JP7099992B2 - Vehicle lights - Google Patents

Description

The present invention relates to a vehicle lamp body.

Conventionally, millimeter-wave radars (millimeter-wave sensors) using millimeter-waves have been known and are used in a wide variety of fields. The millimeter wave is, for example, an electromagnetic wave having an excellent straightness in a frequency range of 30 GHz to 300 GHz and a wavelength range of 1 mm to 10 mm, and has properties similar to light. Therefore, it can be handled like a laser. Therefore, a millimeter-wave radar using millimeter waves is not easily affected by weather, day and night, etc., and can be used, for example, to detect a distance, an angle, a speed, etc. from a detection target.

In order to utilize such characteristics of millimeter waves, vehicles equipped with millimeter wave radar have been put into practical use. For example, by mounting a millimeter-wave radar on the front side of a vehicle, it is possible to detect the distance between the vehicle and a vehicle traveling in front of the vehicle and use it in a front monitoring system or the like. Furthermore, by mounting a millimeter-wave radar on the rear side or side side of the vehicle, it can be used for rearward monitoring or side monitoring, which can contribute to safe driving support.

In mounting the millimeter-wave radar on the front side of the vehicle, for example, a vehicle lamp body in which the millimeter-wave radar is arranged in the lighting chamber of the headlight is known (see, for example, Patent Document 1).
In this vehicle lamp body, a light source unit, a millimeter wave radar, and a light guide lens are arranged in a lamp chamber formed between the lamp body and the outer lens. The light guide lens is arranged between the outer lens and the millimeter wave radar in a state of being located in front of the millimeter wave radar. The light guide lens is capable of emitting light when a part of the light emitted from the light source unit is incident on the light source unit, and is also capable of transmitting millimeter waves transmitted from a millimeter wave radar. .. Therefore, according to the conventional vehicle lamp body, it is possible to make the millimeter-wave radar inconspicuous as well as to make it appear as a lamp by emitting light from the light guide lens.

Japanese Patent No. 4842161

In the above-mentioned conventional vehicle lamp body, since the millimeter wave radar is arranged inside the lamp chamber, it is difficult to sufficiently secure heat dissipation. In particular, the light room is hermetically sealed and various parts are arranged in a densely packed state, so that heat tends to be trapped. As a result, it is difficult to sufficiently dissipate heat from the millimeter-wave radar, which may affect the radar performance.
Further, since the millimeter wave radar is arranged inside the light room, it is difficult to perform maintenance or replacement of the millimeter wave radar, for example. Therefore, the workability is poor and the cost is high, so that there is a problem in serviceability.

The present invention has been made in consideration of such circumstances, and an object of the present invention is to provide a vehicle lamp body capable of improving heat dissipation and serviceability.

(1) The vehicle lamp body according to the present invention comprises a housing, an outer lens that is combined with the housing so as to cover the housing from the outside of the vehicle, and forms a light chamber between the housing and the outer lens. Also provided inside the vehicle and with a millimeter wave radar capable of transmitting millimeter waves towards the outside of the vehicle, the outer lens is capable of transmitting the millimeter waves, and the millimeter wave radar is directed to the housing. It is held in the housing in a state of being combined from the inside of the vehicle, and at least a part thereof is exposed to the outside of the light room, and between the millimeter wave radar and the housing, between the millimeter wave radar and the housing. A seal member is provided to block communication between the inside and the outside of the light chamber through the gap, and a radar mounting hole is provided in the portion of the housing facing the outer lens in the front-rear direction of the vehicle. In addition to being formed so as to penetrate the radar, an annular seal frame is formed so as to surround the opening of the radar mounting hole. It comprises a bracket body surrounding the periphery and a radar bracket having a flange piece integrally formed with the bracket body and supporting the radar body, and the seal member is between the seal frame and the flange piece. It is characterized in that it is arranged in a ring shape and is mounted in a compressed state in the front-rear direction of the vehicle .

