JP2006005515A - Transparent device for radio wave or the like - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transparent device for a radio wave or the like adapted to an exterior door mirror and an exterior sun visor for an automobile incorporating, e.g. a light source and an antenna member, having both a reception function of a prescribed radio wave and a light emission function, capable of obtaining both acting effects, preventing damages of them and occurrence of a defect and extending the lifetime. <P>SOLUTION: A paste coat layer 8 is coated on the surface of a synthetic resin made base member 7. A metallic thin film layer 9 is coated on the surface of the base coat layer 8. The metallic thin film layer 9 is formed by providing very small gaps among metallic fine particles 11. A top coat layer 10 is coated on the surface of the metallic thin layer 9. At least part of each of the layers is formed to be a transparent device for a radio wave or the like provided with a transparent or translucent outer shell member 5. A light source 14 and an antenna member 17 are located apart from each other to one side of the outer shell member 5 in a thickness direction of the outer shell member 5, or located side by side at one side of the outer shell member apart from each other. A prescribed radio wave and light can be transmitted through the device. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  INDUSTRIAL APPLICABILITY The present invention is suitable, for example, for an automobile exterior door mirror or exterior side visor with a built-in light source and antenna member. In addition, the appearance of a metallic brilliant color can be obtained, the design aesthetics and high quality can be obtained, while the radio wave and light impermeability caused by the plating film is eliminated, and the outer shell member has flexibility. The present invention relates to a transmission device for radio waves and the like that can relieve shock and stress during use and manufacture, prevent breakage and failure, and improve life.

Conventionally, as a design automotive lamp having a metallic brilliant color, an inner lens is disposed in front of a light source, and a half mirror on which a metal film of aluminum or chromium is deposited is provided on the surface of the inner lens. Some have an outer lens arranged in front of a half mirror.
The lamp has a metal-like hard image when it is not lit so that the inside is not visible, and when lit, the light from the light source is transmitted through a half mirror and emitted to the outside ( For example, see Patent Document 1).

  However, since the lamp emits light from the light source through the half mirror when it is turned on, there is an unreasonable reason that the light quantity of the light source cannot be effectively used. There was a problem that the lamp could not be used to provide a radio wave receiving function.

In other words, recent automobiles are equipped with or desired to be equipped with a receiving antenna such as a radio, a radar for measuring the distance between vehicles, and a receiving antenna for a door lock remote control.
Although these receiving antennas are attached to be exposed at a predetermined position of the automobile or are concealed, they are preferably concealed as much as possible from the appearance of the automobile.
From this point of view, there is a conventional antenna having a reception antenna attached to an emblem or a front grill of an automobile (see, for example, Patent Documents 2 to 4).

  However, in the above, a metal layer that transmits radio waves of a certain wavelength and reflects light completely is formed on the back surface of the emblem, or a metal layer made of indium is deposited inside the emblem, and the back of the metal layer In addition, a black coating is placed on the front grille, and a metal layer made of indium is vapor-deposited on the coated parts of the front grille, and the surface of this metal layer is covered with an opaque layer, so that it can transmit certain radio waves. The irradiation of light from the inside of the metal layer is blocked, and there is a problem that both functions cannot be obtained.

JP 2003-115206 A JP 2000-49522 A JP 2002-135030 A Japanese Unexamined Patent Publication No. 2000-159039

  The present invention solves such problems, and is suitable for, for example, an automobile exterior door mirror or exterior side visor with a built-in light source and antenna member, and has both a predetermined radio wave reception function and a light irradiation function, While obtaining the effects of both, the appearance of a metallic brilliant color can be obtained, its design aesthetics and high quality can be obtained, while the radio wave and light imperviousness caused by the plating film is eliminated, and it is possible. It is an object of the present invention to provide a transmission device for radio waves and the like that can relieve shock and stress in use and manufacture by a flexible outer shell member, prevent the occurrence of breakage and failure, and improve the life.

  According to the first aspect of the present invention, a base coat layer is coated on the surface of a synthetic resin base material, and a metal thin film layer is coated on the surface of the base coat layer. In a transmission device for radio waves or the like, in which a minute gap is provided between the metal thin film layers and a top coat layer is covered on the surface of the metal thin film layer, and at least a part of each layer includes a transparent or translucent outer shell member. The light source and the antenna member are arranged apart from each other in the thickness direction of the outer shell member on one side of the outer shell member, or arranged side by side separated from the one side of the outer shell member, so that predetermined radio waves and light are transmitted. It is possible to transmit and have both the function of receiving a predetermined radio wave and the function of irradiating light so that both functions and effects can be obtained, and various radio wave transmission devices can be obtained by arranging the light source and the antenna member. In addition, a transmissive device that exhibits a metallic luster color by the reflected light from the metal thin film layer. The design aesthetics and high quality are obtained, while the radio wave and light impervious obstacles due to the plating film are eliminated, and the flexible outer shell member is used and manufactured. The impact and stress are alleviated to improve the lifetime of the transmission device.

