 is to be arranged between the back side of substrate 21X and the back side of substrate 21Y, for both are adhered, for example, is made up of the metal paste such as the resins such as silicones or Ag paste etc.The in the situation that of metal paste, due to the pyroconductivity that can improve between substrate 21X and substrate 21Y, thereby improve the pyroconductivity of substrate 21, therefore can improve the radiating efficiency of substrate 21.Consequently, can suppress the luminous efficiency of the LED causing because of temperature rise and the reduction in life-span.And, owing to having improved the light-proofness of sticker 90 and improved the light-proofness of substrate 21, therefore can suppress the irregular colour one causing towards the light at the back side because of the surface from substrate 21X and 21Y.
Sticker 90 is not to hinder the mode of lead-in wire 70 break-through through hole 21Xb and 21Yb, and at least a portion in the through hole 21Xb between the back side of substrate 21X and the back side of substrate 21Y and the space between 21Yb is not set up.And sticker 90, not hinder the chimeric mode of jut of through hole 21Xa and 21Ya and pillar 40, is not set up in the through hole 21Xa between the back side of substrate 21X and the back side of substrate 21Y and the whole spaces between 21Ya.
Above, by the LED module 20D in this variation, can realize the effect identical with variation 3., can realize the bulb-shaped LED lamp with the large light distribution characteristic in luminous intensity distribution angle.And, be not only the face side of substrate 21, the light and shade of rear side is poor also can be inhibited, and can suppress the brightness disproportionation one of the rear side of substrate 21.
And, even in this variation, at the 5th seal member 33a and the 5th illusory seal member 34a, and, in the 6th seal member 33b and the 6th illusory seal member 34b, concentration by the fluorophor particle to each seal member regulates, or the height of each seal member is adjusted, thereby can suppress irregular colour one.
And in this variation, substrate 21 is made up of the substrate 21Y that is provided with the substrate 21X of LED on surface and is provided with LED on surface.And substrate 21X and 21Y are relative and be configured so that the back side of LED not to be set each other.Now, secondary LED module 20b also can adhere and be fixed to pillar 40.Accordingly, can distinguish in advance prepared substrate 21X and 21Y, after surface arranges all parts, adhere again respectively, by this way manufacturing LED module 20D, thereby can easily manufacture LED module 20D.Consequently, can realize the bulb-shaped lamp of easy manufacture.
And in this variation, secondary LED module 20b is directly mounted to pillar 40, the heat occurring at secondary LED module 20b is transmitted to pillar 40.And main LED module 20a is installed to pillar 40 indirectly via secondary LED module 20b, the heat occurring at main LED module 20a is transmitted to pillar 40 indirectly via secondary LED module 20b.And, between main LED module 20a and secondary LED module 20b, be equipped with the sticker 90 as heat-conduction component.This sticker 90 is any in heat conductivity resin, ceramic paste and metal paste.Accordingly, owing to can improving radiating efficiency and the light-proofness of substrate 21, therefore, not only can suppress the luminous efficiency of LED and the reduction in life-span, and can suppress the irregular colour one between main LED module 20a and secondary LED module 20b.
And in this variation, pillar 40 also can join with the back side of substrate 21X through the through hole 21Yb of substrate 21Y.That is, through hole 21Yb is formed all tablings with the fixed part 42 of pillar 40, can be adhered by sticker 90 in the stationary plane of the fixed part 42 of pillar 40 and the back side of substrate 21X.Accordingly, fixedly becoming of main LED module 20a and secondary LED module 20b and pillar 40 is easy, thereby can realize the bulb-shaped lamp of easy manufacture.And, main LED module 20a is fixed on pillar 40 by adhesion, thereby can make substrate 21X shorten to the heat dissipation path of pillar 40, and can the inwall of through hole 21Yb of substrate 21Y and the fixed part 42 of pillar 40 be contacted via heat-conduction components such as lubricating grease, thereby can expand the heat dissipation path of substrate 21Y to pillar 40.Consequently, can suppress the reduction of luminous efficiency and the reduction in life-span of LED.
(embodiment 2)
Below, embodiment 2 of the present utility model is described.
(entirety of bulb-shaped lamp forms)
First, utilize Figure 11 and Figure 12 that the entirety of the related bulb-shaped lamp 2 of present embodiment 2 is formed and described.Figure 11 is the outward appearance perspective view of the related bulb-shaped lamp of embodiment 2 of the present utility model.And Figure 12 is the decomposition diagram of the related bulb-shaped lamp of embodiment 2 of the present utility model.
As shown in Figure 11 and Figure 12, the related bulb-shaped lamp 2 of present embodiment is the bulb-shaped LED lamps that become the substitute of replacement bulb shape fluorescent lamp or incandescent lamp bulb, possesses: enclosed globe shade 210, have the framework 250 of drive circuit 270, be configured in metal parts 260 in framework 250, feed electrical power to the drive circuit 270 of LED module 220 and accept the lamp holder 280 of electric power from outside as support unit 240, the internal configurations of the LED module 220 of light source, supporting LED module 220.And in addition bulb-shaped lamp 2 also possesses: bonded block 230 and the screw 290 of lead-in wire 270a to 270d, ring-type.And bulb-shaped lamp 2 forms peripheral device by enclosed globe shade 210, framework 250 (outside frame 252) and lamp holder 280.That is, enclosed globe shade 210 is exposed to outside with framework 250 (outside frame 252) and lamp holder 280, and outer surface separately exposes in extraneous air.And the formation of the bulb-shaped lamp 2 in present embodiment is that for example brightness is equivalent to 40W shape.
Below, with reference to Figure 12 and utilize Figure 13 and Figure 14 describes each inscape of the related bulb-shaped lamp 2 of present embodiment.Figure 13 shows a section of the related bulb-shaped lamp 1 of embodiment 2 of the present utility model.Figure 14 shows other section of the formation of the related bulb-shaped lamp 1 of embodiment 2 of the present utility model, and is to illustrate from the state of Figure 13 centered by lamp axle, to rotate the profile approximately 90 °.And, be to become the axle that becomes pivot in the time bulb-shaped lamp 2 being installed to the socket of lighting device as lamp axle, consistent with the rotating shaft of lamp holder 280.And, in Figure 13 and Figure 14, except component, the section part of each component parts is only shown.And, in Figure 14, omit the diagram of component.
[enclosed globe shade]
As shown in Figure 12 to Figure 14, the formation of enclosed globe shade 210 is identical with the enclosed globe shade 10 in embodiment 1.
[LED module]
LED module 220 is identical with the LED module 20 in embodiment 1, to there is LED (LED chip), and carry out luminous light emitting module (light-emitting device) by the electric power that is fed into LED through going between 270a and 270b, emit the light of the wavelength of regulation.LED module 220 is maintained at the inner space of enclosed globe shade 210 by support unit 240.
As shown in Figure 13 and Figure 14, LED module 220 is configured in the inner space of enclosed globe shade 210.LED module 220 is preferably configured in the center (the inner space part that for example, the internal diameter of enclosed globe shade 210 is large) of the ball shape being made up of enclosed globe shade 210.Like this, by LED module 220 being configured to the center of enclosed globe shade 210, thereby the light distribution characteristic of bulb-shaped lamp 2 can be with employing in the past the incandescent lamp bulb of heater winding approximate.
And, treat aftermentioned for the detailed formation of LED module 220.
[bonded block]
Bonded block 230 is the parts for enclosed globe shade 210, support unit 240, metal parts 260 are carried out to combination.As shown in figure 12, bonded block 230 is constituted as ring-type, is trapped among the pedestal 242 (the little 242a of portion in footpath) of support unit 240 around.Bonded block 230 can for example, be hardened and be carried out moulding by the mobility insulating resin in the gap of the outer edge 252a of the outer peripheral face of the pedestal 242 to flowing into support unit 240 and outside frame 252 (silicon).
As shown in Figure 13 and Figure 14, bonded block 230 possesses: the 230a of vertical slot portion, be formed circularly, and insert for the peristome 211 that makes enclosed globe shade 210; Flange part (annular convex) 230b, is formed to transverse direction and gives prominence to, for being embedded into the translot portion of the pedestal 242 that is arranged on support unit 240; And four protuberance 230c, for the position alignment of pedestal 242, and (lamp holder side) is outstanding downwards.And the outer surface of bonded block 230 contacts with the inner surface of the outside frame 252 of framework 250.
[support unit]
Support unit 240 is the parts for supporting LED module 220, is made up of metal.Support unit 240 (metal mainstay) mainly forms by being positioned at the pillar 241 of inner space of enclosed globe shade 10 and the pedestal 242 mainly being surrounded by framework 250 (outside frame 252).In the present embodiment, pillar 241 and pedestal 242 by identical material by one-body molded.
Pillar 241 is the metal plugs that nearby extend setting to the inner space of enclosed globe shade 210 from the peristome 211 of enclosed globe shade 210.Pillar 241 plays a role as the holding member that keeps LED module 220, and one end of pillar 241 is connected with LED module 220, and the other end of pillar 241 is connected with pedestal 242.
And pillar 241 is owing to being made up of metal material, the thermal component that therefore can dispel the heat as the heat that LED module 220 is occurred plays a role.Pillar 241 in present embodiment is made up of aluminium alloy.Like this, because pillar 241 is made up of metal material, the heat that therefore LED module 220 can be occurred is transmitted to pillar 241 expeditiously.Accordingly, can suppress the reduction of luminous efficiency and the minimizing in life-span of the LED222 causing because of temperature rise.
Pillar 241 is made up of main shaft part 241a and fixed part 241b.Main shaft part 241a is that certain cylinder forms by sectional area, and the end of a side of main shaft part 241a is connected with fixed part 241b, and the end of the opposite side of main shaft part 241a is connected with pedestal 242.
And fixed part 241b has the base station 221 of LED module 220 and the stationary plane (upper surface) being fixed.This stationary plane is the contact-making surface that fixed part 241b (pillar 241) contacts with the back side (LED module 220) of base station 221.LED module 220 is loaded in the stationary plane of fixed part 241b, is adhered to stationary plane by sticker etc.And, be equipped with the jut 241b1 outstanding to stationary plane at fixed part 241b.Jut 241b1 is constituted as, chimeric with the through hole 221a of base station 221 that is arranged on LED module 220.Jut 241b1 plays a role as the position specified part of the position of regulation LED module 220, when being constituted as plane and seeing, is shaped as elongate.
