KR20160093213A - Mushrooms growing diversified crops emitting diode lighting fixtures - Google Patents

Abstract

More particularly, the present invention relates to a light emitting diode lighting apparatus for cultivating a mushroom of a variety of crops. More particularly, the present invention relates to a light emitting diode lighting apparatus for cultivating a variety of mushroom crops, A binary switch 22 for controlling the wavelength is provided on the LED printed circuit board 2 of the known LED lighting module 100 constituted by the supply unit 6 so that the color and wavelength (Nm) can be freely selected from the mixed colors and wavelength determined according to the type of mushroom to be cultivated, germination and growth period.
Accordingly, it is possible to smoothly grow different kinds of crops or different mushroom crops in the same place and space, and to improve the compatibility and usability of the light emitting diode lighting apparatus itself for cultivating mushroom crops. In particular, , The production cost of mushroom crops can be greatly reduced and the cultivated variety can be adjusted by predicting the production amount and yield of each kind in advance in order to control the collapse or the increase in the price of the mushroom by kind or variety, can do.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a mushroom-

The present invention relates to a light emitting diode lighting apparatus for growing a variety of mushroom crops, and more particularly, to a lighting apparatus using a light emitting diode (LED) module, Which can be used to grow different kinds of crops or different mushroom crops in the same place and space by installing a wavelength switch for controlling the wavelength, To a diode lighting fixture.

In general, temperature and humidity, CO 2 concentration, pollution prevention, and light irradiation amount are important management factors when cultivating crops such as various mushrooms.

Conventionally, most of the cultivation methods such as mushrooms, etc., are kept warm by covering the outer surface of the grower made of plastic greenhouse with a heat cover, but it is difficult to efficiently manage the heat due to a lot of heat loss.

In addition, it is necessary to maintain the internal temperature constantly within the cultivated area at the optimum temperature required by the crop, but it is difficult to properly manage it due to lack of air conditioning facilities.

Recently, the air conditioner and the air conditioner are taken out to the inside of the cultivation room, and various duct facilities are installed so that air circulated inside the cultivation room is discharged back to the outside.

On the other hand, the art of using artificial light source in cultivation of various plants including mushrooms has been widely studied such as application of plant plant system in recent years.

In addition, with the emergence of LEDs, the current agriculture sector is facing another turning point. In contrast to conventional lighting that has a wide wavelength range and is tailored to human vision, LEDs can control the ratio and intensity of light emission It is possible to provide a wavelength and a light amount necessary for photosynthesis, thereby facilitating plant cultivation illumination.

If such an artificial lighting device using LED is used, it is possible to control the growth of the plant by using no or little chemical fertilizer, effectively irradiating the light, and by applying LED light technology to control pests, low pesticide cultivation is possible , And can save over 80% of energy compared to incandescent bulbs that are in use. It is an eco-friendly product that does not use mercury or heavy metals. It can produce 365 days a year, regardless of climate change.

On the other hand, the mycelial growth of mushrooms can be divided into three types according to temperature. First, low temperature development (optimum temperature 22 ~ 26 ℃, maximum 30 ℃) Temperature 24 ~ 32 ℃), and mushroom, mushroom, and mushroom. The third is medium temperature (optimum temperature 22 ~ 28 ℃, maximum 32 ℃).

In addition, the occurrence of oyster mushrooms requires an environment in which low temperature and high temperature appear alternately. The mushroom of haploid mushroom occurs well at a constant temperature and occurs well in a dark place. Also, the humidity should be high in the occurrence of oyster mushroom and mushroom, The mushroom, shiitake mushroom, matsutake mushroom and white mushroom mushroom should occur at low humidity.

In addition, the spores of the mushroom are divided into two types, larval fungus and basidiomycetes.

In this case, the ascidian fungus is usually endogenous by the fusion and meiosis in the large cystic cell called the eardrum, and the endoplasmic reticulum is composed of a club-like shape called 擔子 柄In the cells of the nucleus fusion and meiosis occurs at the end of the cell has four pointed endoplasmic reticulum (小 子 子 梗) and one on each of them spore spore (擔子 spore) exogenous.

Mushrooms are specially developed fruiting bodies for the formation of these spores. The part of the fruiting body in which the adenocarcinoma or the cotyledonary disease are layered side by side is called the fungus layer. Especially, when the fungus has a special shape and structure, This part is called Josilstack.

The fruiting bodies are various in quality such as meat quality, collagen and agar quality, and solid ones are cork quality, leather quality and wood quality, and the shapes are various like ball shape, bat shape, umbrella shape and fan shape.

Most of the mushroom mushrooms are umbrella-shaped umbrellas and sacks that hold them, and wrinkles are formed on the underside of the freshly grown mushrooms.

When we look at the development process of mushrooms, matured hyphal mushrooms are closely intertwined and organized, forming a primordial body, becoming round, becoming bigger and bigger, and rounded to the side of the wall, Wrinkles are formed.

Also, the upper part is round and the lower part is a sack, and it becomes a young mushroom.

Until the umbrella is still unfolded, it is wrapped with a thin film between the umbrella and the bag to protect the inner layer of the umbilicus, but as the umbrella is expanded, the capsule bursts, a part of which is attached to the umbrella, The mycelium.

Some of the young mushrooms of the clown mushrooms are wrapped in a capsule covering the entire body, but they burst out as they grow larger, scattered on the surface of the warts, and remain as pouches under the sack.

And, depending on the shape of the wrinkles attached to the bag, the wrinkles and the sacks are attached at right angles to them [straightening], the ends of the wrinkles are attached to the bag, and the wrinkles are separated from the sacks It has been found that the wrinkle is attached to the bottom of the bag, and the wrinkle is attached to the bottom of the bag. It is used to describe the characteristics of mushrooms by distinguishing them as [上 生].