According to a second aspect of the present invention, the light source and the antenna member are disposed in a closed space surrounded by an outer shell member, so that the light source and the antenna member can be reliably and firmly protected, and the occurrence of breakage or failure can be prevented. I have to.
According to a third aspect of the present invention, the light source and the antenna member are arranged on one side surface of an opened outer shell member so that both a predetermined radio wave receiving function and a light irradiation function can be obtained with a simple configuration. Yes.
According to a fourth aspect of the present invention, the transmission device for radio waves is an exterior mirror for automobiles, and an exterior mirror exhibiting a metallic brilliant color can be obtained, and its design aesthetics and high quality can be obtained. The radio wave and light impermeability caused by the plating film can be eliminated.
In the invention of claim 5, the radio wave transmission device is an exterior side visor for automobiles, an exterior side visor exhibiting a metallic glitter color can be obtained, and its design aesthetics and high quality can be obtained. The radio wave and light impermeability caused by the plating film can be eliminated.

According to the first aspect of the present invention, the light source and the antenna member are arranged on one side of the outer shell member so as to be spaced apart from each other in the thickness direction of the outer shell member, or spaced apart from each other on the one side of the outer shell member, and Since the light source and the antenna member are arranged facing the transparent or translucent region of the outer shell member so that a predetermined radio wave and light can be transmitted, both a predetermined radio wave reception function and a light irradiation function are combined. In addition to obtaining the effects of both, a transmission device for various radio waves and the like can be obtained by the arrangement of the light source and the antenna member, and a transmission device exhibiting a metallic glitter color can be obtained by the reflected light from the metal thin film layer. While achieving design aesthetics and high quality, it eliminates radio wave and light impermeability caused by the plating film, and further reduces impact and stress during use and manufacturing with a flexible outer shell member. To improve the life of the permeation device It is possible.
In the invention of claim 2, since the light source and the antenna member are arranged in a closed space surrounded by an outer shell member, the light source and the antenna member are securely and firmly protected, and the occurrence of breakage or failure thereof is prevented. Can do.

In the invention of claim 3, since the light source and the antenna member are arranged on one side surface of the open outer shell member, it is possible to obtain both a predetermined radio wave receiving function and a light irradiation function with a simple configuration. .
In the invention of claim 4, since the transmission device for radio waves is an automobile exterior mirror, an exterior mirror exhibiting a metallic brilliant color can be obtained, and its design aesthetics and high quality can be obtained. At the same time, the radio wave and light impermeability caused by the plating film can be eliminated.
In the invention of claim 5, since the transmission device for radio waves is an exterior visor for automobiles, an exterior visor exhibiting a metallic glitter color can be obtained, and its design aesthetics and high quality can be obtained. At the same time, the radio wave and light impermeability caused by the plating film can be eliminated.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring to FIG. 1 to FIG. 3, reference numeral 1 denotes a front pillar disposed at a side edge of a windshield 2 provided at the lower portion thereof. A door mirror 4 is attached via the bracket 3.
The door mirror-4 has a mirror housing 5 that exhibits a metallic brilliant color as an outer shell member, and the housing 5 is formed into a hollow, substantially bullet-shaped shape by acrylic resin or polycarbonate resin having excellent transparency. A synthetic resin mirror cover 6 that divides the outside of the standard mounting door mirror is fitted and attached to the inside.

  The mirror housing 5 is configured so that at least an irradiation portion of a lamp body, which will be described later, is transparent or semi-transparent, and this includes a housing base 7 made of synthetic resin as a base material forming the main body of the housing 5, and the housing A base coat layer 8 covering the surface of the base 7, a metal thin film layer 9 covering the surface of the base coat layer 8, and a top coat layer covering the surface of the metal thin film layer 9 10 are stacked and arranged.