According to the vehicle lamp body according to the present invention, the millimeter wave transmitted from the millimeter wave radar can be transmitted toward the outside of the vehicle after being transmitted through the outer lens. In particular, since the millimeter wave radar is combined with the housing from the inside of the vehicle to expose at least a part of the millimeter wave radar to the outside of the light room, the heat dissipation of the millimeter wave radar can be improved. Therefore, the heat generated by the operation of the millimeter wave radar can be efficiently dissipated, and the stability of the operation can be appropriately maintained. Therefore, the radar performance can be stably maintained.
Further, since the sealing member can be used to block the communication between the inside and the outside of the lighting chamber through the gap between the millimeter wave radar and the housing, the airtightness of the lighting chamber can be appropriately ensured. .. Therefore, it is possible to prevent dust, moisture, and the like from entering the lighting chamber, and it is possible to ensure the reliability of the lamp body function in the vehicle lamp body.

Furthermore, since the millimeter wave radar is combined with the housing from the inside of the vehicle, the millimeter wave radar can be easily removed from the housing. Therefore, for example, maintenance and replacement of the millimeter-wave radar can be easily performed, these workability can be improved, and the cost associated with the work can be suppressed. This can lead to improvement of serviceability.

(2) A light source is provided in the lighting chamber, and the outer lens emits light by the light from the light source and can guide the light to be emitted to the outside of the vehicle. A rough surface portion may be formed to emit the emitted light in a predetermined light emission pattern.

In this case, the outer lens emits light by the light from the light source, and the light can be guided and emitted toward the outside of the vehicle. In particular, since the outer lens has a rough surface portion formed, the light guided by using this rough surface portion can be emitted toward the outside of the vehicle in a predetermined light emission pattern. Therefore, the light emitted from the outer lens itself and the light emitted from the outer lens can be used to obscure the millimeter-wave radar from the outside through the outer lens, and the existence of the millimeter-wave radar can be effectively hidden. Therefore, it is possible to provide an appearance that does not give a sense of discomfort, and it is possible to secure the design and design of the lamp body for a vehicle.

Further, since the millimeter wave radar can be made inconspicuous by using the outer lens having the rough surface formed as described above, the millimeter wave radar can be hidden between the outer lens and the millimeter wave radar. No need to place parts. As a result, the millimeter wave transmitted from the millimeter wave radar can be transmitted toward the outside of the vehicle by transmitting only one outer lens. Therefore, the attenuation of millimeter waves can be suppressed and the radar performance can be improved.

As described above, it is possible to secure the design by making the millimeter wave radar inconspicuous and to transmit the millimeter wave with suppressed attenuation with one outer lens, so compared to the conventional one. The number of parts can be reduced and the cost can be reduced. Further, since the light from the light source can be emitted in a predetermined light emission pattern by using the outer lens, it can be used as light for, for example, a position light, a stop light, a turn light, and the like.

(3) The rough surface portion may be formed on the inner surface of the outer lens facing the millimeter wave radar side.

In this case, since the rough surface portion can be directed to the inside of the vehicle, for example, dust and moisture from the outside are less likely to adhere to the rough surface portion, and the rough surface portion can be kept clean. Therefore, the radar performance can be stably maintained for a long period of time, and the light from the light source can be appropriately emitted in a predetermined light emission pattern.

(4) The rough surface portion of the outer lens has at least one of a plurality of convex portions protruding toward the millimeter wave radar side and a plurality of concave portions recessed toward the outside of the vehicle. Of these, the surface roughness is formed to be coarser than the outer surface facing the outside of the vehicle, and the plurality of the convex portions and the plurality of the concave portions reflect the light guided into the outer lens in the light emission pattern. It may be emitted to the outside of the vehicle.

In this case, it is simple to form at least one of a plurality of convex portions (for example, mountain-shaped, hemispherical shape, etc.) and a plurality of concave portions (for example, valley-shaped, hemispherical shape, etc.) on the inner surface of the outer lens. It is possible to form a rough surface portion with a flexible structure, and by utilizing the reflection by these multiple convex portions and concave portions, the light guided into the outer lens is directed to the outside of the vehicle in a predetermined emission pattern while changing the direction of the light. It can be properly emitted toward. In particular, since the light emission pattern can be set to an arbitrary pattern depending on the shapes of the plurality of convex portions and concave portions, the formation pattern, and the like, a desired light emission pattern can be easily and easily obtained.

According to the vehicle lamp body according to the present invention, it is possible to improve heat dissipation and serviceability, and it is also possible to make the millimeter wave radar difficult to see from the outside and provide good design.