On the other hand, environmental conditions such as temperature, humidity, atmosphere, and nutrient intake greatly affect mycelial growth and fruiting of mushrooms.

Generally, mycelium grows at 5 ~ 40 ℃, suitable temperature is 20 ~ 30 ℃, suitable temperature for fruiting body is 10 ~ 20 ℃, humidity is hygroscopic at 65 ℃ To 80%, and 80% to 95% of moisture and a large amount of water are required for generation of fruiting bodies.

Mushroom fungus is a respiratory aerobic bacterium that does not develop in the absence of air. Light rays are not necessary for mycelial growth, but mushrooms are produced under proper light scattering to fruiting bodies. Nutrients are mycelial parasites of the mycelium and various organic substances in it are taken by decomposing by the power of enzyme (enzymes), and various inorganic components and vitamins are involved in the promotion of growth.

On the other hand, the temperature, humidity, carbon dioxide concentration, light and the like are made by the air conditioning system equipped with the cooler, the heater and the ventilation as the main environmental factors for the improvement of the normal mushroom growth as described above.

Recently, it has been required to develop cultivation technology using air conditioning facilities for stabilized production at the time when the height of cultivated land is shifted to the increase of sawdust cultivation.

Up to now, studies on temperature, humidity and carbon dioxide have been mainly focused on mushroom cultivation, and studies on light have been mainly based on foreign research results.

Studies on the effect of light on the growth of mushrooms have shown that blue light close to ultraviolet light is effective for the formation and development of mushrooms and that the production of carotenoid pigments is induced in mycelia and spores of other fungi, (Mushroom Journal, 2010) reported that green, yellow, and orange light is effective.

In particular, in Japan, studies using LEDs have been actively carried out. In the case of Zeltmania mushroom, 30 liters of LED light was irradiated for 12 days during the growth period of fruiting body, resulting in the increase in freshness of the blue LED, (Kengi et al, 2002). In addition, it is known that the size of the gut becomes smaller and the color of the gut becomes thicker toward the long wavelength (red light) region (Kengi et al, 2002).

In addition, the taste mushroom gene controlled by blue light is cdcs5 gene. As a result of growing for 7 days under fluorescent light, blue light, red light, and dark condition, the size of gut is increased in fluorescent lamp and blue light, , Red light and dark conditions are known to show a tendency for growth of gad and growth of gad (Kaori et al., 2005).

On the other hand, the results of LED studies on mushroom cultivation were very poor, and blue LEDs were found to be suitable for the growth of fruiting bodies of green mushrooms, Yeltsman mushrooms, and green mushrooms (Chang et al., 2010) .

However, since the conventional mushroom-grown light emitting diode lighting apparatuses are not manufactured so that different kinds of mushrooms can be smoothly grown in the same place and space, compatibility and usability of the light emitting diode lighting apparatus for mushroom cultivation itself are lacking, There is a problem that the cultivation space can not be efficiently utilized.

Korean Registered Patent No. 10-1168747 (July 19, 2012) Korean Patent Registration No. 10-1451343 (October 08, 2014) Korea Registered Utility Model No. 20-0473079 (June 02, 2014) Korean Registered Patent No. 10-1150303 (May 21, 2012)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the related art, and it is an object of the present invention to provide a light emitting diode (LED) In manufacturing a light emitting diode lighting apparatus for cultivating a mushroom of a variety of crops using an LED lighting module, a plurality of color LEDs are used on a printed circuit board in each LED lighting module to arbitrarily select a mixed color of a desired wavelength (nm) (That is, the wavelength of the desired color among seven monochromatic and mixed colors) to be output, so that different kinds of crops or different mushroom crops can be smoothly grown in the same place and space The compatibility and usability of the light emitting diode luminaire for mushroom cultivation itself can be improved, and in particular, The production cost of mushroom crops can be greatly reduced and the cultivated varieties can be adjusted by predicting the amount of production and yield of the mushrooms in advance in order to control the price of mushrooms or the prices of the varieties The present invention provides a light emitting diode lighting apparatus for cultivating a variety of mushroom cultivars capable of protecting a farmhouse.

Another object of the present invention is to provide a mushroom crop cultivation shelf having a height of 1m and a light emitting diode lighting apparatus with a predetermined photon density (for example, 4 to 6W) It is possible to raise the cultivation efficiency of mushroom crops including the production cost to the production cost, as well as to lower the production cost of the product through cost reduction, and to prevent water and moisture, It can be used for green lighting because it is free from heavy metal contamination unlike fluorescent lamps or discharge lamps. It can contribute to environment friendly production and green growth. It can be driven with low power consumption, And can be protected by a safety circuit even when an impulse voltage is applied, Unlike an existing discharge lamp, it is possible to prevent a case where one of the plurality of LED lighting modules is defective even if the other modules are normally turned off (turned off) unlike the conventional one, It has an extremely long lifespan, it can cultivate and produce various mushroom crops for 365 days regardless of climate change. It can save more than 80% of energy compared to existing incandescent lamps and is an eco-friendly product that does not use mercury or heavy metals. The present invention relates to a light emitting diode (LED) lighting apparatus for cultivating a variety of mushroom cultivars capable of effectively cultivating various mushroom crops.