Pedestal 242 is parts of support column 241, as shown in Figure 13 and Figure 14, is constituted as the peristome 211 that stops up enclosed globe shade 210.Pedestal 242 is made up of metal material, same with pillar 241 in the present embodiment, is made up of aluminium alloy.Accordingly, be transmitted to the heat of the LED module 220 of pillar 241, can be transmitted to expeditiously pedestal 242.And pedestal 242 is the lid shape parts with stage portion, formed by the little 242a of portion in the little footpath of diameter and the large large 242b of portion in footpath of diameter.
The border of the little 242a of portion and the large 242b of portion in footpath in footpath, the translot portion that is circumferentially formed with of the little 242a of portion along footpath.And, be configured with bonded block 230 in the stage portion (on the large 242b of portion in footpath) of pedestal 242, chimeric by the flange part 230b of bonded block 230 and the translot portion of pedestal 242, thus bonded block 230 is fixed on pedestal 242.
The little 242a of portion in footpath, as shown in Figure 13 and Figure 14, not only supports pillar 241, and is the disc-shaped part that is constituted as the peristome 211 that stops up enclosed globe shade 210.Pillar 241 is formed on the central portion of the little 242a of portion in footpath.And the outer peripheral face of the little 242a of portion in footpath is that face contacts with face with the inner peripheral surface of bonded block 230.And the little 242a of portion is equipped with two through hole 242a1 that pass for make to go between 270a and 270b in footpath.
The formation of the large 242b of portion in footpath is for being substantially cylindric, and outer peripheral face is that face contacts with face with the inner peripheral surface of metal parts 260.Accordingly, the enough high efficiency metal parts 260 that is transmitted to of the heat energy of support unit 240 (pedestal 242).And the large 242b of portion is formed with four recess 242b1 in footpath, as in the time riveting with metal parts 260 to guide hole.
[framework]
Framework 250 is insulation crusts with insulating properties that inside has been configured drive circuit 270, is made up of inner side frame body (the first frame) 251 and outside frame (the second frame) 252.Framework 250 can be made up of insulative resin material, for example the resin forming by polybutylene terephthalate (PBT).
Inner side frame body 251, as shown in Figure 13 and Figure 14, is configured to surround drive circuit 270, be can not be visual from the outside of lamp to the internal part being configured (circuit case).Inner side frame body 251 has: the circuit cap 251a being configured to cover the mode of drive circuit 270 and the circuit maintaining part 251b that is configured to cover the mode of surrounding of drive circuit 270.Circuit cap 251a and the separated setting of circuit maintaining part 251b, and circuit cap 251a and circuit maintaining part 251b are configured with contactless state.
The upper surface shape of circuit cap 251a is to be configured along the inner surface configuration of the pedestal 242 of support unit 240.Accordingly, circuit cap 251a is embedded in the pedestal 242 of support unit 240, is twisted solid at support unit 240 by screw 290.
Circuit maintaining part 251b is constituted as drum.The lamp holder side end of circuit maintaining part 251b is connected with outside frame 252, and in the present embodiment, circuit maintaining part 251b and outside frame 252 are by one-body molded.And, be formed with the stage portion of the circuit substrate 271 for loading drive circuit 270 at the enclosed globe shade side end of circuit maintaining part 251b.
And outside frame 252 at least becomes a part for the peripheral device of lamp, be the state can see from lamp outside and the external component that is configured.Region beyond the part covering with lamp holder 280 in the outer peripheral face of outside frame 252 is exposed to lamp outside.In the present embodiment, outside frame 252 has the 252b of the portion that screws up that is exposed to the outer edge 252a of lamp outside and screws up with lamp holder 280.
Outer edge 252a has diameter, and than screwing up the 252b of portion, the large cylinder-like part that is roughly forms.In the present embodiment, the formation of outer edge 252a is to diminish gradually towards its diameter of lamp holder 280 1 sides., the inner peripheral surface of outer edge 252a and outer peripheral face tilt with respect to lamp axle.Because the outer surface of outer edge 252a is exposed in atmosphere, therefore, the heat that is transmitted to framework 250 is mainly dispelled the heat from the outer surface of outer edge 252a.
Screwing up the 252b of portion is made up of the diameter cylinder-like part that is roughly less than outer edge 252a.Be screwed into lamp holder 280 at the portion 252b of screwing up.The outer peripheral face that, screws up the 252b of portion is configured with the state contacting with the inner peripheral surface of lamp holder 280.
The outside frame 252 (outer edge 252a) with above this formation is constituted as, and surrounds pedestal 242 and the bonded block 230 of inner side frame body 251, metal parts 260, support unit 240.And, between the outer surface of the inner surface of side frame body 252 (outer edge 252a) and inner side frame body 251 (circuit cap 251a and circuit maintaining part 251b), be equipped with the interval of regulation outside.And, in the present embodiment, outside frame 252 (outer edge 252a) does not contact with metal parts 260, as shown in figure 14, between the inner surface of outside frame 252 (outer edge 252a) and the outer surface of metal parts 260, has certain space.
[metal parts]
Metal parts 260 is constituted as sleeve-shaped, to surround the inner side frame body 251 in framework 250, and is configured between inner side frame body 251 and outside frame 252.Accordingly, metal parts 260 can become contactless state with drive circuit 270, thereby can guarantee the insulating properties of drive circuit 270.
And metal parts 260 is made up of metal material, plays a role as radiator.Accordingly, the heat that can utilize metal parts 260 to occur LED module 220 and drive circuit 270 is dispelled the heat expeditiously.Particularly, the heat of LED module 220 and drive circuit 270, via inner side frame body 251 and metal parts 260, is transmitted to outside frame 252, is rejected heat to lamp outside from outside frame 252.
As the metal material of metal parts 260, for example can adopt Al, Ag, Au, Ni, Rh, Pd, or by the two or more alloys that form of these metals, or can consider alloy of Cu and Ag etc.This metal material, owing to having good heat conductivity, can conduct the heat to metal parts 260 expeditiously.
And metal parts 260 contacts with support unit 240.In the present embodiment, as previously discussed, the inner peripheral surface of metal parts 260 is that face contacts with face with the outer peripheral face of the pedestal 242 (the large 242b of portion in footpath) of support unit 240.Because metal parts 260 and support unit 240 form by metal, therefore, the heat energy that is transmitted to the LED module 220 of support unit 240 is transmitted to metal parts 260 enough expeditiously.
And, metal parts 260 in present embodiment does not contact with outside frame 252 in framework 250 (outer edge 252a, screw up the 252b of portion), does not also contact with inner side frame body 251 (circuit cap 251a, circuit maintaining part 251b)., metal parts 260 is to be non-contacting state and to be configured with inner side frame body 251 and outside frame 252.Accordingly, can fully guarantee the insulating properties that framework 250 is all.
[drive circuit]
Drive circuit (circuit unit) 270 has the light a lamp lamp circuit (power circuit) of (luminous) of LED222 for making LED module 220, and the electric power of regulation is supplied to LED module 220.For example, drive circuit 270 comprises by pair of lead wires 270c and 270d, and the alternating current of supplying with from lamp holder 280 is converted to galvanic circuit, via pair of lead wires 270a and 270b, this direct current is supplied to LED module 220.
And drive circuit 270 also has the light adjusting circuit that the light modulation of LED222 is controlled.That is, drive circuit 270 changes by the size that makes the electric current that is supplied to LED222, thereby the light modulation of LED222 is controlled.
At this, drive circuit 270 is made up of circuit substrate 271 and multiple components (electronic component) 272 of being installed in circuit substrate 271.Circuit substrate 271 is the printed circuit board (PCB)s that formed by pattern by metal wiring, and the multiple components 272 that are installed in this circuit substrate 271 are electrically connected to each other.In the present embodiment, circuit substrate 271 is with interarea and the orthogonal state of lamp axle and be configured.As shown in figure 14, quilt loads in the circuit maintaining part 251b of inner side frame body 251 and is held circuit substrate 271.
Component 272 is for example various electric capacity, resistive element, convertor circuit element, coil part, choking-winding (choke transformer), noise filter, diode or integrated circuit component etc.
There is the drive circuit 270 of this formation because the inner side frame body 251 by framework 250 covers, therefore become contactless state with metal parts 260.Like this, can guarantee the insulating properties of drive circuit 270.
And drive circuit 270 is not limited only to lamp circuit or light adjusting circuit, also can select rightly and combine booster circuit etc.
[lead-in wire]
Lead-in wire 270a to 270d is alloyed copper lead-in wire, and the resin coating of the insulating properties of the heart yearn being made up of alloyed copper and coated this heart yearn forms.
Pair of lead wires 270a and 270b are for by the direct current that LED module 220 is lit a lamp, and are supplied to the electric wire of LED module 220 from drive circuit 270.Drive circuit 270 is electrically connected by pair of lead wires 270a and 270b with LED module 220.Particularly, the end (heart yearn) of one end separately of lead-in wire 270a and 270b, be electrically connected with the electric power efferent (metal wiring) of circuit substrate 271 by scolding tin etc., the end (heart yearn) of the other end is separately electrically connected with the electric power input part (electrode terminal) of LED module 220 by scolding tin etc.
And pair of lead wires 270c and 270d will be supplied to the electric wire of drive circuit 270 from the alternating current of lamp holder 280.Drive circuit 270 is electrically connected via pair of lead wires 270c and 270d with lamp holder 280.Particularly, the end (heart yearn) of one end separately of lead-in wire 270c and 270d is electrically connected with lamp holder 280 (shell portion or contact chip portion), and the end (heart yearn) of the other end is separately electrically connected with the electric power input part (metal wiring) of circuit substrate 271 by scolding tin etc.
[lamp holder]
As shown in Figure 13 and Figure 14, lamp holder 280 is from the outside power receiving section of accepting the luminous electric power of LED222 for making LED module 220 of lamp.Lamp holder 280 is for example installed in the socket of ligthing paraphernalia, and in the time that bulb-shaped lamp 2 is lit a lamp, lamp holder 280 is accepted electric power from the socket of ligthing paraphernalia.For example, lamp holder 280 is supplied to alternating current from source power supply (AC100V).Lamp holder 280 in present embodiment is accepted alternating current by two contacts, and the electric power of accepting at lamp holder 280 is imported into the electric power input part of drive circuit 270 by pair of lead wires 270c and 270b.