It is a perspective view of the tail light unit provided with the sublight unit (vehicle lamp body) which concerns on this invention. It is a perspective view of the sublight unit shown in FIG. It is a cross-sectional view of the tail light unit along the line AA shown in FIG. It is a vertical sectional view of the tail light unit along the line BB shown in FIG. It is a figure which shows the state which the 1st light source and the 2nd light source emit light from the state shown in FIG. 3, and the millimeter wave radar transmits a millimeter wave. It is an enlarged vertical sectional view of the part surrounded by the C line shown in FIG. It is a perspective view of the millimeter wave radar shown in FIG. It is a top view of the millimeter wave radar shown in FIG. 7. It is a figure which shows the modification about the fixing method of a seal member, and is the vertical sectional view corresponding to FIG. It is a figure which shows another modification about the fixing method of a seal member, and is the vertical sectional view corresponding to FIG.

Hereinafter, embodiments of the vehicle lamp body according to the present invention will be described with reference to the drawings.
In the present embodiment, a case where the light body for a vehicle is applied to a tail light unit provided on the rear side of the vehicle will be described as an example.

As shown in FIG. 1, the rear portion of the vehicle body 1 is composed of, for example, a rear bumper 2, left and right rear fenders 3, a tailgate 4, and the like. Then, for example, the left and right tail light units 10 are arranged on both sides of the tail gate 4. The vehicle shown in FIG. 1 is an example, and the vehicle body structure and the like constituting the rear portion of the vehicle body 1 may be changed according to the type, model year, size, and the like of the vehicle type.

In this embodiment, each direction is defined based on the direction of the vehicle shown in FIG. That is, in the front-rear direction L1 of the vehicle, the front side seen from the driver is called the front, and the opposite side is called the rear. Further, in the vehicle width direction L2 of the vehicle, the right-hand side of the driver is referred to as the right side, the left-hand side is referred to as the left side, the upper side of the driver is referred to as the upper side, and the lower side is referred to as the lower side.

The left and right tail light units 10 have a symmetrical relationship, but their configurations are the same. Therefore, in the present embodiment, the left tail light unit 10 will be described in detail, and the right tail light unit 10 will be described. Omit.

As shown in FIGS. 1 and 2, the tail light unit 10 is a unit in which a main light unit 20 and a sub light unit (vehicle lamp body according to the present invention) 30 are combined.

As shown in FIGS. 1, 3 and 4, the main light unit 20 has a main bracket 11 and a main outer lens 12 combined with the main bracket 11 so as to cover the main bracket 11 from the rear side. It is equipped with a light case 13. The main outer lens 12 is made of, for example, a transparent or translucent synthetic resin. However, the material of the main outer lens 12 is not limited to this case.

As shown in FIG. 1, the main light case 13 has a front extending portion 13a extending toward the front of the vehicle body 1 along the rear fender 3 on the left side and an upward extending portion extending upward along the tailgate 4. 13b and.
Further, the main light case 13 is located on the right side of the front extending portion 13a and below the upward extending portion 13b so that a storage space 14 for combining the sub light unit 30 is secured. It is formed in a three-dimensional shape. The accommodation space 14 is a space that penetrates the main light case 13 in the front-rear direction L1 and opens to the right side.

As shown in FIGS. 3 and 4, the inside of the main light case 13, that is, the enclosed space formed between the main bracket 11 and the main outer lens 12 functions as a light chamber 15. Various light sources (not shown) are provided in the light chamber 15, and are used as light sources for various lights such as a stop light which is a braking light, a turn light which is a vehicle direction indicator light, and a backlight which is a back light. It will be used.

Therefore, the main light unit 20 of the present embodiment functions as a combination light in which, for example, a stop light, a turn light, a backlight, and the like are integrally incorporated. Further, in the illustrated example, a rod-shaped light guide 16 for guiding light emitted from light sources for various lights is provided in the light chamber 15. The light guide 16 has flexibility, for example, and is arranged so as to surround the periphery of the accommodation space 14 in a state of being supported by a bracket 17 arranged in the light chamber 15.
The light guide 16 may be a plate-shaped one. However, the light guide 16 is not essential and may not be provided.

As shown in FIGS. 1 to 4, the sub light unit 30 is integrally combined with the main light unit 20 so as to be fitted in the above-mentioned accommodation space 14.
The sub light unit 30 has a sub housing (housing according to the present invention) 40 and a sub outer lens (related to the present invention) integrally combined with the sub housing 40 so as to cover the sub housing 40 from the rear side (outside of the vehicle). The outer lens) 50 and the millimeter wave radar 60 arranged on the front side (inside the vehicle) of the sub outer lens 50 and capable of transmitting the millimeter wave M (see FIG. 5) toward the rear are provided.