According to an aspect of the present invention, there is provided a plasma display panel comprising: a translucent plate detachably coupled to a bottom of a heat radiator; An LED printed circuit board having a plurality of colored LEDs mounted thereon and generating light required for cultivation of various mushroom crops; A heat dissipating member for dissipating heat generated from the LED; An auxiliary heat sink for performing a heat dissipation function and a function for preventing the formation of a groove for generating an air layer between the contact surfaces with the LED printed circuit board due to a part of the heat shrinkage caused by the cooling of the heat dissipation member; A heat dissipation type upper case for dissipating some residual heat of LEDs transmitted through the heat dissipation body including heat generated from a power supply unit; And a power supply unit for supplying the power supply voltage necessary for driving the LEDs. The LED lighting unit is installed on an upper part of a mushroom cultivation shelf having a height of 1m and is provided with a LED lighting unit And a plurality of module fixing plates each having a predetermined area are used as a light emitting diode lighting device for cultivating a mushroom of a variety of crops, And a plurality of color LEDs connected in series between the output terminal of the power supply unit and the power supply terminal of the LED printed circuit board so that the color and wavelength (nm) output from the plurality of color LEDs A choice of colors and wavelengths to match the type and germination and growth period It characterized.

At this time, the density of photon of each LED lighting module used for cultivation of mushroom crops is characterized by being 4 ~ 6W.

The wavelength-tunable binary switch includes a dip switch and a binary output rotary switch.

When the binary switch for wavelength adjustment is set to "0 ", all the plurality of color LEDs provided on the LED printed circuit boards of the LED lighting modules are turned " off" (Blue) and infrared rays (UV) having a wavelength band of 390 ~ 470 (㎚) suitable for cultivation of Oyster mushroom, Zelkova mushroom, Shiitake mushroom, Throat mushroom, Top mushroom, Green "light having a wavelength range of 500 to 540 (nm) suitable for cultivation of a high-quality large oyster mushroom or sawdust-cultivated shiitake mushroom is irradiated, and when it is set to" 3 " (Blue), infrared (UV), and green (green) light is irradiated so that light having a wavelength range of 390 to 540 (nm) suitable for cultivation of a large oyster mushroom is irradiated , And "4", the mushroom (but not the mushroom) (Cherry RED) and red (RED) light to be irradiated with light having a wavelength range of 610 to 710 (nm) suitable for the cultivation of a green mushroom - (Blue) and infrared (UV) light for irradiating light having a wavelength band of 400 & 640 (nm) although there is no experimental result of the corresponding varieties when it is set to "5" (Pink) light of red, green, red, blue, red, and red, and when set to 6, the luminous intensity of red LED is 20 [u-mol / green (RED) and red (RED) mixed light (orange) light is irradiated so that light having a wavelength band of 520 & 640 (nm) 7 ", blue (blue) and red (blue) light are irradiated so that light having a wavelength band of 390 to 710 (nm) suitable for the cultivation of Oyster mushroom- And supplies a voltage output from a power supply unit to each of the color LEDs so that mixed color (yellow) light of line UV, green color, cherry red, and red color is irradiated .

In addition, a tool insertion hole is further formed in the translucent plate so that the user can manipulate the wavelength control binary switch using a tool from the outside.

In addition, a transparent cap provided on the outer side of the transparent plate is provided with a handle for preventing the transparent plate from being contaminated by various foreign substances and for preventing the foreign substances from flowing into the LED printed circuit board through the tool insertion hole, And is detachably installed with a consumable property.

In addition, the LED lighting module may be provided with a spiral socket coupling hole so that the LED lighting module can be screwed into the socket like a general light bulb.

A part of the power supply line connected to the power supply unit is exposed to the outside of the coupling protrusion of the heat-dissipating upper case, and a connector is provided at the exposed end of the power supply line.

The heat dissipation resin material has a thermal diffusion coefficient of 0.75-0.8 [cm 2 / sec], a thermal conductivity of 90-150 [W / mK], a density of 1.4 ± 0.2 [g / Carbon nanotube metal polymer (CMP) containing carbon nanotubes (CNTs) having a specific heat of 160 ° C and a specific heat of 1.1 ± 0.4 [J / gK].

As described above, according to the light emitting diode lighting apparatus for cultivating a multi-variety mushroom crop of the present invention, the light emitting diode lighting apparatus for cultivating a multi-product mushroom grows light using one or a plurality of LED lighting modules disclosed in Korean Patent Application No. 10-1322614 In fabricating the apparatus, a plurality of color LEDs are used on a printed circuit board in each LED lighting module to arbitrarily select a mixed color of a desired wavelength (nm) (that is, a desired color of seven monochromatic and mixed colors The wavelength of the light emitted by the mushroom cultivating plant can be adjusted so that different kinds of crops or different mushroom crops can be smoothly grown in the same place and space, And the usability can be improved. Especially, the same cultivation space can be efficiently utilized, Can significantly reduce the cost of production of crops, it can also be adjusted so the cultivars to pre-estimate the breed-specific production and yield in order to adjust the types or varieties of mushrooms by price slump and soaring protect farmers.

In addition, in the present invention, various mushroom cultivation shelves are installed in multi-stages with a height of 1 m, and light emitting diode lighting apparatuses are installed with a predetermined photon density (for example, 4 to 6 W) It is possible to increase the cultivation efficiency of mushroom crops including the production cost per production cost, as well as to lower the production cost of the product through cost reduction, and to be waterproof and moisture resistant, Unlike fluorescent or discharge lamps, it is free from heavy metal pollution and can be used as green light, contributing to environment friendly production and green growth. It can be driven with low power consumption, which can save energy cost considerably, Even if a voltage is applied, it can be protected by a safety circuit. Unlike an existing discharge lamp, even if one of the plurality of LED lighting modules is defective, the other modules can operate normally, so that it is possible to prevent a case where the module is turned off (turned off) It can grow and produce various mushroom crops for 365 days regardless of climate change. It can save more than 80% of energy compared to incandescent light bulbs. It is an eco-friendly product that does not use mercury or heavy metals. It is a very useful invention that can effectively grow various mushroom crops without using them.