The housing base 7 is formed in an approximately similar shape to the housing 5 by an acrylic resin or polycarbonate resin having excellent transparency, and the base coat layer 8 is a base coat of a resin system. The coating agent is formed to a thickness of about 15 μm.
The metal thin film layer 9 is made of indium, chromium, nickel, aluminum, titanium, iron, gold, silver, lead or the like, or an alloy thereof, in the embodiment, indium, with a thickness of about 80 nm by appropriate means such as vacuum deposition. The top coat layer 10 is formed by applying a resin type top coat agent to a thickness of about 20 μm.

  As shown in FIG. 3, the metal thin film layer 9 of the embodiment is formed by separating indium metal fine particles 11 into a minute gap 12, and a top coat layer 10 is interposed in the minute gap 12 to obtain a base coat. The layer 8 is in close contact.

  A transparent or semi-transparent synthetic resin lamp case 13 is attached in close contact with the inner surface of the central portion of the front side 5a of the mirror housing 5 via an appropriate recess 21. A plurality of LEDs 14 which are lamps are arranged, and these LEDs 14 are connected to a power source such as a battery. In the embodiment, the LED 14 can be turned on in synchronization with the operation of a turn signal lamp (not shown) or for vehicle width confirmation.

  The mirror cover 6 is resin-molded into a hollow, substantially bullet-like shape that is shorter than the mirror housing 5, and its front end portion is disposed close to the rear of the lamp case 13, and thereafter A double-sided adhesive tape 15 is attached to the part-side peripheral surface, and is adhered and fixed to the rear-side inner surface of the mirror housing 5.

On the inner surface of the front end portion of the mirror cover 6, an antenna holding piece 16 having engaging elasticity is projected and formed into a plurality or a bead shape, and these are substantially ring-shaped as shown in FIG. The antenna member 17 is attached to or formed on the antenna member 17 and can receive radio waves of a predetermined wavelength.
In the embodiment, as the antenna member 17, a linear antenna or a loop antenna having a simple configuration in which a conductor having a predetermined length is arranged in a linear shape or a substantially loop shape is used, and this is used as a receiving antenna of a door remote controller. The terminal portion is connected to a receiving device (not shown) in the passenger compartment.

  In addition, in the figure, 18 is a convex spherical plate-shaped mirror disposed at the rear end of the mirror cover 6, and 19 is a mirror holder to which the mirror 18 is attached. It is pivotally connected to a drive shaft 20 (not shown) so as to be swingable. 22 is a side window glass.

A transmission device for radio waves and the like applicable to the door mirror 4 configured as described above requires a synthetic resin mirror housing 5 capable of transmitting radio waves and a mirror cover 6 of a standard mounting door mirror. The resin is molded into a suitable shape.
In the embodiment, the mirror housing 5 and the mirror cover 6 are formed in two large and small hollow substantially bullet shapes, and these can be fitted.

Of these, a large mirror housing 5 is formed in a multilayered laminated structure, and a synthetic resin housing base 7 which is the main body is molded into a predetermined shape, and a base is formed on the surface of the base 7. The scouring agent is applied to a thickness of about 15 μm to cover the basal layer 8.
Next, the metal thin film layer 9 is coated on the surface of the base coat layer 8 by forming indium metal fine particles 11 to a thickness of about 80 nm by an appropriate means such as vacuum deposition. At this time, the metal fine particles 11 of indium are separated from the minute gaps 12 to form the metal thin film layer 9.

  Thereafter, the metal thin film layer 9 is irradiated with ultraviolet rays to modify the surface thereof, and a top coat layer 10 is applied to the metal thin film layer 9 to a thickness of about 20 μm. The top coat layer 10 is intervened and brought into close contact with the base coat layer 8.

After manufacturing the mirror housing 5 in this way, the lamp case 13 assembled with the plurality of LEDs 14 is attached to the recess 21 formed on the inner surface of the central portion of the front side 5a by an adhesive means and the like. -Attach the housing 5 to the mirror cover 6 and interpose a double-sided adhesive tape 15 between them to bond and fix them; Thereafter, the antenna member 17 is mounted and wired on the antenna holding piece 16 of the mirror cover 6, and the position change motor, the mirror holder 19, the mirror 18 and the like are assembled.

When the assembled door mirror-4 is attached to a vehicle, it is attached to the front pillar 1 via the bracket 3 and a terminal of a lead wire (not shown) that conducts to the antenna member 17 is connected to a receiving device (not shown) in the passenger compartment. ) And a lead wire (not shown) that is electrically connected to the LED 14 is connected to a power source on the vehicle side.
As described above, since the door mirror 4 according to the embodiment can be attached in the same manner as the conventional one, this can be easily performed.