Like the main outer lens 12, the sub outer lens 50 is made of, for example, a transparent or translucent synthetic resin. However, the material of the sub outer lens 50 is not limited to this case. In particular, the sub-outer lens 50 is capable of emitting light by the light O2 from the second light source 71, which will be described later, and at the same time, guiding the light O2 and emitting it toward the rear, and also from the millimeter-wave radar 60. It is possible to transmit the transmitted millimeter wave M.

The sub-outer lens 50 includes a lens body 51 that bulges rearward and a flange portion 55 that is integrally formed with the lens body 51.

The lens body 51 is connected to a rectangular top lens 52 that is longer in the vehicle width direction L2 than the vertical direction L3 when viewed from the rear side of the vehicle, and is connected to the top lens 52 and is forward from the outer peripheral edge portion of the top lens 52. It is provided with four side lenses 53 protruding toward the surface, and is formed in a substantially rectangular cuboid shape as a whole.

The right side lens 53a located on the right side of the four side lenses 53 is formed to be thicker than the thickness of the top lens 52, for example, and is connected to the top lens 52 so that the angle formed with the top lens 52 is an acute angle. It is set up.
The thickness of the right side lens 53a does not need to be thicker than that of the top lens 52, and may be changed as appropriate. However, in the present embodiment, as will be described later, it is possible to guide the light O1 emitted from the first light source 70 into the right side lens 53a and then emit it rearward. When the light O1 is guided in this way, it is preferable that the right side lens 53a has a thick wall shape.

The left side lens 53b located on the left side of the four side lenses 53 is formed to have the same thickness as the top lens 52, for example, and is connected to the top lens 52 so as to form an obtuse angle with the top lens 52. ing. The thickness of the left side lens 53b does not have to be the same as the thickness of the top lens 52, and may be changed as appropriate.
In particular, the connecting portion between the left side lens 53b and the top lens 52 is formed in a curved surface shape, and functions as a reflecting portion 54 that reflects the light O2 emitted from the second light source 71, which will be described later, to guide the light O2 to the top lens 52 side. do.

Of the four side lenses 53, the upper side lens 53c located on the upper side and the lower side lens 53d located on the lower side are formed to have the same thickness as, for example, the top lens 52. The thicknesses of the upper side lens 53c and the lower side lens 53d do not have to be formed to be the same as the thickness of the top lens 52, and may be changed as appropriate.
The flange portion 55 is integrally connected to the four side lenses 53, and is formed so as to surround the periphery of the lens body 51 and project in the vertical direction L3 and the vehicle width direction L2.

The sub-housing 40 is arranged on the front side of the sub-outer lens 50 and is integrally combined with the flange portion 55 of the sub-outer lens 50. A part of the sub-housing 40 is a bulging portion 41 that bulges toward the rear side and enters the lens body 51 of the sub-outer lens 50.
Specifically, the bulging portion 41 enters the lens body 51 so as to be close to or in contact with the top lens 52, a part of the left side lens 53b, the upper side lens 53c, and the lower side lens 53d. There is. As a result, the sub-outer lens 50 and the bulging portion 41 are combined in a state of being overlapped with each other in the front-rear direction L1.

The portion of the sub-housing 40 excluding the bulging portion 41 is more than the front end portion of the side lens 53 (right side lens 53a, left side lens 53b, upper side lens 53c and lower side lens 53d) of the sub outer lens 50. It is connected to the flange portion 55 of the sub-outer lens 50 in a state of being arranged on the front side. As a result, a closed space that functions as a light chamber 56 is formed between the sub-outer lens 50 and the sub-flange. The light chamber 56 is widely formed in the peripheral portion of the front end portion of the side lens 53.