1 is a perspective view of a single light emitting diode lighting apparatus to which the present invention is applied;
2 is an exploded perspective view of a single light emitting diode lighting apparatus to which the present invention is applied.
3 is a longitudinal cross-sectional view of a coupled state of a single light emitting diode lighting device to which the present invention is applied.
4 is a plan view of an LED printed circuit board installed in the LED lighting module of the present invention.
5 is a circuit diagram of an LED printed circuit board installed in an LED lighting module of the present invention.
6 is a partially exploded perspective view of a light emitting diode lighting apparatus having a state in which a plurality of LED lighting modules to which the present invention is applied is installed on a module fixing plate so that the LED lighting modules can be used together with a bulb.
FIG. 7 is a graph showing a central wavelength used in a light emitting diode lighting apparatus for cultivating a mushroom of a variety of crops to which the present invention is applied.
FIG. 8 is a photograph of a part of a sash of a mushroom cultivation shelf equipped with a light emitting diode lighting apparatus for cultivating a multi-variety mushroom crop of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a single light emitting diode lighting apparatus to which the present invention is applied, FIG. 2 is an exploded perspective view of a single light emitting diode lighting apparatus to which the present invention is applied, FIG. 3 is a perspective view of a single light emitting diode lighting apparatus FIG. 4 is a plan view of an LED printed circuit board installed in the LED lighting module according to the present invention.

5 is a circuit diagram of an LED printed circuit board installed in the LED lighting module of the present invention. FIG. 6 is a view illustrating a state in which a plurality of LED lighting modules to which the present invention is applied is installed on a module fixing plate FIG. 7 is a graph showing the central wavelengths used in the light emitting diode lighting apparatus for cultivating a mushroom of the present invention to which the present invention is applied, and FIG. 8 is a graph showing the central wavelengths used for the cultivation of the multi- FIG. 2 is a photograph showing a part of a mushroom growing plant with a light-emitting diode lighting apparatus installed. FIG.

According to the present invention,

A translucent plate 1 detachably connected to the bottom of the heat discharging body 3 to transmit or diffuse the light generated from the LEDs 21 and to block the inflow of various foreign substances and foreign substances introduced from the outside; A plurality of color LEDs 21 are fixed by soldering at predetermined intervals on the bottom surface of the heat discharging body 3 so as to be detachably fixed to the bottom surface of the heat discharging body 3 and controlled by a power supply unit 6, An LED printed circuit board (2) for generating light; And a plurality of streamlined heat dissipating rods 31 are integrally formed on the upper surface so as to integrally protrude radially so that air can be circulated in all directions. The heat generated by the LEDs 21 A heat dissipator 3 for dissipating heat; A plurality of case fixing bosses 41 are provided on the upper surface of the heat dissipating body 3 and the heat dissipating body 3 is integrally inserted into the inside of the heat dissipating body 3 during injection molding of the heat dissipating body 3, A part of the heat dissipating body 3 is cooled after being injected and a part of the heat dissipating body 3 is shrunk to thereby prevent the formation of a groove for generating an air layer between the contact surfaces with the LED printed circuit board 2, 4); A power supply unit (not shown) which is detachably coupled to the upper surface of the heat discharging body 3 and has a configuration in which a heat radiating resin material of a conductive polymer has a cap shape having a coupling protrusion 51 at an upper portion thereof, A heat-dissipating upper case 5 for dissipating some residual heat of the LED 21 transmitted through the heat dissipating member 3 including heat generated in the heat dissipating member 6; And a power supply unit 6 installed in the heat-dissipating upper case 5 to supply a power source voltage necessary for driving the LEDs 21. The mushroom planting lathe 200 has a height of 1 m, The LED lighting module (100), which is installed and generates the output of the density of photons necessary for the cultivation of various mushroom crops, is used alone, or a plurality of modules are mounted on the module fixing plate (9) To be used as a light emitting diode lighting device for cultivation

The binary control switch 22 for controlling the wavelength is provided on each LED printed circuit board 2 of the LED lighting modules 100 and the output terminal of the power supply unit 6 and the power supply of the LED printed circuit board 2 The color and wavelength (nm) output from the plurality of color LEDs 21 can be selected by the user so as to have a mixed color and a wavelength determined according to the type of mushroom to be cultivated, germination and growth period, etc. .

At this time, the LED light module 100 used for cultivation of the mushroom crops has a photon density of 4 to 6W.

The wavelength-tunable binary switch 22 is characterized by including a dip switch and a binary output rotary switch.

When the wavelength controlling binary switch 22 is set to "0 ", all the plurality of color LEDs 21 provided on the LED printed circuit board 2 of each LED lighting module 100 are" Blue "with a wavelength of 390 ~ 470 (㎚) suitable for cultivation of Oyster mushroom, Yeltsman mushroom, Shiitake mushroom, Throat mushroom, Top mushroom, Leaf mushroom and Coarse mushroom when it is set to" 1 " (Green) having a wavelength band of 500 to 540 (nm) suitable for cultivation of high-quality large oyster mushroom or sawdust mushroom when irradiated with blue light and infrared light (UV) ), And when it is set to "3 ", blue, infrared (UV), and green (Green) colors are irradiated so that light having a wavelength range of 390 to 540 (Light blue) light is irradiated, and when set to "4" Chrysanthemum mushroom - Chrysanthemum mushroom - Cherry RED and red (red) to irradiate light with a wavelength range of 610 ~ 710 (㎚) (Red) light of red (RED) is irradiated, and when it is set to "5", there are no experimental results of the corresponding varieties, but blue (blue) and infrared UV light, Cherry RED and RED mixed light (pink) light is irradiated. When set to "6", the light intensity of the red LED is 20 [u- (orange) light of Green, Cherry RED and Red (RED) is irradiated so that light having a wavelength range of 520 & 640 (nm) , And when it is set to "7", blue light is irradiated so that light having a wavelength range of 390 to 710 (nm) suitable for the cultivation of the oyster mushroom- (Yellow) light of blue (B) and infrared (UV), green (Green), green (Rerry) and red (RED) .