The door mirror 4 thus attached to the vehicle is as shown in FIG. 1, and is slightly larger than the conventional standard-equipped door mirror so as to protrude slightly forward by the space of the mirror housing 5.
The door mirror-4 is protected by being surrounded by a mirror housing 5 and light is transmitted from the top coat 10 in the daytime portion, which is reflected by the metal thin film 9 and irradiated to the outside. Therefore, the entire mirror housing 5 exhibits a metallic brilliant color, has a design aesthetic feeling compared to a conventional door mirror, and has a high quality feeling.

Next, the door mirror 4 is used by driving the position change motor in the same manner as in the prior art, rotating the door mirror 4 around the pivotal support (not shown) of the bracket 3 and moving the mirror 18 to a predetermined position. Can be used for confirmation of the rear view.
Further, when the automobile is driven, the LED 14 is turned on in synchronization with the turn signal lamp, and in addition to the display or the visual effect by the turn signal lamp, the LED 14 is turned on to display to surrounding traveling vehicles, pedestrians and the like. It is possible to improve the safety of road traffic by expanding the function of the turn signal lamp. In particular, this effect is conspicuous during twilight or at night when it is difficult to visually recognize the display of the turn signal lamp.

In this case, the metal thin film layer 9 in the mirror housing 5 has the metal fine particles 11 spaced apart by forming a minute gap 12, so that the light from the LED 14 slightly decreases from the minute gap 12 portion to the outside. Irradiated.
Therefore, in order to obtain the same metallic brilliant color on the door mirror-4, there is no problem that the transmission or irradiation of light is blocked by the plating film of the metal plating that is usually taken.

On the other hand, the door mirror-4 can receive a predetermined radio wave.
That is, the propagation area of the radio wave from the mirror housing 5 of the door mirror 4 to the antenna member 17 includes the mirror housing 5, the lamp case 13 including the LED 14, and the mirror cover 6.
Among them, the lamp case 13 and the mirror cover 6 are made of synthetic resin, and the housing base 7 of the mirror housing 5, the base coat layer 8, and the top coat layer 10 are made of synthetic resin. Since they are made of resin, they do not hinder the transmission of radio waves.

Further, the metal thin film layer 9 in the mirror housing 5 has a fine gap 11 formed by fine metal particles 11 and a base coat layer 8 and a top coat layer which are synthetic resin layers on both sides of the fine gap 12 portion. 10 are adjacent to each other. For this reason, the 12 portions of the minute gap form a propagation path of the radio wave, and the radio wave is transmitted from the portion to reach the antenna member 17.
Therefore, in order to obtain the same metallic luster color in the door mirror-4, there is no problem that radio wave transmission is blocked by the plating film of the metal plating that is usually taken.

  Therefore, for example, when a driver or the like operates the door remote controller toward the door mirror 4 when getting on and off the automobile, the control radio wave emitted from the remote controller is input to the mirror housing 5 and is minutely transmitted from the top coat layer 10. Through the gap 12, the light passes through the base coat layer 8 and the housing base 7, reaches the antenna member 17 from the mirror cover 6, and the antenna member 17 receives the radio waves of the remote controller.

Thereafter, the received radio signal of the remote controller is guided to a receiving device (not shown) in the passenger compartment, the received radio wave is demodulated by the receiving device, and a signal corresponding to the transmission signal is output from the output unit.
In the embodiment, a control signal corresponding to the operation content of the door remote controller is input from the receiving device to a door locking / unlocking drive motor (not shown), and the motor is driven to lock the door lock. Or unlock.

On the other hand, the metal thin film layer 9 of the mirror housing 5 has the fine metal particles 11 forming the minute gaps 12, so that it can be bent in the thickness direction compared to the case where the fine metal particles 11 are dense and continuous. Since the top coat layer 10 enters the minute gap 12 and is in close contact with the base coat layer 8, the top coat layer 10, the metal thin film layer 9 and the base coat layer 8 are in close contact with each other. The force is strengthened, preventing delamination and making the mirror housing 5 flexible.
Therefore, in order to obtain a metallic luster color on the door mirror-4, the plating film of the metal plating that is usually taken does not break due to stress and does not cause delamination.

Therefore, the door mirror 4 is surrounded and protected by the mirror housing 5 as described above, and even if it is in contact with other members during use, the shock is buffered or the stress is reduced, and the mirror housing 5 itself is damaged. This prevents the spread of damage to the inside of the door mirror 4 and improves its service life. This is the same as when the door mirror 4 is assembled, and the mirror housing 5 comes into contact with or scrapes adjacent members. However, the damage is prevented and the workability of the assembly is improved.