Lamp holder 280 is the metal end cylindrical shell shape that has, and having outer peripheral face is the shell portion of male thread and the contact chip portion that is installed in shell portion by insulation division.And the outer peripheral face of lamp holder 280 has been formed the portion of screwing up, for screwing up the socket of lighting device, be formed with the portion that screws up of the 252b of the portion that screws up for screwing up outside frame 252 at the inner peripheral surface of lamp holder 280.
The kind of lamp holder 280 does not have special restriction, adopts in the present embodiment the lamp holder of the Edison screw (E type) of screw-type.For example, the lamp holder adopting as lamp holder 280 for example has E26 shape, E17 shape or E16 shape etc.And, also can adopt plug-in type lamp holder as lamp holder 280.
[the detailed formation of LED module]
Then, utilize Figure 15 and Figure 16 to describe each inscape of the related LED module 220 of embodiment 2 of the present utility model.Figure 15 shows the formation of the related LED module of embodiment 2 of the present utility model.That is, (a) of Figure 15 is the top view (plane) of this LED module, and (b) of Figure 15 is the profile of this LED module after cutting along the A1-A1 ' line of (a).
As Figure 15 (a) and (b), LED module 220 has: base station 221, LED222, seal member 223a, wavelength conversion parts 223b and metal wiring 224.LED module 220 in present embodiment is identical with the LED module 20 in embodiment 1, is COB structure.Below, each inscape of LED module 220 is elaborated.
First, base station 221 is carried out.Base station 221 is the LED mounting substrates for LED222 is installed.Can adopt the substrate 21 in embodiment 1 as base station 221.Base station 221 in present embodiment is by being that the parts with light transmission form to visible ray.Have the base station 221 of light transmission by employing, the light of LED222 can see through the inside of base station 221, and face (back side) ejaculation of LED222 is never installed.Therefore,, even the face (surface) of a side that is only installed in base station 221 at LED222, also can penetrate light from the face of opposite side (back side), thereby obtain the light distribution characteristic approximate with incandescent lamp bulb.
Base station 221 preferably adopts the parts that full transmitance is high to make.For example, can adopt by being more than 90% sintered alumina (Al to the full transmitance of visible ray as base station 221
2o
3) form ceramic substrate.In addition, also can adopt as base station 221 ceramic substrate being formed by AlN or MgO.
And, adopt as the shape of the base station 221 in present embodiment, in the time overlooking, (from the top of enclosed globe shade 210 time) is the rectangular substrate of elongate.Like this, the shape of LED module 20 in the time overlooking also becomes elongate.
And, be set up through hole 221a, 221b at base station 221.Through hole 221a is for making base station 221 be set up with the fixed part 241b tabling of the pillar 241 of support unit 240.In the present embodiment, through hole 221a plane is rectangular-shaped, is formed on from the position that has departed from the longitudinal direction at base station 221 center.On the other hand, through hole 221b is owing to being electrically connected with two lead-in wires 270a and 270b, thereby has been set up two, in the present embodiment, is arranged on the both ends of the length direction of base station 221.
And, though adopt light-transmitting substrate as base station 221, the low low transmission substrate (for example full transmitance is the white substrates such as the white alumina substrate below 10%) of light transmission rate of the light that LED222 is sent also can be adopted.And, also can adopt the almost nil light tight substrate of full transmitance (for example substrate taking metal the end of as) as base station 221.And, in the situation that adopting these base stations, adopt two base stations 221 that only form LED222, seal member 223a and wavelength conversion parts 223b on surface, and by being fitted each other in the back side of two base stations 221, form a LED module.Or, can form LED222, seal member 223a and wavelength conversion parts 223b by the two sides at a base station, thereby form a LED module.
Then, LED222 is described.LED222 is an example of the semiconductor light-emitting elements luminous by the electric power specifying, is the bare chip that sends monochromatic visible ray being configured on base station 221.LED222 is modulated light by the big or small variation of the electric current of supplying with from drive circuit 270.In the present embodiment, adopt the blue led chip that can send blue light in the time of energising.And LED222 is only installed in the face (surface) of a side of base station 221, multiple (for example 12) LED222 element line forming that forms a line is configured to four row with linearity.
And, though multiple LED222 have been installed in the present embodiment, the number of LED222 can be done suitably and change according to the purposes of bulb-shaped lamp.For example, in the LED lamp of the low output types such as alternative pea lamp, LED222 can be also one.And in the LED of high output type lamp, the number of the LED222 in row can be also more than 12.And in the present embodiment, multiple LED222 have been mounted four row on base station 221, but it can be also the multiple row beyond row or four row.
And the formation of the LED222 adopting in present embodiment is identical with the LED22a (LED chip) in the embodiment 1 shown in Fig. 5.
Then, with reference to Figure 15 and utilize Figure 16 to be elaborated to seal member 223a and wavelength conversion parts 223b.Figure 16 shows seal member in the related LED module of embodiment 2 of the present utility model and the formation of wavelength conversion parts.Particularly, Figure 16 shows seal member in the LED module after cutting along the B1-B1 ' line of Figure 15 (a) and a part of amplification profile of wavelength conversion parts.
Seal member 223a is equivalent to the main light emission portion (wavelength conversion parts) in embodiment 1, is the illuminating part self with light-emitting component, has multiple LED222 in seal member 223a.Seal member 223a is formed linearity in the mode that covers the multiple LED222 (sealing in the lump) in row.In the present embodiment, because the element line of LED222 has been mounted four row, four seal member 223a have therefore been formed.And, seal member 223a comprises the fluorophor as optical wavelength conversion material, play a role as the first wavelength transformation component (the first wavelength transform component), this first wavelength transformation component is the wavelength conversion layer that light that LED222 is sent carries out wavelength conversion.Can adopt as seal member 223a, in silicones disperse regulation fluorophor particle (not shown) and photodiffusion material (not shown) contain fluorophor resin.
As fluorophor particle, be to send the blue led chip of blue light at LED222, in order to obtain white light, same with embodiment 1, the yellow fluorophor particle that for example can adopt YAG to be.And in the present embodiment, owing to having adopted the base station 221 with light transmission, the white light therefore penetrating from seal member 223a sees through the inside of base station 221, and penetrates from the back side of base station 221.
And, same with embodiment 1, as the fluorophor particle comprising in seal member 223a, can also add red-emitting phosphors particle.
The seal member 223a with this formation is same with embodiment 1, for example, can for example, for example,, by containing the seal member material (silicones) of unhardened paste shape of wavelength shifter (fluorophor particle), apply and make it to harden to form by distributor.
And seal member 223a also can be formed by silicones, except the organic resins such as fluorine resin, can also by low melting point glass or or the inorganic material such as the glass made of sol-gal process form.
Wavelength conversion parts 223b is configured in, and compared with seal member 223a, from the position away from LED222, plays a role as second wave length transformation component, and this second wave length coversion material is the wavelength conversion layer that light wavelength that LED222 is sent converts.Particularly, wavelength conversion parts 223b is the resin of the side that is configured in seal member 223a on base station 221., wavelength conversion parts 223b has been formed two with linearity between two seal member 223a.
Wavelength conversion parts 223b is equivalent to the secondary illuminating part (illusory seal member) in embodiment 1, and self does not have LED, is that the light being sent by the LED of wavelength conversion parts 223b outside carrys out luminous illuminating part.In wavelength conversion parts 223b, do not exist and can carry out wavelength conversion and luminous light-emitting component by these wavelength conversion parts 223b.
Wavelength conversion parts 223b in present embodiment is same with seal member 223a, comprises the fluorophor particle as optical wavelength conversion material, and wavelength conversion parts 223b is constituted as, and the concentration ratio seal member 223a of contained fluorophor particle is high.At this, the concentration of this fluorophor particle is higher, and the amount (wavelength conversion amount) of light wavelength conversion is just larger.Wavelength conversion amount shows the amount of the degree that light wavelength is converted, and wavelength conversion amount is larger, and the degree that light wavelength is converted is just higher.; the second wave length converted quantity of the degree that light wavelength that the LED222 in wavelength conversion parts 223b is sent converts is shown, larger than the first wavelength converted quantity that the degree that light wavelength that the LED222 in seal member 223a is sent converts is shown.And the fluorophor particle comprising in wavelength conversion parts 223b is due to identical with the fluorophor particle comprising in seal member 223a, therefore detailed.
Wavelength conversion parts 223b is same with seal member 223a, for example can for example, for example,, by containing the seal member material (silicones) of unhardened paste shape of wavelength shifter (fluorophor particle), apply and make it to harden to form by distributor.
In the present embodiment, seal member 223a and wavelength conversion parts 223b adopt fluorophor particle to disperseing regulation in silicones containing fluorophor resin.
Then, metal wiring 224 is described.Metal wiring 224 is same with the metal wiring 26 in embodiment 1, be the distribution being made up of the metal of the Ag being formed by pattern at LED installed surface (surface) etc., the electric power that is supplied to LED module 220 from lead-in wire 270a and 270b is fed into each LED222.Each LED222 is electrically connected with metal wiring 224 by golden wire 225.
And the metal wiring 224 that is formed on the surrounding of through hole 221b becomes power supply.Article two, the leading section break-through of lead-in wire 270a and 270b, to the 221b of through hole shown in Figure 13, is electrically connected and physical connection with metal wiring 224 by scolding tin etc.
As previously discussed, formed the bulb-shaped lamp 2 that possesses the related LED module of present embodiment 220.Like this, the bulb-shaped lamp 2 in present embodiment has adopted the identical enclosed globe shade of enclosed globe shade (glass bulb) shape using with incandescent lamp bulb, and, on the pillar 241 extending in the inner space to enclosed globe shade 210, be provided with LED module 220.Accordingly, can realize the large light distribution characteristic in luminous intensity distribution angle, thereby can obtain the light distribution characteristic same with incandescent lamp bulb.