Further, in the portion of the bulging portion 41 of the sub-housing 40 facing the top lens 52 of the sub-outer lens 50, a radar mounting hole 57 is formed so as to penetrate the bulging portion 41 in the front-rear direction L1. At the same time, an annular seal frame 58 projecting forward is formed so as to surround the opening of the radar mounting hole 57.
Further, in the portion of the bulging portion 41 facing the top lens 52 of the sub outer lens 50, as shown in FIGS. 4 and 6, a plurality of boss portions 59 projecting forward are formed. The boss portion 59 is arranged between the seal frame 58 and the opening of the radar mounting hole 57, and is formed so as to project forward from the seal frame 58. In the present embodiment, four are formed corresponding to the number of insertion holes 64a described later, and are arranged at intervals in the vehicle width direction L2 and the vertical direction L3. The boss portion 59 is formed with a connecting screw hole 59a that opens forward.

As shown in FIGS. 3 and 4, a light source that emits light toward the rear is arranged in the light chamber 56. In the present embodiment, two light sources, a first light source 70 and a second light source 71, are arranged in the light chamber 56. Examples of the first light source 70 and the second light source 71 include, but are not limited to, LEDs and the like. Further, the number and arrangement of light sources may be changed as appropriate.

The first light source 70 is arranged in front of the front end portion of the right side lens 53a in the light chamber 56, and is mounted on the first control board 72 supported by a support member (not shown). The second light source 71 is arranged in front of the front end portion of the left side lens 53b in the light chamber 56, and is mounted on the second control board 73 supported by a support member (not shown).

Since the first light source 70 and the second light source 71 are arranged as described above, as shown in FIG. 5, the light O1 emitted from the first light source 70 is incident on the right side lens 53a and is the second light source. The light O2 emitted from the 71 is incident on the left side lens 53b.
The light O1 emitted from the first light source 70 and incident on the right side lens 53a is guided along the right side lens 53a, passes through the connection portion between the right side lens 53a and the top lens 52, and then rearward. It is emitted toward. Therefore, the light O1 from the first light source 70 can be emitted backward through the sub-outer lens 50 while maintaining the light intensity at the time of emission.

On the other hand, the light O2 emitted from the second light source 71 and incident on the left side lens 53b is guided along the left side lens 53b to the connection portion between the left side lens 53b and the top lens 52. It is mainly reflected by the formed curved reflecting portion 54. As a result, the light O2 reflected by the reflecting unit 54 is guided into the top lens 52 and travels in the top lens 52 while being repeatedly reflected in the top lens 52. As a result, the top lens 52 of the sub-outer lens 50 can be mainly emitted by using the light O2 mainly from the second light source 71.

Further, as shown in FIGS. 3 and 4, the light guided into the top lens 52 is directed to the front surface (inner surface according to the present invention) of the top lens 52 of the sub-outer lens 50 facing the millimeter wave radar 60 side. A rough surface portion 75 that emits O2 rearward in a predetermined light emission pattern is formed.
Specifically, the rough surface portion 75 is formed in a portion of the front surface of the top lens 52 located inside the radar mounting hole 57 formed in the sub-housing 40 in a predetermined forming pattern. The rough surface portion 75 is a portion whose surface roughness is formed to be coarser than other portions by fine cutting processing, surface treatment processing, etc., and in the illustrated example, a plurality of convex portions 76 protruding forward in a mountain shape. It is composed of.
The distance between adjacent convex portions 76 is, for example, several μm to several tens of μm, but in each drawing, each convex portion 76 is emphasized for easy viewing.

As described above, since the rough surface portion 75 is formed on the front surface of the top lens 52, as shown in FIG. 5, the light O2 guided into the top lens 52 is used by using the inclined surface of each convex portion 76 or the like. It is possible to reflect the light and emit it toward the rear side.
From the above, the light from the second light source 71 can be used to mainly emit the top lens 52 itself, and the light is guided into the top lens 52 based on the formation pattern of the rough surface portion 75. It is possible to emit light O2 toward the rear in a predetermined light emission pattern.

The first light source 70 and the second light source 71 are used as various light sources for lighting, for example, a light source for a position light which is a side light, a light source for a stop light, a light source for a tail light, and the like. However, it is not limited to these cases.

As shown in FIGS. 3 and 4, the millimeter wave radar 60 includes a radar body 61 that transmits and receives millimeter waves M, and a radar bracket 62 that supports the radar body 61.
The radar main body 61 has a transmission antenna (not shown) that transmits millimeter wave M, a reception antenna (not shown) that receives millimeter wave M reflected by a detection object, and a signal of the transmitted millimeter wave M and a signal of the received millimeter wave M. It mainly has an internal signal generation unit (not shown) that generates a detection signal based on the above. This makes it possible to detect, for example, the distance between the object to be detected and the like based on the detection signal generated by the signal generation unit.