4 to 7 show other embodiments of the present invention, and the same reference numerals are used for the components corresponding to the above-described embodiments.
In this embodiment, the present invention is applied to an automotive exterior side visor, and a synthetic resin side visor 23, like the above-described mirror housing 5, exhibits a metallic bright color and can transmit light and radio waves. It is configured.

  That is, as shown in FIG. 7, the side visor 23 is a plate-like side visor base 7 which is a base material of the side visor 23, a base coat layer 8 covering the surface, and the base visor 23. A metal thin film layer 9 that covers the surface of the coat layer 8 and a top coat layer 10 that covers the surface of the metal thin film layer 9 are stacked and arranged.

A lighting case 13 is attached to the inner surface of the rear end of the side visor 23, and an antenna holding piece 16 is projected over the entire upper inner surface of the side visor 23. The holding piece 16 receives radio waves of a predetermined wavelength. A possible antenna member 17 is attached.
In addition, in the figure, reference numeral 24 denotes a double-sided adhesive tape 24 bonded to the peripheral surface of the upper end portion of the side visor 23, and the other end is bonded to a sash frame 25 attached to the peripheral edge of the side window glass 22, and 26 denotes a side visor. It is a mounting frame attached to the upper periphery of -23.

  By configuring the side visor 23 in this way, the side visor 23 has a metallic brilliant color, has a design aesthetics and a high-quality feeling, and allows the light of the LED 17 to be transmitted to the outside. Can be received by the antenna member 17 and used as described above.

  Therefore, in order to obtain the same metallic brilliant color on the side visor, there is no problem that the transmission or irradiation of light is blocked or the transmission of radio waves is blocked by the plating film of the metal plating that is usually taken, and it acts on the plating film. It does not break when stressed and causes delamination.

  As described above, the transmission device for radio waves and the like according to the present invention has both a predetermined radio wave reception function and a light irradiation function, and can obtain both functions and effects, and an appearance exhibiting a metallic brilliant color. While achieving a beautiful aesthetics and high quality, it eliminates obstruction of radio waves and light caused by the plating film, and also has a flexible outer shell member that reduces impact and stress during use and manufacturing. Therefore, it is possible to prevent the occurrence of breakage or failure and to improve the service life. For example, it is suitable for an exterior door mirror or exterior side visor of an automobile incorporating a light source and an antenna member.

In the perspective view which shows embodiment which applied this invention to the door mirror for the exterior of a motor vehicle, the condition seen from the front of the motor vehicle is shown. It is sectional drawing which follows the AA line of FIG. It is sectional drawing which shows the principal part of embodiment of FIG. 1 typically. It is a perspective view which shows other embodiment which applied this invention to the side visor for a motor vehicle exterior. It is sectional drawing which follows the BB line of FIG. 4, and has expanded and shown a little. It is sectional drawing which follows the CC line | wire of FIG. 4, and has expanded a little. It is sectional drawing which shows typically the principal part of embodiment of FIG.

Explanation of symbols

4 Domira
5 Outer shell member (mirror housing)
7 Base material (housing base, side visor base)
8 Base coat layer 9 Metal thin film layer 10 Top coat layer 11 Metal fine particles 12 Micro gap 14 Light source (LED)
17 Antenna member 23 Side visor

Claims (5)

  A base coat layer is coated on the surface of a base material made of synthetic resin, and a metal thin film layer is coated on the surface of the base coat layer. The metal thin film layer has a minute gap between metal fine particles. In a transmission device for radio waves or the like, in which a top coat layer is coated on the surface of the metal thin film layer, and at least a part of each layer includes a transparent or translucent outer shell member, A light source and an antenna member are arranged apart from each other in the thickness direction of the outer shell member, or are arranged side by side separated from one side of the outer shell member so that predetermined radio waves and light can be transmitted. Radio wave transmission device.   The radio wave transmission device according to claim 1, wherein the light source and the antenna member are disposed in a closed space surrounded by an outer shell member.   The radio wave transmission device according to claim 1, wherein the light source and the antenna member are arranged on one side of an open outer shell member.   The transmission device for radio waves or the like according to claim 1 or 2, wherein the transmission device for radio waves or the like is an automobile exterior mirror. 4. The radio wave transmission device according to claim 1, wherein the radio wave transmission device is a car exterior visor.

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