And, in the LED module 220 that bulb-shaped lamp 2 in the present embodiment possesses, possess, as the seal member 223a of the first wavelength transformation component and as the wavelength conversion parts 223b of second wave length transformation component, these wavelength conversion parts 223b is configured in, compared with seal member 223a, from the position away from LED222.And, the degree (wavelength conversion amount) that the light wavelength that LED222 in wavelength conversion parts 223b is sent converts, the degree (wavelength conversion amount) that the light wavelength that the LED222 in comparison seal member 223a sends converts is large.At this, utilize Figure 17 to describe the effect that there is the LED module 220 of above-mentioned formation and realize.
Figure 17 is the figure for the effect that the related LED module of embodiment 2 of the present utility model realizes is described.Particularly, Figure 17 (a) shows while carrying out brightness adjustment control, is supplied to the irradiating state of the light that the LED222 in the situation that the electric current of LED222 is little sends.And Figure 17 (b) shows in the time carrying out brightness adjustment control, be fed into the irradiating state of the light that the LED222 in the situation that the electric current of LED222 is large sends.
As shown in Figure 17 (a), in the time carrying out brightness adjustment control, in the case of be supplied to the electric current of LED222 little, owing to irradiating low light level L1 from LED222, after seeing through seal member 223a, the amount of light that arrives wavelength conversion parts 223b is less.At this, in the case of be supplied to the electric current of LED222 little, the ratio of specific heat of being sent by LED222 is less, therefore the reducing amount of the wavelength conversion efficiency of seal member 223a is less.Therefore, the light that sees through seal member 223a can not be subject to the impact of wavelength conversion Efficiency Decreasing, and user can visually arrive.
And, as shown in Figure 17 (b), in the time carrying out brightness adjustment control, be fed in the situation of electric current increase of LED222, owing to irradiating Strong light L2 from LED222, after seeing through seal member 223a, the amount that arrives the light of wavelength conversion parts 223b increases.At this, in the case of be supplied to the electric current of LED222 large, because the heat occurring from LED222 is more, the therefore wavelength conversion Efficiency Decreasing of seal member 223a.Therefore,, although be subject to the impact of the reduction of wavelength conversion efficiency through the light of seal member 223a, this light can also see through wavelength conversion parts 223b.
At this, the degree that the light wavelength that the LED222 in wavelength conversion parts 223b is sent converts, the degree that the light wavelength that the LED222 in comparison seal member 223a sends converts is large.Therefore,, because this light also can see through wavelength conversion parts 223b, therefore can reduce the impact of the reduction of the wavelength conversion efficiency causing because of seal member 223a.
As previously discussed, by the related LED module 220 of embodiment 2 of the present utility model, even in the situation that carrying out brightness adjustment control, also can reduce the impact of the wavelength conversion Efficiency Decreasing that the light that sends because of LED222 causes, thereby can suppress the variation of the color of the light penetrating.
And wavelength conversion parts 223b is the resin of the side that is configured in seal member 223a on base station 221.Like this, in LED module 220, by wavelength conversion parts 223b being configured in to the side of seal member 223a, thereby the impact of the wavelength conversion Efficiency Decreasing that the light that sends because of LED222 causes can be easily reduced, and the variation of the color of the light penetrating can be suppressed.
And the concentration ratio seal member 223a of the contained fluorophor particle of wavelength conversion parts 223b is high.Like this, in LED module 220, by fluorophor particle contain concentration adjustment, thereby can easily reduce the impact of the wavelength conversion Efficiency Decreasing that light that LED222 sends causes, and can suppress the variation of the color of the light penetrating.
And, at above-mentioned embodiment 2, although seal member 223a be configured in the mode of surrounding that covers LED222, but seal member 223a also can be configured to cover at least a portion of LED222.
(variation of embodiment 2)
The variation of the LED module 220 then, bulb-shaped lamp 2 being possessed describes.And in following variation, the inscape beyond the LED module that bulb-shaped lamp possesses, because the inscape possessing with the bulb-shaped lamp 2 in above-mentioned embodiment 2 is identical, is therefore omitted the explanation to the inscape beyond LED module.
(variation 1 of embodiment 2)
Utilize Figure 18 to Figure 20 to describe each inscape of the related LED module 220A of the variation 1 of embodiment 2 of the present utility model.Figure 18 shows the formation of the related LED module of the variation 1 of embodiment 2 of the present utility model.That is, (a) of Figure 18 is the plane of this LED module, and (b) of Figure 18 is the profile of the LED module after cutting along the A2-A2 ' line of (a).
As Figure 18 (a) and (b), LED module 220A has base station 221, LED222, seal member 223a, metal wiring 224 and luminescent coating 227., the LED module 220A in this variation does not have the wavelength conversion parts 223b of the LED module 220 in above-mentioned embodiment 2.And the LED module 220A in this variation has luminescent coating 227.And, base station 221, LED222, seal member 223a and the metal wiring 224 that LED module 220A possesses due to LED module 220 in above-mentioned embodiment 2 to possess base station 221, LED222, seal member 223a and metal wiring 224 identical, therefore detailed.
Utilize Figure 19 and Figure 20 to describe luminescent coating 227.Figure 19 is the amplification profile of the LED periphery in the related LED module of the variation 1 of embodiment 2 of the present utility model.And Figure 20 is the major part amplification profile of the related LED module of the variation 1 of embodiment 2 of the present utility model.Particularly, the amplification profile of the formation of a seal member periphery of the LED module of Figure 20 after cutting along the B2-B2 ' line of Figure 18 (a).
Luminescent coating 227 is formed between each of base station 221 and multiple LED222, is the printing fluorophor (wavelength conversion parts) that comprises the optical wavelength conversion material that light wavelength that LED222 is sent converts.That is, on base station 221, print luminescent coating 227, on the luminescent coating 227 that this is printed, LED222 is installed.
At this, as the optical wavelength conversion material comprising in luminescent coating 227,223a is same with seal member, adopts the light stimulus of being sent by LED222 and emits the fluorophor particle of the light of desirable color (wavelength).For example, luminescent coating 227 is by fluorophor particle and sintering bond material and the sintered body film forming.And the fluorophor particle comprising in luminescent coating 227 is due to identical with the fluorophor particle comprising in seal member 223a, therefore detailed.
And, as sintering bond material, can adopt with silica (SiO
2) be the inorganic material such as frit that the material of main component forms.Frit is for fluorophor particle being combined in to the bond material (grafting material) on base station 221, by the high material of the transmitance of visible ray is formed.Frit can form by glass powder is heated and dissolved.Glass powder as frit can adopt SiO
2-B
2o
3-R2
osystem, B
2o
3-R
2o system or P
2o
5-R
2o is (but, R
2o is, Li
2o, Na
2o or K
2o).And the material as sintering in conjunction with material, except frit, can also adopt the SnO being made up of low melting point crystallization
2-B
2o
3deng.
And luminescent coating 227 is between base station 221 and LED222, by adhering and be formed with base station 221.The sticker that, luminescent coating 227 self has by luminescent coating 227 is fixed on base station 221.Luminescent coating 227 in this variation be positioned at each LED222 under, on base station 221, be formed as island., each of luminescent coating 227 and multiple LED222 is corresponding, has been formed multiple.And luminescent coating 227 is formed in the mode not contacting with the metal wiring 224 being formed between adjacent LED222.
And as shown in figure 20, in middle position, (center in XY plane) has central portion 227a to luminescent coating 227, has end 227b in the outside of central portion 227a (around the central portion 227a in XY plane)., central portion 227a and end 227b are the luminescent coatings that is formed one between base station 221 and LED222.
Central portion 227a is configured to cover at least a portion of LED222, and the first wavelength transformation component converting as the light wavelength that LED222 is sent plays a role., central portion 227a be the below that is configured in LED222 (under) rectangular-shaped optical wavelength conversion material.
End 227b is configured in than central portion 227a from the position away from LED222, and the second wave length transformation component converting as the light wavelength that LED222 is sent plays a role., end 227b is the optical wavelength conversion material being in the form of a ring configured in the mode round LED222.
And luminescent coating 227 is constituted as, more away from LED222, thickness (width of Z-direction) is thicker., end 227b is thicker than the thickness of central portion 227a.Particularly, the upper surface of end 227b is formed curved surface, and more away from the position of central portion 227a, thickness is thicker.For example, the thickness of central portion 227a is tens of μ m, and the maximum ga(u)ge of end 227b is hundreds of μ m.
At this, this thickness is thicker, and the amount (wavelength conversion amount) that light wavelength is converted is just larger.Wavelength conversion amount illustrates the amount of the degree that light wavelength is converted, and wavelength conversion amount is larger, and the degree that light wavelength is converted is just higher.That is, the second wave length converted quantity of the degree that light wavelength that the LED222 in the 227b of end is sent converts is shown, larger than the first wavelength converted quantity that the degree that light wavelength that the LED222 in central portion 227a is sent converts is shown.Like this, luminescent coating 227 is constituted as, more just larger away from the LED222 light wavelength converted quantity that LED222 sends.
As shown above, in the LED module 220A in this variation, possess as the central portion 227a of the first wavelength transformation component and as the end 227b of second wave length transformation component, this end 227b is configured in the position away from LED222 than central portion 227a.And base station 221 has light transmission, central portion 227a and end 227b are the luminescent coatings that is formed one between base station 221 and LED222.And, the degree (wavelength conversion amount) that the light wavelength that the LED222 in the 227b of end is sent converts, the degree (wavelength conversion amount) that the light wavelength that the LED222 in comparison central portion 227a sends converts is large.Therefore, the LED module 220A in this variation can realize the effect identical with LED module 220 in above-mentioned embodiment 2.Particularly, utilize Figure 21 to describe the effect that there is the LED module 220A of above-mentioned formation and realize.
Figure 21 is the figure of the effect that realizes of the related LED module of variation 1 for embodiment 2 of the present utility model is described.Particularly, (a) of Figure 21 shows in the time carrying out brightness adjustment control, in the case of being fed into the irradiating state of the light that the electric current of LED222 sends from LED222 little.And Figure 21 (b) shows in the time carrying out brightness adjustment control, be fed into the irradiating state of the light of emitting from LED222 in the situation that the electric current of LED222 is large.