The radar bracket 62 includes a bottomed cylindrical bracket body 63 that surrounds the periphery of the radar body 61, and a flange piece 64 that is integrally formed with the bracket body 63.
The flange piece 64 is formed in an annular shape in the vehicle width direction L2 and the vertical direction L3 so as to surround the periphery of the bracket main body 63. As shown in FIGS. 6, 7, and 8, the flange piece 64 is formed with a plurality of insertion holes 64a for inserting the connecting screw 65.

In the present embodiment, four insertion holes 64a are formed at intervals in the vertical direction L3 and the vehicle width direction L2. More specifically, the four insertion holes 64a are separated from the center line X penetrating the center of the radar body 61 in the thickness direction by the same distance D1 in the vertical direction L3 in a plan view of the radar body 61 when viewed from the thickness direction. In addition, they are formed at positions separated from the center line X by the same distance D2 in the vehicle width direction L2. The four boss portions 59 on the sub-housing side described above are formed so as to correspond to the front-rear direction L1 with respect to each insertion hole 64a.

As shown in FIGS. 3 and 4, the millimeter-wave radar 60 configured in this way is held in the sub-housing 40 in a state of being combined from the front with respect to the sub-housing 40, and at least a part thereof is outside the light chamber 56. It is exposed to.
Specifically, the millimeter-wave radar 60 is arranged in the bulging portion 41 of the sub-housing 40, and is combined with the sub-housing 40 so that the bracket main body 63 and the radar main body 61 enter the radar mounting hole 57 from the front side. ing. At this time, the flange piece 64 comes into contact with the boss portion 59 formed in the sub-housing 40 from the front, so that the entire millimeter-wave radar 60 is positioned. At the time of positioning, the four insertion holes 64a formed in the flange piece 64 are arranged so as to face the connecting screw holes 59a formed in the boss portion 59 and are arranged in the connecting screw holes 59a as shown in FIG. It is said to be in communication.

Then, the millimeter wave radar 60 is integrally combined with the sub-housing 40 by the connecting screw 65 screwed into the connecting screw hole 59a through each insertion hole 64a. In particular, as described above, since the four insertion holes 64a are formed at the same distance and away from the center line X of the radar body 61 in the vertical direction L3 and the vehicle width direction L2, for example, a millimeter wave radar. Even when the 60 is rotated 180 degrees around the center line X, the insertion hole 64a and the connecting screw hole 59a are opposed to each other. Therefore, the millimeter-wave radar 60 can be attached regardless of the left-right orientation, and the workability associated with the attachment / detachment of the millimeter-wave radar 60 can be improved.

Since the millimeter-wave radar 60 is attached as described above, the radar bracket 62 side can be exposed to the outside of the light chamber 56 as shown in FIGS. 3 and 4. Further, only the sub-outer lens 50 is arranged behind the radar main body 61. Further, the radar main body 61 is arranged in a state of being hidden behind the rough surface portion 75. A gap is secured between the rough surface portion 75 and the radar main body 61.

Further, in the present embodiment, as shown in FIGS. 3, 4 and 6, there is a light chamber between the millimeter wave radar 60 and the sub-housing 40 through a gap between the millimeter-wave radar 60 and the sub-housing 40. A seal member 68 is provided to block communication between the inside and the outside of the 56.
The seal member 68 is formed, for example, in the shape of a square ring surrounding the bracket main body 63 of the radar bracket 62 and in a thin seal shape, and is elastically deformable in the thickness direction. Specifically, the seal member 68 is formed in an annular shape corresponding to the shape of the seal frame 58 formed on the sub-housing 40 side. The seal member 68 is arranged so as to be sandwiched between the seal frame 58 and the flange piece 64, and is attached in a compressed state as the connecting screw 65 is tightened.

As a result, the seal member 68 blocks communication between the inside and the outside of the light chamber 56 through the gap between the millimeter wave radar 60 and the sub-housing 40. Therefore, it is possible to keep the inside of the light chamber 56 in a sealed state with the installation of the millimeter wave radar 60.
The type and material of the seal member 68 are not particularly limited. For example, as the seal member 68, a seal ring, a seal packing, a gasket, or the like made of rubber (for example, nitrile rubber, silicon rubber, fluororubber, butyl rubber, urethane rubber, etc.) or synthetic resin can be adopted.