The translucent plate 1 is further provided with a tool insertion hole 14 for allowing the user to operate the wavelength control binary switch 22 using a tool from the outside.

The translucent plate 1 is prevented from being contaminated by various foreign substances on the outside of the translucent plate 1 and flows into the LED printed circuit board 2 through various foreign substances through the tool insertion hole 14 And a transparent cap (7) provided with a handle (72) for preventing contamination is detachably installed in a consumable manner.

The LED lighting module 100 is provided with a spiral socket coupling hole 8 so that the LED lighting module 100 can be screwed into the socket 81 like a general light bulb in the coupling protrusion 51 of the heat- do.

A part of the power supply line 61 connected to the power supply unit 6 is exposed to the outside of the coupling protrusion 51 of the heat dissipative upper case 5 and the connector 62 is connected to the exposed end of the power supply line 61. [ Is provided.

The heat dissipation resin material has a thermal diffusion coefficient of 0.75-0.8 [cm 2 / sec], a thermal conductivity of 90-150 [W / mK], a density of 1.4 ± 0.2 [g / Carbon nanotube metal polymer (CMP) containing carbon nanotubes (CNTs) having a specific heat of 160 ° C and a specific heat of 1.1 ± 0.4 [J / gK].

Hereinafter, the operation and effect of the light emitting diode lighting apparatus for cultivating a mushroom of the present invention will be described.

First, as shown in FIGS. 1 to 6, a light emitting diode lighting fixture for cultivating mushroom cultivars according to the present invention comprises a translucent plate 1, an LED printed circuit board 2, a heat sink 3, A binary switch 22 for wavelength control is installed on the LED printed circuit board 2 of the known LED lighting module 100 composed of the power supply unit 4, the heat-dissipating upper case 5 and the power supply unit 6, The color and wavelength (nm) output from the color LED 21 of the first embodiment can be freely selected in accordance with the type of mushroom to be cultivated, germination and growth period, and the like.

The light emitting diode lighting apparatus for cultivating a multi-product mushroom crop of the present invention using the known LED lighting module 100 may have a bulb shape as shown in FIGS. 1 to 3, and may be used alone or in combination with a module fixing plate 9 ) Are installed at predetermined intervals as shown in FIG. 8 on the upper part of the multi-stage mushroom cultivation shelf 200 to generate a power output corresponding to the density of the photocatalyst required for the cultivation of various mushroom crops.

The translucent plate 1 is formed by injection-molding a synthetic resin material having light transparency so as to have a disk-like cap shape. The translucent plate 1 is made of a heat dissipating material (3) is detachably coupled to the bottom portion to transmit or diffuse the light generated from the LEDs (21), and to block the inflow of various foreign substances and foreign substances introduced from the outside.

The LED printed circuit board 2 includes an aluminum or epoxy printed circuit board. A plurality of color LEDs 21 are soldered and fixed to the bottom surface of the LED printed circuit board 2 at predetermined intervals. And a function of generating light required for cultivation and illumination of various kinds of mushroom crops under the control of the power supply unit 6 in a detachably fixed state by using a thermally conductive adhesive or screw or the like on the bottom surface.

In this case, the LED printed circuit board 2 is further provided with a binary switch 22 for controlling the wavelength as described above. The binary switch for wavelength control 22 will be described later in detail.

The heat dissipating body 3 is formed by injection molding with a heat dissipating resin material of a polymer having conductivity, unlike the conventional one, which is mostly made of aluminum. The upper surface of the heat dissipating body 3 is provided with several streamline heat dissipating rods 31, Are integrally protruded in a radial direction at predetermined intervals and angles, and perform the function of radiating most of the heat generated by the respective color LEDs 21 to the outside.

When the heat dissipating plate 4 is formed by injection molding the heat dissipating plate 3 using the heat dissipating resin material of a polymer having conductivity, a part of the heat dissipating plate 4 is formed in a state that the thickness thereof is thick, In the process of cooling after the injection molding of the heat discharging body 3, a lot of shrinkage occurs at a portion where a large amount of material is injected, which may cause a concave groove. In the groove-formed portion thus formed, 2 is fixedly installed, an air layer is generated at a portion where the grooves are formed, thereby preventing the heat dissipation performance of the heat dissipating body 3 itself from deteriorating.

That is, the auxiliary heat sink 4 is provided with several case fixing bosses 41 on the upper surface thereof. In the injection molding of the heat sink 3, as shown in the longitudinal section of FIG. 3, As described above, the heat dissipating body 3, which is injection-molded using the heat-dissipating resin material of a polymer having conductivity, is prevented from being shrunk by a large amount of material during cooling after injection molding (That is, the generation of a portion in which the material itself is largely contained is prevented), so that the function of preventing the air layer from being generated between the LED printed circuit board 2 and the heat discharging body 3 is prevented do.

At this time, the auxiliary heat sink 4 and the plurality of case fixing bosses 41 provided therein are formed of copper or aluminum having a hardness higher than that of the heat dissipation resin material of the polymer having a very good thermal conductivity and having conductivity, 4, the case fixing boss 41 including the case fixing boss 41 has a function of preventing the generation of a groove due to a large amount of material shrinking during cooling after the injection of the heat dissipating body 3 as described above, .

In addition, the heat-dissipating upper case 5 is formed by injection molding using a heat-dissipating resin material having a conductivity similar to that of the heat dissipating body 3, and is provided with a spiral socket fitting 8, Is detachable through a screw or the like which is engaged with the case fixing boss 41 of the auxiliary heat sink plate 4 in a state of being mounted on the upper surface of the heat dissipator body 3 And performs a combined function of dissipating a part of the residual heat of the LEDs 21 transmitted through the heat discharging body 3 including the heat generated from the power supply unit 6 installed inside.