As shown in Figure 21 (a), in the time carrying out brightness adjustment control, in the case of be fed into the electric current of LED222 little, owing to irradiating the low light level from LED222, therefore arrive the amount of light of end 227b towards the light L3 of the rear side of base station 221 less.At this, in the case of be fed into the electric current of LED222 little, because the heat that LED222 occurs is less, therefore the reducing amount of the wavelength conversion efficiency of luminescent coating 227 is also few.Therefore, the light irradiating from LED222 can not be subject to the impact of wavelength conversion Efficiency Decreasing, and user can visually arrive.
And, as shown in Figure 21 (b), in the time carrying out brightness adjustment control, in the case of be fed into the electric current of LED222 large, owing to irradiating Strong light from LED222, the amount that therefore arrives the light of end 227b in the light L4 of the rear side of base station 221 increases.At this, in the case of be fed into the electric current of LED222 large, the heat occurring due to LED222 increases, therefore the wavelength conversion Efficiency Decreasing of luminescent coating 227.Therefore,, although the light irradiating from LED222 is subject to the impact of wavelength conversion Efficiency Decreasing, this light can pass through end 227b.
At this, the degree that the light wavelength that the LED222 in the 227b of end is sent converts, the degree that the light wavelength that the LED222 in comparison central portion 227a sends converts is large.Therefore,, because this light can pass through end 227b, therefore can reduce the impact causing because of the reduction of wavelength conversion efficiency.
As previously discussed, by the related LED module 220A of embodiment 2 of the present utility model, even the in the situation that of modulated light, in the light of the rear side of base station 221, also the impact that the reduction of the light wavelength conversion efficiency of sending because of LED222 causes can be reduced, and the variation of the color of the light penetrating can be suppressed.
And end 227b is thicker than the thickness of central portion 227a.Like this, in LED module 220A, by adjusting the thickness of luminescent coating 227, thereby can easily reduce the impact that the reduction of the light wavelength conversion efficiency of sending because of LED222 causes, and can suppress the variation of the color of the light penetrating.
(variation 2 of embodiment 2)
Utilize Figure 22 and Figure 23 to describe each inscape of the related LED module 220B of the variation 2 of embodiment 2 of the present utility model.Figure 22 and Figure 23 show the formation of the related LED module of the variation 2 of embodiment 2 of the present utility model.That is, (a) of Figure 22 is the plane of LED module 220B, and (b) of Figure 22 is the profile of this LED module 220B after cutting along the A3-A3 ' line of (a).And Figure 23 illustrates the seal member 223a of this LED module 220B after cutting along the B3-B3 ' line of Figure 22 (a) and the major part amplification profile of the formation of wavelength conversion parts 223b periphery.
As shown in Figure 22 and Figure 23, LED module 220B possesses: base station 221, LED222, seal member 223a, wavelength conversion parts 223b, metal wiring 224 and luminescent coating 227., the LED module 220B in this variation is same with the LED module 220 in above-mentioned embodiment 2, has wavelength conversion parts 223b.And the LED module 220B in this variation is same with the LED module 220A in above-mentioned variation 1, has luminescent coating 227.
And, base station 221, LED222, seal member 223a, wavelength conversion parts 223b and metal wiring 224 that LED module 220B possesses, same with base station 221, LED222, seal member 223a, wavelength conversion parts 223b and metal wiring 224 that the LED module 220 in above-mentioned embodiment 2 possesses, therefore detailed.And LED module luminescent coating that 220B possesses 227 is due to identical with the LED module luminescent coating that 220A possesses 227 in above-mentioned variation 1, therefore detailed.
That is, seal member 223a plays a role as the first wavelength transformation component, and wavelength conversion parts 223b plays a role as second wave length transformation component, and luminescent coating 227 plays a role as three-wavelength transformation component.
As previously discussed, by the LED module 220B in this variation, can realize the effect identical with LED module 220A in LED module 220 and variation 1 in above-mentioned embodiment 2.
(variation 3 of embodiment 2)
Utilize Figure 24 to carry out the formation of the related LED module 220C of the variation 3 of embodiment 2 of the present utility model.Figure 24 is the major part amplification profile of the related LED module of the variation 3 of embodiment 2 of the present utility model.Particularly, Figure 24 is the fragmentary cross-sectional view of the seal member 223a of LED module 220C.At this, this variation can be suitable for the LED module 220B in LED module 220A and the variation 2 in above-mentioned variation 1.
As shown in figure 24, in LED module 220C, possesses luminescent coating 228, the luminescent coating 227 being possessed to replace above-mentioned variation 1 and variation 2.And, in the LED module 220C in this variation, for the inscape beyond luminescent coating 228 due to identical with the inscape beyond luminescent coating 227 in above-mentioned variation 1 and variation 2, therefore detailed.
Luminescent coating 228 is formed between each of base station 221 and multiple LED222, is the printing fluorophor that comprises the optical wavelength conversion material that light wavelength that LED222 is sent converts.The middle position (center in XY plane) of luminescent coating 228 has central portion 228a, and the outside (the central portion 228a in XY plane around) of central portion 228a has end 228b.
And end 228b is thicker than the thickness of central portion 228a (width of Z-direction).Particularly, the upper surface of end 228b is formed step-like plane, and more away from central portion 228a, thickness is thicker., for the shape that the thickness having for the end 227b in above-mentioned variation 1 and variation 2 slowly changes, the end 228b in this variation has the shape that thickness is step-like variation.And the luminescent coating 228 in this variation is except shape, all the other are all identical with the luminescent coating 227 in above-mentioned variation 1 and variation 2, therefore detailed.
That is, the second wave length converted quantity of the degree that light wavelength that the LED222 in the 228b of end is sent converts is shown, larger than the first wavelength converted quantity that the degree that light wavelength that the LED222 in central portion 228a is sent converts is shown.
And in the case of this variation being applicable to the LED module 220A in above-mentioned variation 1, central portion 228a plays a role as the first wavelength transformation component, end 228b plays a role as second wave length transformation component.And, in the case of this variation being applicable to the LED module 220B in above-mentioned variation 2, seal member 223a plays a role as the first wavelength transformation component, wavelength conversion parts 223b plays a role as second wave length transformation component, and luminescent coating 228 plays a role as three-wavelength transformation component.
As previously discussed, by the LED module 220C in this variation, can realize the effect identical with LED module 220B in LED module 220A and variation 2 in above-mentioned variation 1.
(variation 4 of embodiment 2)
Utilize Figure 25 to describe the formation of the related LED module 220D of the variation 4 of embodiment 2 of the present utility model.Figure 25 is the major part amplification profile of the related LED module of the variation 4 of embodiment 2 of the present utility model.Particularly, Figure 25 is the fragmentary cross-sectional view of the seal member 223a of LED module 220D.At this, this variation can be applicable to the LED module 220B in LED module 220A and the variation 2 in above-mentioned variation 1.
As shown in figure 25, LED module 220D possesses luminescent coating 229, the luminescent coating 227 being possessed to replace above-mentioned variation 1 and variation 2.And in the LED module 220D of this variation, the inscape except luminescent coating 229 is due to all identical with the inscape beyond luminescent coating 227 in above-mentioned variation 1 and variation 2, therefore detailed.
Luminescent coating 229 is formed between each of base station 221 and multiple LED222, is the printing fluorophor that contains the optical wavelength conversion material that light wavelength that LED222 is sent converts.Luminescent coating 229 has the central portion 229a that is positioned at middle position (center in XY plane), and is positioned at the end 229b in the outside (the central portion 229a in XY plane around) of central portion 229a.
And luminescent coating 229 is constituted as, the concentration of the fluorophor particle more containing away from LED222 is just higher.That is, the thickness of end 229b is identical with the thickness (width of Z-direction) of central portion 229a, but the concentration ratio central portion 229a of the fluorophor particle containing is high.Particularly, end 229b is constituted as, and more away from the position of central portion 229a, the concentration of fluorophor particle is just higher.That is, in end 227b and end 228b in above-mentioned variation 1 to 3, more away from the position of LED222, thickness is with regard to thicker, and the end 229b in this variation is constituted as more that the concentration of fluorophor particle is just higher away from the position of LED222.And the fluorophor particle that the luminescent coating 229 in this variation comprises is identical with the fluorophor particle that the luminescent coating 227 in above-mentioned variation 1 and variation 2 comprises, therefore detailed.
By this formation, the second wave length converted quantity of the degree that light wavelength that the LED222 in the 229b of end is sent converts is shown, larger than the first wavelength converted quantity that the degree that light wavelength that the LED222 in central portion 229a is sent converts is shown.
And in the case of this variation being applicable to the LED module 220A in above-mentioned variation 1, central portion 229a plays a role as the first wavelength transformation component, end 229b plays a role as second wave length transformation component.And, in the case of this variation being applicable to the LED module 220B in above-mentioned variation 2, seal member 223a plays a role as the first wavelength transformation component, wavelength conversion parts 223b plays a role as second wave length transformation component, and luminescent coating 229 plays a role as three-wavelength transformation component.
As shown above, by the LED module 220D in this variation, can realize the effect identical with LED module 220B in LED module 220A and variation 2 in above-mentioned variation 1.,, in this variation, the concentration ratio central portion 229a of the contained fluorophor particle of end 229b is high.Like this, in LED module 220D, by fluorophor particle contain concentration adjustment, thereby can easily reduce the impact that the reduction of the light wavelength conversion efficiency of sending because of LED222 causes, and can suppress the variation of the color of the light being penetrated.
(variation)
Below, variation of the present utility model is described.
(variation 1)
Figure 26 shows the formation of the related LED module of variation 1 of the present utility model, (a) is plane, is (b) profile on the A-A ' line of (a).And Figure 27 is the figure for the method that the related LED module of variation 1 of the present utility model is assembled is described.
As shown in Figure 26 and Figure 27, the main light emission portion being made up of LED222 (light-emitting component) and seal member 223 is equipped with multiple on base station 221, by using as being embedded into of secondary illuminating part multiple masks 324 containing fluorophor resin (wavelength conversion parts) 323 overlap to the base station 221 that has been configured multiple main light emission portion, thereby can form LED module 320.
In mask 324 containing fluorophor resin 323 by fluorophor (wavelength shifter) is distributed in the resins such as silicones and is configured.Be equivalent to illusory seal member containing fluorophor resin 323, there is not the light-emitting components such as LED containing in fluorophor resin 323.
In the time that base station 221 is overlapped with mask 324, seal member 223 be configured to adjacent one another arely containing fluorophor resin 323, in this variation, seal member 223 is configured in adjacent one another are containing between fluorophor resin 323., though seal member 223 with containing fluorophor resin 323 in the row direction or on column direction, be alternate configurations each other.
Above, by the related LED module 320 of this variation, owing to can making to be equipped with the base station 221 of the illuminating part being formed by LED222 and seal member 223, to overlap with the mask 324 having containing fluorophor resin 323, thereby can strengthen all glow colors of LED module 320.And, can carry out color adjustment by the ratio containing fluorophor resin 323 changing in mask 324.
(variation 2)
Figure 28 is the perspective view that the formation of the related LED module of variation 2 of the present utility model is shown.
As shown in figure 28, in the related LED module 420 of this variation, main light emission portion that the seal member 223 sealing by LED222 with to LED222 forms, with the secondary illuminating part of illusory seal member 24X as not comprising LED, be not to be formed wire, but be all formed dome-shaped.
Seal member 223 is with illusory seal member 24X by adjacent setting, and in this variation, seal member 223 is configured between illusory seal member 24X adjacent one another are., though seal member 223 and illusory seal member 24X in the row direction or on column direction, be alternate configurations each other.
In this variation, also can realize and embodiment 1 and 2 identical effects.
And, in this variation, lose function by the colour switching that makes illusory seal member 24X, thereby can make the glow color of LED module produce color displacement.
Example as shown in figure 29, temporarily arranges part or all of multiple illusory seal member 24X, and by removing the temporary transient illusory seal member 24X arranging, thereby can make color displacement.
And as shown in figure 30, each of part or all of multiple illusory seal member 24X is by being covered by reflection part 400, thereby can carry out color displacement.Reflection part 400 is for example constituted as cup-shaped to cover the mode of illusory seal member 24X, and the outer surface of reflection part 400 has reflection function.
And, as shown in figure 31, by part or all of multiple illusory seal member 24X carried out to blacking etc. by black ink, make the table face ?look of illusory seal member 24X, thereby can realize color displacement.
And, shown in figure 32, led to part or all that covers multiple illusory seal member 24X with ?look mask 500, thereby can realize color displacement.
(other variation etc.)
Above, the bulb-shaped lamp related to the utility model is illustrated based on embodiment 1,2 and their variation, but the utility model is limit by these embodiments and variation not.
For example, in above-mentioned embodiment 1,2 and variation, not containing in the seal member of LED, can also add special fluorophor or light absorber and realize color displacement.Example as shown in figure 33, also can form LED module by red-emitting phosphors being mixed in the illusory seal member 24Y that contains yellow fluorophor.Accordingly, can realize red displacement.Or, also can in the illusory seal member 24Y that contains yellow fluorophor, sneak into green-emitting phosphor, realize green displacement.And, also can be by sneak into neodymium powder (light absorber) in the illusory seal member 24Y that contains yellow fluorophor, and remove the yellow color displacement that becomes to assign to realize.
And, in above-mentioned embodiment 1,2 and variation, by appending to main light emission portion containing fluorophor resin, thereby realize color displacement.(a) of for example Figure 34 and (b) shown in, by forming containing fluorophor resin 423 on the seal member 223 LED222 is sealed, realize color displacement.In this case, if containing fluorophor resin 423 be formed on LED222 directly over.Contain fluorophor resin 423 by fluorophor (wavelength shifter) is distributed in the resins such as silicones and is formed.And the section shape of seal member 223 can be the summary semicircular in shape shown in Figure 34 (a), can be also slightly rectangular shown in Figure 34 (b).
And, in above-mentioned embodiment 1,2 and variation, can be also in the mode relative with main light emission portion, luminescent coating is formed on to the back side of light-transmitting substrate.For example, shown in Figure 35 (a), in the mode relative with main light emission portion (LED222 and seal member 223), form luminescent coating 527 at the back side of light transmission base station 221.Can be, also that the mode that clips the base station 221 of light transmission forms main light emission portion and luminescent coating 527.Luminescent coating 527 is the wavelength conversion parts that comprise the optical wavelength conversion material that light wavelength that LED222 is sent converts.By this formation, the inside of the light transmission base station 221 penetrating from LED222, is transformed color by luminescent coating 527, therefore can penetrate from the back side of base station 221 light (for example white light) of desirable color.And, as shown in Figure 35 (b), also can prune a part for luminescent coating 527.Accordingly, can suppress the color of the light (back light) penetrating from base station 221.
And, in above-mentioned embodiment 1,2 and variation, although the formation of LED module is to emit white light by blue led chip and yellow fluorophor, but be not limited by this.For example, the formation that also can adopt is, utilize contain red-emitting phosphors and green-emitting phosphor containing fluorophor resin, and combine with blue led chip, emit white light.
And in above-mentioned embodiment 1,2 and variation, LED also can adopt the LED that sends blue color in addition.For example, in the case of adopting the LED chip of luminescence-utraviolet as LED22a to 22d, 32a, 32b, can combine the fluorophor particle of each color of sending three primary colors (red, green, blueness) as fluorophor particle.And, also can adopt fluorophor particle wavelength conversion material in addition, for example, can adopt as wavelength shifter, contain semiconductor, metal complex, organic dyestuff, pigment etc. the light of certain medium wavelength is absorbed, and send the material of the material of the light different from the light wavelength absorbing.
And, in above-mentioned embodiment 1,2 and variation, although show for example LED as light-emitting component, but also can adopt the semiconductor light-emitting elements such as semiconductor laser, or other the solid-state light emitting element such as the EL element such as organic EL (Electro Luminescence: electroluminescent) or inorganic EL.
And in above-mentioned embodiment 1,2 and variation, LED module, as the light-emitting component on substrate, has adopted the formation of the COB type of direct installation LED chip, but, is not limited by this.For example also can adopt the LED module of SMD type, specifically LED chip is installed in the recess (cavity) of resinous container, and will in this recess, form the LED element that encapsulates build containing fluorophor is recording member resin-enclosed, and utilize the LED element of this encapsulation build, using this LED element as light-emitting component, on the substrate that is formed with metal configuration, install multiple, thereby form the LED module of surface attaching type (SMD:Surface Mount Device).
And in above-mentioned embodiment 1,2 and variation, the situation that is applicable to bulb-shaped lamp taking LED module is illustrated as example, but, the related LED module of present embodiment also can be applicable to Straight lamp or circular lamp etc.In this case, the shape of the substrate of installation LED can form according to each lamp.And the LED module in the utility model also can be suitable for other the light source of equipment beyond lamp.
And, in above-mentioned embodiment 1 and variation, although lead-in wire is arranged on the outside of pillar, but can be also that the profile of bulb-shaped lamp 1A of Figure 36 is such, in pillar 40A, cavity is set, configures through in the cavity of pillar 40A by a part that makes lead-in wire.In this case, lead-in wire 70 cavities in supporting station 50 is directly inserted into pillar 40A, in nearby exposing from the side on the top of pillar of LED module 20, thereby be connected with LED module 20.Like this, can reduce the light of LED module 20 because of the phenomenon of 70 shadings that cause that go between.And, though in Figure 36, be that lead-in wire 70 is configured to pass substrate from the rear side of substrate, also can be configured to, around the face side to substrate, pass from the face side of substrate.
And, in above-mentioned embodiment 1 and variation, wavelength conversion parts (the first to the 6th seal member, the first to the 6th illusory seal member) are formed linearity, but also can be curve-like, other the shape such as the ring-type of meander-like or rounded, rectangle.In this case, LED can configure according to the shape of wavelength conversion parts.
And, in above-mentioned embodiment 1 and variation, though built-in non-luminous semi-conductor electricity sub-element (Zener diode) in the second illusory seal member 24b only, be not limited by this.For example, also non-luminous semi-conductor electricity sub-element (Zener diode) can be built in to the first illusory seal member 24a etc., in the illusory seal member of other beyond the second illusory seal member 24b.In this case, non-luminous semi-conductor electricity sub-element can be built in multiple illusory seal members.
And, in above-mentioned embodiment 2 and variation, screw up the 252b of portion as a part for outside frame 252, but, also can be used as a part for inner side frame body 251.That is, can will screw up the part of the 252b of portion as the circuit case for receiving drive circuit 270, more specifically, can will screw up the part of the 252b of portion as circuit maintaining part 251b.
And the utility model can be realized as the lighting device that possesses above-mentioned bulb-shaped lamp.Example as shown in figure 37, as the related lighting device of embodiment of the present utility model, can form the lighting device of the utensil of lighting a lamp (ligthing paraphernalia) 3 that possesses the related bulb-shaped lamp of above-mentioned embodiment 11 and this bulb-shaped lamp 1 has been installed.In this case, the utensil 3 of lighting a lamp for bulb-shaped lamp 1 is turned off the light and lit a lamp, for example, possesses and is installed in the appliance body 4 of ceiling and covers the light transmission of bulb-shaped lamp 1 or the lampshade of non-light transmittance 5.Wherein, appliance body 4 is mounted the lamp holder of bulb-shaped lamp 1, and has the socket 4a powering to bulb-shaped lamp 1.And, at the peristome of lampshade 5, light-passing board also can be set.And, as the bulb-shaped lamp that is installed in the utensil 3 of lighting a lamp, also can adopt the bulb-shaped lamp in the variation of bulb-shaped lamp 2 in embodiment 2 or embodiment 1,2.
In addition, in the situation that not departing from purport of the present utility model, the various distortion that those skilled in the art can be expected are executed in the formation of present embodiment and variation, or formation after the inscape in embodiment and variation is combined is all included in scope of the present utility model.