The heat dissipation resin material of the conductive polymer used for injection molding the heat dissipator 3 and the heat dissipation upper case 5 has a thermal diffusion coefficient of 0.75-0.8 [cm 2 / sec] and a thermal conductivity of 90-150 (CNT) having a specific surface area of [W / mK], a density of 1.4 ± 0.2 [g / cm 3], a melting temperature of 105 to 160 ° C. and a specific heat of 1.1 ± 0.4 [J / gK] Carbon nanotube metal polymer (CMP).

When the heat dissipating body 3 and the heat-dissipating upper case 5 are extruded with a carbon nanotube metal polymer (CMP), the density and specific heat are 1.4 ± 0.2 g / cm 3 and 1.1 ± 0.4 J / unlike aluminum, which has a density and specific heat smaller than that of aluminum with 2.7 [g / cm3] and 0.9 [J / gK] and thermal diffusivity of 0.6-0.84 [cm2 / sec] Cm < 2 > / sec].

Accordingly, when the heat dissipator 3 and the heat-dissipating upper case 5 are formed of a carbon nanotube metal polymer (CMP) having characteristics of excellent thermal conductivity rather than that of aluminum, which is conventionally widely used, Since the atmospheric release performance of the thermoelectrometer is extremely high even when the heat dissipating body 3 and the heat dissipating upper case 5 are formed with aluminum with a smaller surface area and volume than the aluminum thermoplastic body 3, the carbon nanotube metal polymer (CMP It is possible to significantly increase heat dissipation performance and optical efficiency for heat generated by the power supply unit 6 including the LEDs 21 and to provide a light emitting diode lighting device for cultivating a multi- The product itself can be made lighter and smaller in manufacturing, and manufacturing costs can also be reduced.

The power supply unit 6 is installed in the heat-dissipating upper case 5 to supply the power supply voltage necessary for driving the color LEDs 21 required for germination and cultivation of various kinds of mushroom crops. Function.

In the present invention, a binary switch (22) for wavelength control is provided on each LED printed circuit board (2) of the LED lighting module (100), and the dip switch or the binary output rotary switch ) And the power supply terminal of the LED printed circuit board 2 so that the user can control the color and the wavelength of the light emitted from the plurality of color LEDs 21 through the wavelength- ㎚) can be selected to have a mixed color and wavelength determined according to the type of mushroom to be cultivated, germination and growth period.

Therefore, different kinds of crops or different mushroom crops can be smoothly grown in the same place and space, and compatibility and usability of the light-emitting diode lighting apparatus itself for mushroom growing can be improved. In particular, The production cost of mushroom crops can be greatly reduced. In order to control the price of mushrooms and varieties, it is possible to adjust the cultivated varieties by predicting the yields and yields of varieties in advance. .

At this time, the density of photons of each LED lighting module 100 installed in a light emitting diode lighting apparatus to which the present invention is applied is made to have an optimum photon density of 4 ~ 6W for growing various mushroom crops.

The connection state and the arrangement state of the LEDs 21 of various colors installed on the LED printed circuit board 2 of the LED lighting module 100 and the wavelength-controlling binary switch 22 are shown in FIGS. 4 and 5 FIG. 4 is a plan view of the LED printed circuit board 2 installed in the LED lighting module 100 of the present invention. FIG. 5 is a plan view of the LED lighting module 100 of the present invention. And a circuit diagram of the circuit board 2 is shown.

In addition, the wavelength-tunable binary switch 22 includes a dip switch and a binary output rotary switch. By using the wavelength-tunable binary switch 22, the main wavelength (nm) of the light source and the color The major varieties of mushroom cultivars to be cultivated and the color of the senses following the mixing are shown in Table 1 below.

Binary switch for wavelength control
Selection number Blue / 450 [nm]
+ UV /
400 [nm] (6.5: 3.5)
Green / 520
[nm] Cherry RED / 700 [nm] + RED 620 [nm]
(6: 4)
Sight
color Main light source
wavelength
[nm]

Major varieties applied 0 off
One
ON
blue
390 to 470 Oyster mushroom, Zelgium strand mushroom, shiitake mushroom, throat mushroom, mushroom mushroom, mushroom mushroom, bold mushroom
Mushroom 2 ON Green 500 to 540 High-quality large oyster mushroom, shiitake mushroom for sawdust cultivation 3 ON ON sky 390 ~ 540 Large Pleurotus mushroom 4 ON Red 610-710 Mushroom, oyster mushroom 5 ON ON pink 400 & 640 (No test results of the corresponding varieties) 6 ON ON Orange 520 & 640 Snowflake mushroom 7 ON ON ON yellow 390 to 710 Pleurotus ostreatus

Uniqueness 1. The reason for distinguishing the 7 single and mixed wavelengths is to select and use the effective radiation wavelength of LED according to various kinds of mushrooms and other cultivation environment.
2. In order to control the price of mushrooms and varieties, the municipalities are required to predict the yields of varieties beforehand and to protect the farmers by adjusting the cultivars.

That is, when the user selects "0" by operating the dip switch or the binary switch for wavelength adjustment 22, which is a binary output rotary switch, the LED lighting module 100 is mounted on the LED printed circuit board 2 All the color LEDs 21 remain turned off. When selecting "1", blue and infrared rays are mixed at a ratio of 6.5: 3.5, It has a blue light shape of 390 ~ 470 (㎚) wavelength suitable for cultivation of Zelkova strand mushroom, shiitake mushroom, thorny mushroom, top mushroom, leaf mushroom and coarse mushroom.

When "2" is selected, green light is irradiated, which has a green light shape of 500 to 540 (nm) wavelength suitable for cultivation of high-quality large oyster mushroom or sawdust-cultivating shiitake mushroom, and When "3" is selected, a mixed color light including 6.5: 3.5 ratio of blue and infrared (UV) is irradiated, which is suitable for the cultivation of large oyster mushroom at 390 ~ 540 ) Will have a light blue form of light.