Industrial applicibility
The utility model can be useful on the lamp with light-emitting components such as LED, is particularly useful for as an alternative bulb-shaped lamp of incandescent lamp bulb in the past etc. etc., and can be as the light source of the equipment in lighting device etc. and be widely used.
symbol description
1,1A, 2 bulb-shaped lamps
3 utensils of lighting a lamp
4 appliance bodies
4a socket
5 lampshades
10,210 enclosed globe shades
11,211 peristomes
20,20A, 20B, 20C, 20D, 200,201,220,220A, 220B, 220C, 220D, 320,420 LED modules
The main LED module of 20a
The secondary LED module of 20b
21,21X, 21Y substrate
21a, 21b, 21Xa, 21Xb, 21Ya, 21Yb, 221a, 221b, 242a1 through hole
22a,22b,22c,22d,32a,32b,222LED
23a the first seal member
23b the second seal member
23c the 3rd seal member
23d the 4th seal member
23A, 223,223a seal member
The illusory seal member of 24a first
The illusory seal member of 24b second
24c the 3rd illusory seal member
24d the 4th illusory seal member
24X, the illusory seal member of 24Y
25 Zener diodes
26,36,224 metal wirings
27,37 wires
28,38 terminals
29,39 electric conductivity adhesion parts
30 lamp holders
33a the 5th seal member
33b the 6th seal member
34a the 5th illusory seal member
34b the 6th illusory seal member
40,40A, 241 pillars
41,241a main shaft part
42,241b fixed part
42b, 241b1 jut
50 supporting stations
60 resin enclosures
61 first housing departments
62 second housing portions
70,270a to 270b goes between
80 lamp circuits
90 stickers
122a sapphire substrate
122b nitride semiconductor layer
122c cathode electrode
122d anode electrode
122e, 122f wire joint portion
122g chips incorporate material
221 base stations
223b wavelength conversion parts
225 gold medal wires
227,228,229,527 luminescent coatings
227a, 228a, 229a central portion
227b, 228b, 229b end
230 bonded blocks
230a vertical slot portion
230b flange part
230c protuberance
240 support units
242 pedestals
The little portion in 242a footpath
The large portion in 242b footpath
242b1 recess
250 frameworks
251 inner side frame bodies
251a circuit cap
251b circuit maintaining part
252 outside frames
252a outer edge
252b screws up portion
260 metal parts
270 drive circuits
271 circuit substrates
272 components
280 lamp holders
290 screws
323,423 containing fluorophor resin
324 masks
400 reflection parts
500 ?look mask
ML1 the first main light emission portion
ML2 the second main light emission portion
ML3 the 3rd main light emission portion
ML4 the 4th main light emission portion
The secondary illuminating part of SL1 first
The secondary illuminating part of SL2 second
SL3 the 3rd secondary illuminating part
SL4 fourth officer illuminating part
WC1 the first wavelength transform component
WC2 second wave length transform component
WC3 three-wavelength transform component
WC4 the 4th wavelength conversion parts
WC5 the 5th wavelength conversion parts
WC6 the 6th wavelength conversion parts
WC7 the 7th wavelength conversion parts
WC8 the 8th wavelength conversion parts.
Claims (34)
1. a light-emitting device, is characterized in that, possesses:
Substrate;
The first light-emitting component, is configured on described substrate;
The first wavelength transform component, is arranged on described substrate, and the light wavelength that described the first light-emitting component is sent converts; And
Second wave length transform component, with the adjacent setting of described the first wavelength transform component, the light wavelength that described the first light-emitting component is sent converts,
In described the first wavelength transform component, there is described the first light-emitting component,
In described second wave length transform component, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by this second wave length transform component.
2. light-emitting device as claimed in claim 1, is characterized in that,
Described the first light-emitting component, be configured with on described substrate with row shape multiple,
Described the first wavelength transform component is configured to wire on described substrate,
Described second wave length transform component is configured to side by side wire with described the first wavelength transform component on described substrate.
3. light-emitting device as claimed in claim 2, is characterized in that,
Described the first wavelength transform component comprises the first wavelength shifter and comprises the first seal member of this first wavelength shifter, the light wavelength that described the first wavelength shifter is sent multiple described the first light-emitting components converts, described the first seal member is configured to wire, and multiple described the first light-emitting components are sealed in the lump
Described second wave length transform component comprises second wave length coversion material and comprises the first illusory seal member of this second wave length coversion material, and the light wavelength that described second wave length coversion material sends multiple described the first light-emitting components converts.
4. light-emitting device as claimed in claim 3, is characterized in that,
The concentration of the described second wave length coversion material in described the first illusory seal member is, below the concentration of described the first wavelength shifter in described the first seal member.
5. light-emitting device as claimed in claim 3, is characterized in that,
The length of described the first illusory seal member is, below the length of described the first seal member.
6. the light-emitting device as described in any one of claim 3 to 5, is characterized in that,
Described the first wavelength shifter and described second wave length coversion material are fluorophor particle,
Described the first seal member and described the first illusory seal member are resin.
7. the light-emitting device as described in any one of claim 3 to 5, is characterized in that,
In described the first illusory seal member, there is non-luminous electronic component.
8. light-emitting device as claimed in claim 2, is characterized in that,
It is semicircle that the shape of this first wavelength transform component in the section vertical with the length direction of described the first wavelength transform component is essentially,
Multiple described the first light-emitting components are configured to row,
Each of multiple described the first light-emitting components is located substantially on the center of the width of described the first wavelength transform component.
9. light-emitting device as claimed in claim 2, is characterized in that,
This light-emitting device also possesses:
Multiple the second light-emitting components along the column direction of multiple described the first light-emitting components, are configured shape in column on described substrate; And
Three-wavelength transform component is configured to wire on described substrate, and the light wavelength that multiple described the second light-emitting components are sent converts,
In described three-wavelength transform component, there are multiple described the second light-emitting components,
Described second wave length transform component is arranged between described the first wavelength transform component and described three-wavelength transform component, and the light wavelength of also multiple described the second light-emitting components being sent converts.
10. light-emitting device as claimed in claim 9, is characterized in that,
Described the first wavelength transform component comprises the first wavelength shifter and comprises the first seal member of this first wavelength shifter, the light wavelength that described the first wavelength shifter is sent multiple described the first light-emitting components converts, described the first seal member is configured to wire, and multiple described the first light-emitting components are sealed in the lump
Described second wave length transform component comprises second wave length coversion material and comprises the first illusory seal member of this second wave length coversion material, the light wavelength that described second wave length coversion material sends multiple described the first light-emitting components and multiple described the second light-emitting component converts
Described three-wavelength transform component comprises three-wavelength coversion material and the second seal member that comprises this three-wavelength coversion material, the light wavelength that described three-wavelength coversion material sends multiple described the second light-emitting components converts, described the second seal member is configured to wire, and multiple described the second light-emitting components are sealed in the lump.
11. light-emitting devices as claimed in claim 10, is characterized in that,
Multiple described the first light-emitting components and multiple described the second light-emitting component are the light-emitting components that can send the light of same color,
The concentration of the described second wave length coversion material in described the first illusory seal member is, below the concentration of described the first wavelength shifter in described the first seal member, and below the concentration of described three-wavelength coversion material in described the second seal member.
12. light-emitting devices as described in claim 10 or 11, is characterized in that,
The concentration of described the first wavelength shifter in described the first seal member is almost consistent with the concentration of the described three-wavelength coversion material in described the second seal member.
13. light-emitting devices as described in claim 10 or 11, is characterized in that,
Described the first wavelength shifter, described second wave length coversion material and described three-wavelength coversion material are fluorophor particle,
Described the first seal member, described the first illusory seal member and described the second seal member are resin.
14. light-emitting devices as claimed in claim 9, is characterized in that,
It is semicircle that the shape of this first wavelength transform component in the section vertical with the length direction of described the first wavelength transform component is essentially,
It is semicircle that the shape of this three-wavelength transform component in the section vertical with the length direction of described three-wavelength transform component is essentially,
Multiple described the first light-emitting components and multiple described the second light-emitting component are configured to respectively row,
Each of multiple described the first light-emitting components is located substantially on the center of the width of described the first wavelength transform component,
Each of multiple described the second light-emitting components is located substantially on the center of the width of described three-wavelength transform component.
15. light-emitting devices as claimed in claim 9, is characterized in that,
This light-emitting device also possesses:
Multiple the 3rd light-emitting components and multiple the 4th light-emitting component along the column direction of multiple described the second light-emitting components, are configured shape in column on described substrate;
The 4th wavelength conversion parts, adjacent with described three-wavelength transform component and on described substrate, be arranged to wire, the light wavelength that multiple described the 3rd light-emitting components are sent converts;
The 5th wavelength conversion parts are configured to side by side wire with described the 4th wavelength conversion parts on described substrate, and the light wavelength that multiple described the 3rd light-emitting components and multiple described the 4th light-emitting component are sent converts; And
The 6th wavelength conversion parts, adjacent with described the 5th wavelength conversion parts and on described substrate, be arranged to wire, the light wavelength that multiple described the 4th light-emitting components are sent converts,
In described the 4th wavelength conversion parts, there are multiple described the 3rd light-emitting components,
In described the 6th wavelength conversion parts, there are multiple described the 4th light-emitting components,
Described the 5th wavelength conversion parts are arranged between described the 4th wavelength conversion parts and described the 6th wavelength conversion parts,
In described the 5th wavelength conversion parts, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by the 5th wavelength conversion parts.
16. light-emitting devices as claimed in claim 15, is characterized in that,
Described the 4th wavelength conversion parts comprise the 4th wavelength shifter and comprise the 3rd seal member of the 4th wavelength shifter, the light wavelength that described the 4th wavelength shifter is sent multiple described the 3rd light-emitting components converts, described the 3rd seal member is configured to wire, and multiple described the 3rd light-emitting components are sealed in the lump
Described the 5th wavelength conversion parts comprise the 5th wavelength shifter and comprise the second illusory seal member of the 5th wavelength shifter, the light wavelength that described the 5th wavelength shifter is sent multiple described the 3rd light-emitting components and multiple described the 4th light-emitting component converts
Described the 6th wavelength conversion parts comprise the 6th wavelength shifter and comprise the 4th seal member of the 6th wavelength shifter, the light wavelength that described the 6th wavelength shifter is sent multiple described the 4th light-emitting components converts, described the 4th seal member is configured to wire, and multiple described the 4th light-emitting components are sealed in the lump.
17. light-emitting devices as claimed in claim 16, is characterized in that,
This light-emitting device also possesses the 7th wavelength conversion parts, and the 7th wavelength conversion parts are arranged between described three-wavelength transform component and described the 4th wavelength conversion parts,
Described the 7th wavelength conversion parts comprise the 7th wavelength shifter and comprise the 3rd illusory seal member of the 7th wavelength shifter, the light wavelength that described the 7th wavelength shifter is sent multiple described the second light-emitting components and multiple described the 3rd light-emitting component converts
In described the 7th wavelength conversion parts, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by the 7th wavelength conversion parts.