When "4" is selected, Cherry RED and RED are mixed at a ratio of 6: 3, which is irradiated with a mushroom of 100 to 200 [Lux] It is a mixed color of 610 ~ 710 (㎚) wavelength range suitable for the cultivation of Gyotae jinjyeong, that is, red light.

When "5" is selected, mixed color (pink) light of blue and infrared (UV), cherry red and red is irradiated with a wavelength band of 400 & 640 (nm) There are no experimental results of the appropriate varieties.

When "6" is selected, a mixture of green, cherry red and red is irradiated. This is because the luminous intensity of red LED is 20 [u-mol / (Nm)], which is suitable for the cultivation of the plant.

When "7" is selected, a mixture of blue and infrared (UV), green (Green), cherry red (RED) and red (RED) Has a yellow (also known as "amber") light form at a suitable wavelength of 390 to 710 (nm).

Here, the center wavelengths used in the light emitting diode lighting apparatus for cultivating a mushroom cultivating variety to which the present invention is applied are shown in a graph form, and the wavelengths of various colors irradiated from the plurality of LEDs 21 mentioned above are different from each other .

In the present invention, a tool insertion hole 14 is further formed at the center of the translucent plate 1, that is, at the position where the wavelength-tunable binary switch 22 is installed, A tool such as a driver may be inserted through the tool insertion hole 14 formed at the center to appropriately operate the wavelength control binary switch 22 provided on the LED printed circuit board 2. [

Therefore, when a user wishes to cultivate a specific mushroom crop by using the light-emitting diode lighting apparatus for cultivating a mushroom of the present invention, the light-emitting diode lighting apparatus is separated from the socket 81 or the like, A tool such as a driver is inserted through a tool insertion hole 14 formed at the center of the translucent plate 1 from the outside and then mounted on the LED printed circuit board 2 with a wavelength adjusting binary switch 22) can be appropriately operated so that mixed light of the wavelength set according to the variety, germination or growth condition of the mushroom crop can be output, so that the product itself is highly usable and compatible.

Further, in the present invention, a plurality of cap engaging pieces 13 are formed integrally with the outside of the transparent plate 1 with a predetermined gap, and a handle 72 is provided on one side thereof, and along the upper inner circumferential portion, A transparent cap 7 formed by a transparent synthetic resin material is provided on the outer side of the transparent plate 1 so as to form an engaging groove 72 in which the cap engaging piece 13 of the transparent plate 1 is caught and hooked, It is possible to prevent the transparent plate 1 itself from being contaminated by various foreign substances and to prevent the foreign materials from flowing into the LED printed circuit board 2 through the tool insertion hole 14 to be contaminated.

At this time, when the transparent cap 7 itself is contaminated due to moisture, water vapor and dust during the cultivation of various mushroom crops due to the consumable property, the transparent cap 7 may be used as a consumable product Only the transparent cap 7 is detached from the transparent plate 1 and replaced with a new one so that electric safety accidents (that is, electric shock accidents) that may occur when the transparent plate 1 of the LED lighting module is directly cleaned Not only can it be prevented in advance, but also the merchandise performance, reliability and safety of the product itself can be greatly improved.

1 to 3, a spiral socket coupling hole 8 for supplying an AC voltage to the power supply unit 6 is further provided in the coupling protrusion 51 of the heat-dissipating upper case 5 according to the present invention The LED lighting module 100 to which the present invention is applied can be screwed into the socket 81 like a general light bulb.

In the present invention, the spiral socket coupling 8 as described above may not be provided on the coupling protrusion 51 of the heat-radiating upper case 5, and if necessary, the power supply unit 6 A connector 62 is provided at an end of the power supply line 61 in a state where a part of the connected power supply line 61 is exposed to the outside of the coupling protrusion 51 of the heat dissipating upper case 5.

A plurality of LED lighting modules 100 are fixed to a module fixing plate 9 having a predetermined shape by drilling the module fixing plate 9 so as to have a desired output on the outer circumferential surface of the bottom portion of the heat- A locking protrusion 56 which is engaged with the upper surface of the module fixing plate 9 around the module mounting hole 91 when the module fixing hole 9 is fitted into the mounting hole and A plurality of elastic catching pieces 57 are integrally formed to hold the LED lighting modules in a state where they are integrally fixed to one module fixing plate 9. [

In addition, the connectors 62 provided in the power supply lines 61 of the LED lighting modules, as described above, are coupled vertically in the central upper surface of the module fixing plate 9 on which the several LED lighting modules 100 are installed A power supply rod 92 provided with a plurality of connector coupling apertures 93 for connecting the power supply rod 92 to the power supply rod 92 is provided at the upper end of the power supply rod 92, And a plurality of LED lighting modules are provided integrally with one module fixing plate 9 as shown in FIG. 6 by providing a coupling hole 8 so as to form a spiral shape, such as a regular light bulb, provided at the upper end of the power supply rod 92, It can be used by screwing it into the socket 81 by using the socket coupling hole 8.

Therefore, it is possible to easily manufacture and use the light emitting diode lighting device for cultivating a variety of mushroom crops, which requires several LED lighting modules, so that the production cost and the installation cost of the product can be greatly reduced or decreased, and unnecessary resource waste can be prevented , Especially the compatibility of the LED lighting module itself can be improved, so that it is possible to meet various lighting apparatuses of users which are variously required.

As shown in FIG. 8, when the light emitting diode lighting apparatus for cultivating a variety of mushroom crops having such a structure is installed in a multi-stage in various mushroom cultivation shelves 200, the production amount of mushrooms per unit area (1 m X 1 m) In addition to increasing the cultivation efficiency of mushroom crops including the production cost per cost, it is possible to lower the production cost of the product through cost reduction, and it can be used freely regardless of places because it is waterproof and moisture resistant. Unlike a discharge lamp, it is free from heavy metal pollution, and can be used as green light, contributing to eco-friendly production and green growth, and can be driven with low power consumption to save energy cost considerably. It can be protected by a safety circuit.