18. light-emitting devices as described in claim 16 or 17, is characterized in that,
This light-emitting device also possesses the 8th wavelength conversion parts, the 8th wavelength conversion parts are arranged at least both sides of the length direction of one of them of following wavelength conversion parts, these wavelength conversion parts refer to: described the first wavelength transform component, described three-wavelength transform component, described the 4th wavelength conversion parts and described the 6th wavelength conversion parts
Described the 8th wavelength conversion parts comprise the 8th wavelength shifter and comprise the 4th illusory seal member of the 8th wavelength shifter, the 8th wavelength shifter converts at least one of them light wavelength of sending of following light-emitting component, these light-emitting components refer to: multiple described the first light-emitting components, multiple described the second light-emitting component, multiple described the 3rd light-emitting component and multiple described the 4th light-emitting component
In described the 8th wavelength conversion parts, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by the 8th wavelength conversion parts.
19. light-emitting devices as claimed in claim 1, is characterized in that,
Described the first wavelength transform component with cover described the first light-emitting component at least a portion mode and be configured,
Described second wave length transform component is configured in, compared with described the first wavelength transform component, and on the position away from described the first light-emitting component,
Described the first light-emitting component is modulated light by the big or small variation of the electric current being supplied to,
The second wave length converted quantity that the degree that the light wavelength that described the first light-emitting component is sent in described second wave length transform component converts is shown, the first wavelength converted quantity of the degree converting than the light wavelength that described the first light-emitting component is sent illustrating in described the first wavelength transform component is large.
20. light-emitting devices as claimed in claim 19, is characterized in that,
Described the first wavelength transform component is the seal member that described the first light-emitting component is sealed,
Described second wave length transform component is the resin that is configured in the side of described the first wavelength transform component on described substrate.
21. light-emitting devices as claimed in claim 20, is characterized in that,
Described in the concentration ratio of the contained fluorophor particle of described second wave length transform component, the first wavelength transform component is high.
22. light-emitting devices as described in claim 20 or 21, is characterized in that,
Described substrate has light transmission,
Described light-emitting device also possesses three-wavelength transform component, and this three-wavelength transform component is the luminescent coating being formed between described substrate and described the first light-emitting component,
Described three-wavelength transform component is constituted as, and more away from described the first light-emitting component, the light wavelength converted quantity that described the first light-emitting component sends is just larger.
23. light-emitting devices as claimed in claim 22, is characterized in that,
Described three-wavelength transform component is constituted as, and more away from described the first light-emitting component, the thickness of this three-wavelength transform component is just thicker.
24. light-emitting devices as claimed in claim 22, is characterized in that,
Described three-wavelength transform component is constituted as, and more away from described the first light-emitting component, the concentration of the contained fluorophor particle of this three-wavelength transform component is just higher.
25. light-emitting devices as claimed in claim 19, is characterized in that,
Described substrate has light transmission,
Described the first wavelength transform component and described second wave length transform component are between described substrate and described the first light-emitting component, to be formed the luminescent coating of one.
26. light-emitting devices as claimed in claim 25, is characterized in that,
Described in the Thickness Ratio of described second wave length transform component, the first wavelength transform component is thick.
27. light-emitting devices as claimed in claim 25, is characterized in that,
The concentration of the contained fluorophor particle of described second wave length transform component is higher than described the first wavelength transform component.
28. 1 kinds of bulb-shaped lamps, is characterized in that possessing:
Light-emitting device described in any one of claim 1 to 27;
The enclosed globe shade of light transmission; And
The pillar arranging is extended in inner space to described enclosed globe shade,
Described light-emitting device is configured in described enclosed globe shade, and is fixed on described pillar.
29. bulb-shaped lamps as claimed in claim 28, is characterized in that,
The mode that is positioned at top one side of described enclosed globe shade with the first surface of described substrate, described light-emitting device is fixed on described pillar, and the first surface of described substrate refers to the face that is equipped with multiple described the first light-emitting components.
30. bulb-shaped lamps as claimed in claim 29, is characterized in that,
Described light-emitting device also possesses:
Multiple the 5th light-emitting components, are configured in second of described substrate with row shape, the second face of described substrate is and the face of the contrary side of described first surface of described substrate; And
The 9th wavelength conversion parts, are configured to wire at described the second face, and the light wavelength that multiple described the 5th light-emitting components are sent converts,
In described the 9th wavelength conversion parts, there are multiple described the 5th light-emitting components.
31. bulb-shaped lamps as claimed in claim 30, is characterized in that,
Described light-emitting device also possesses the tenth wavelength conversion parts, and the tenth wavelength conversion parts are configured to wire side by side with described the 9th wavelength conversion parts on described second, and the light wavelength that multiple described the 5th light-emitting components are sent converts,
In described the tenth wavelength conversion parts, do not exist and can send the light-emitting component that is carried out the light of wavelength conversion by the tenth wavelength conversion parts.
32. bulb-shaped lamps as claimed in claim 31, is characterized in that,
Described the 9th wavelength conversion parts comprise the 9th wavelength shifter and comprise the 5th seal member of the 9th wavelength shifter, the light wavelength that described the 9th wavelength shifter is sent multiple described the 5th light-emitting components converts, described the 5th seal member is configured to wire, and multiple described the 5th light-emitting components are sealed in the lump
Described the tenth wavelength conversion parts comprise the tenth wavelength shifter and comprise the 5th illusory seal member of the tenth wavelength shifter, and the light wavelength that described the tenth wavelength shifter is sent multiple described the 5th light-emitting components converts.
33. bulb-shaped lamps as described in any one of claim 30 to 32, is characterized in that,
Described substrate is made up of main substrate and auxiliary substrate, and the surface of described main substrate is provided with multiple described the first light-emitting components, and the surface of described auxiliary substrate is provided with multiple described the 5th light-emitting components,
Described main substrate and described auxiliary substrate are configured to, the back side of described main substrate is relative with the back side of described auxiliary substrate, the back side of described main substrate refers to the face that multiple described the first light-emitting components are not set, and the back side of described auxiliary substrate refers to the face that multiple described the 5th light-emitting components are not set.
34. 1 kinds of lighting devices, is characterized in that, possess the bulb-shaped lamp described in any one of claim 28 to 33.
Applications Claiming Priority (5)
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JP2012-183409 | 2012-08-22 | ||
JP2012183409 | 2012-08-22 | ||
JP2012188439 | 2012-08-29 | ||
JP2012-188439 | 2012-08-29 | ||
PCT/JP2013/003784 WO2014030281A1 (en) | 2012-08-22 | 2013-06-18 | Light emitting device, bulb lamp and illumination device |
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CN203743911U true CN203743911U (en) | 2014-07-30 |
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CN201390000101.8U Expired - Fee Related CN203743911U (en) | 2012-08-22 | 2013-06-18 | Light-emitting apparatus, bulb lamp and lighting apparatus |
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JP (1) | JP5627801B2 (en) |
CN (1) | CN203743911U (en) |
WO (1) | WO2014030281A1 (en) |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN109424868A (en) * | 2017-09-01 | 2019-03-05 | 液光固态照明股份有限公司 | LED bulb and manufacturing method thereof |
CN112912664A (en) * | 2018-10-22 | 2021-06-04 | Gce研究开发有限公司 | Lighting device with power generation function |
CN115003951A (en) * | 2019-10-28 | 2022-09-02 | 创意电缆股份公司 | External low-voltage lamp |
Families Citing this family (4)
Publication number | Priority date | Publication date | Assignee | Title |
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RU2646071C1 (en) * | 2014-05-20 | 2018-03-06 | Филипс Лайтинг Холдинг Б.В. | Lighting or exposure system with conformal coating |
JP2016171146A (en) * | 2015-03-11 | 2016-09-23 | パナソニックIpマネジメント株式会社 | Light emission device and manufacturing method for the same |
WO2016143261A1 (en) * | 2015-03-11 | 2016-09-15 | パナソニックIpマネジメント株式会社 | Light-emitting device and manufacturing method for light-emitting device |
EP3919806A1 (en) * | 2020-06-04 | 2021-12-08 | Xiamen Eco Lighting Co., Ltd. | Led bulb apparatus |
Family Cites Families (5)
Publication number | Priority date | Publication date | Assignee | Title |
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JP4551948B2 (en) * | 2007-06-13 | 2010-09-29 | シャープ株式会社 | Linear light source device, surface light emitting device, planar light source device, and liquid crystal display device |
JP2012156440A (en) * | 2011-01-28 | 2012-08-16 | Toshiba Lighting & Technology Corp | Light-emitting device and luminaire |
JP4932064B2 (en) * | 2010-03-11 | 2012-05-16 | パナソニック株式会社 | Light emitting module, light source device, liquid crystal display device, and method for manufacturing light emitting module |
JP5073107B2 (en) * | 2010-12-24 | 2012-11-14 | パナソニック株式会社 | Light bulb shaped lamp and lighting device |
CN202839730U (en) * | 2010-12-28 | 2013-03-27 | 松下电器产业株式会社 | Light emitting device, light emitting module and lamp |
-
2013
- 2013-06-18 JP JP2013552776A patent/JP5627801B2/en not_active Expired - Fee Related
- 2013-06-18 WO PCT/JP2013/003784 patent/WO2014030281A1/en active Application Filing
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109424868A (en) * | 2017-09-01 | 2019-03-05 | 液光固态照明股份有限公司 | LED bulb and manufacturing method thereof |
US11221108B2 (en) | 2017-09-01 | 2022-01-11 | Liquidleds Lighting Corporation | LED light bulb and manufacturing method thereof |
CN112912664A (en) * | 2018-10-22 | 2021-06-04 | Gce研究开发有限公司 | Lighting device with power generation function |
CN115003951A (en) * | 2019-10-28 | 2022-09-02 | 创意电缆股份公司 | External low-voltage lamp |
Also Published As
Publication number | Publication date |
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JP5627801B2 (en) | 2014-11-19 |
JPWO2014030281A1 (en) | 2016-07-28 |
WO2014030281A1 (en) | 2014-02-27 |
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