In addition, when the LED lighting module 100 is manufactured by a plurality of LED lighting modules 100, unlike an existing discharge lamp, even if one of the plurality of LED lighting modules is defective, the other modules can operate normally, , It is convenient to replace and repair individual modules, has a very long life, can cultivate and produce various mushroom crops for 365 days regardless of climate change, can save more than 80% of energy compared to existing incandescent lamps, It is an eco-friendly product that does not use mercury or heavy metals and can effectively grow various mushroom crops without using chemical fertilizers.

Although the preferred embodiments of the present invention have been described for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. Which will be apparent to those skilled in the art.

1: Transparent plate
13: Cap engaging piece 14: Tool insertion hole
2: LED printed circuit board
21: LED 22: binary switch for wavelength adjustment
3: Heat radiator 31: Streamline heat radiator
4: auxiliary heat sink 41: case fixing boss
5: heat-dissipating upper case 51:
56: Retaining tab 57: Elastic retaining piece
6: Power supply
61: power supply line 62: connector
7: Transparent cap
71: latching groove 72: handle
8: Spiral socket coupling port 81: Socket
9: Module fixing plate 91: Module mounting hole
92: Power supply rod 93: Connector coupling port
100: LED lighting module
200: Mushroom cultivation lathe

Claims (8)

A translucent plate detachably coupled to the bottom of the heat radiator; An LED printed circuit board having a plurality of colored LEDs mounted thereon and generating light required for cultivation of various mushroom crops; A heat dissipating member for dissipating heat generated from the LED; An auxiliary heat sink for performing a heat dissipation function and a function for preventing the formation of a groove for generating an air layer between the contact surfaces with the LED printed circuit board due to a part of the heat shrinkage caused by the cooling of the heat dissipation member; A heat dissipation type upper case for dissipating some residual heat of LEDs transmitted through the heat dissipation body including heat generated from a power supply unit; And a power supply unit for supplying a power supply voltage necessary for driving the LEDs. The LED lighting module is installed on an upper part of a multi-stage mushroom cultivation lathe and generates an output of density of photons necessary for the cultivation of various mushroom crops. Or a plurality of module fixing plates having a predetermined area are provided, so that it can be used as a light emitting diode lighting device for cultivating a variety of mushroom crops,
A binary switch for wavelength control is provided on each LED printed circuit board of the LED lighting modules, and the output terminal of the power supply unit and the power supply terminal of the LED printed circuit board are connected in series, Characterized in that the color and wavelength (nm) of the mushroom to be cultivated are selected so as to have a mixed color and a wavelength determined according to the kind of mushroom to be cultivated and germination and growth period.
The method according to claim 1,
Wherein a density of photons of the LED lighting module is 4 to 6W.
The method according to claim 1,
Wherein the wavelength-tunable binary switch includes a dip switch and a binary output rotary switch.
The method according to claim 1 or 3,
When the binary control switch for wavelength adjustment is set to "0 ", all the plurality of color LEDs provided on the LED printed circuit boards of the respective LED lighting modules are turned "off"
When set to "1", blue and infrared rays with a wavelength band of 390 to 470 (㎚) suitable for growing oyster mushroom, Zelkova mushroom, shiitake mushroom, thorny mushroom, top mushroom, (UV) are mixed and irradiated,
When set to "2 ", green light having a wavelength range of 500 to 540 (nm) suitable for the cultivation of high-quality large oyster mushroom or sawdust cultivation mushroom is irradiated,
(Sky blue) light of blue, infrared (UV) and green color (green) so that light having a wavelength range of 390 to 540 (nm) suitable for the cultivation of large oyster mushroom can be irradiated when it is set to "3"Lt; / RTI >
When set to "4", mushrooms (100 to 200 [Lux] light quantity is required for mushroom mushroom cultivation), 610 ~ 710 (㎚) wavelength range suitable for cultivation of Mushrooms (Red) light of red (RED) and red (RED) is irradiated so that the light having the red (RED)
When set to "5", there are no experimental results of the corresponding varieties, but blue (blue) and infrared (UV), red (Cherry RED) and red (RED) Allowing the mixed color (pink) light to be irradiated,
When set to "6 ", green light is used to illuminate light having a wavelength band of 520 & 640 (nm) suitable for cultivation of snowy mushroom mushroom (the luminous intensity of red LED is 20 [u-mol / (Orange) light of green (Cherry RED) and red (RED)
When set to "7", blue light and infrared light (UV), green color (Green), and purple (Cherry) are applied to light having a wavelength range of 390 to 710 RED) and red (RED) mixed light (yellow) light is irradiated to the respective color LEDs. The light emitting diode lighting apparatus of claim 1,
The method according to claim 1,
Wherein the translucent plate further comprises a tool insertion hole for allowing a user to operate the wavelength control binary switch using a tool from the outside.
The method of claim 5,
A transparent cap including an outer surface of the transparent plate and having a handle for preventing the contaminants from flowing into various LEDs through the tool insertion hole toward the LED printed circuit board is detachably mounted on the outer side of the transparent plate Light emitting diode light fixture for cultivating various kinds of mushroom crops.
The method according to claim 1,
Wherein the LED lighting module is provided with a spiral socket coupling hole for screwing the LED lighting module into the socket like a general bulb, in the coupling protrusion of the heat-dissipating upper case.
The method according to claim 1,
Wherein a part of the power supply line connected to the power supply unit is exposed to the outside of the coupling protrusion of the heat-dissipating upper case, and a connector is provided at the exposed end of the power supply line.

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