(Action of sublight unit)
Next, among the tail light units 10 configured as described above, the operation of the sub light unit 30 will be mainly described below.
According to the sub light unit 30 of the present embodiment, as shown in FIG. 5, the millimeter wave M transmitted from the millimeter wave radar 60 is transmitted toward the rear outside the vehicle after being transmitted through the sub outer lens 50. be able to. At this time, unlike the conventional case, the millimeter wave M can be transmitted backward only by transmitting only one sub-outer lens 50, so that the attenuation of the millimeter wave M can be suppressed. Therefore, the radar performance can be improved.

Further, in the sub-outer lens 50, the top lens 52 itself emits light mainly by the light O2 from the second light source 71, and the light O2 guided into the top lens 52 is moved backward by using the rough surface portion 75. It can be emitted with a predetermined light emission pattern. Therefore, the millimeter wave radar 60 can be obscured from the outside through the sub outer lens 50 by utilizing the light emission of the sub outer lens 50 itself and the light O2 emitted from the sub outer lens 50, and the existence of the millimeter wave radar 60. Can be hidden.
Therefore, it is possible to provide an appearance that does not give a sense of discomfort, and it is possible to secure the design and design of the sub light unit 30.

Further, since it is possible to secure the design by making the millimeter wave radar 60 inconspicuous and to transmit the millimeter wave M with suppressed attenuation with one sub-outer lens 50, compared with the conventional case. It is possible to reduce the number of parts and reduce the cost.
Further, since the sub-outer lens 50 can emit the light O2 from the second light source 71 in a predetermined light emission pattern, it can be appropriately used as light for, for example, a position light, a stop light, or a tail light. It is also possible to do. In particular, since the light O1 from the first light source 70 can be emitted rearward through the sub-outer lens 50 while maintaining the light intensity, it is possible to sufficiently satisfy the prescribed requirements for the light. ..

Further, since the millimeter wave radar 60 is combined with the sub-housing 40 in a state where the radar bracket 62 is exposed to the outside of the light chamber 56, the heat dissipation of the millimeter wave radar 60 can be improved. Therefore, the heat generated by the operation of the millimeter wave radar 60 can be efficiently dissipated, and the stability of the operation can be appropriately maintained. Therefore, the radar performance can be stably maintained.
The radar bracket 62 is preferably made of a metal such as aluminum. In this case, the heat dissipation can be further improved. Further, when the radar bracket 62 is made of metal, it is more preferable to form, for example, a plurality of heat radiation fins.

Further, since the seal member 68 can be used to block the communication between the inside and the outside of the light chamber 56 through the gap between the millimeter wave radar 60 and the sub-housing 40, the airtightness inside the light chamber 56 can be improved. It can be secured appropriately. Therefore, it is possible to prevent dust, moisture, and the like from entering the lighting chamber 56, and it is possible to ensure the reliability of the lamp body function.

Further, since the millimeter wave radar 60 is combined with respect to the sub housing 40 from the front inside the vehicle, the millimeter wave radar 60 can be easily removed from the sub housing 40. Therefore, for example, the millimeter-wave radar 60 can be easily maintained or replaced, the workability thereof can be improved, and the cost associated with the work can be suppressed. This can lead to improvement of serviceability.
In particular, when the millimeter-wave radar 60 is attached, it can be attached without worrying about the left-right orientation of the millimeter-wave radar 60 as described above, so that the workability associated with attachment / detachment can be further improved. ..

As described above, according to the sublight unit 30 of the present embodiment, it is possible to improve heat dissipation and serviceability, and at the same time, make the millimeter wave radar 60 difficult to see from the outside and provide good design. Can be done. In addition, millimeter wave M can be transmitted while suppressing attenuation, and radar performance can be improved.

Further, since the rough surface portion 75 faces the millimeter wave radar 60 side, for example, dust and moisture from the outside are less likely to adhere to the rough surface portion 75, and the rough surface portion 75 can be kept clean. Therefore, the radar performance can be stably maintained for a long period of time, and the light O2 from the second light source 71 can be appropriately emitted in a predetermined light emission pattern.

Although the embodiments of the present invention have been described above, these embodiments are presented as examples and are not intended to limit the scope of the invention. The embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the gist of the invention. Examples of embodiments and variations thereof include those easily conceivable by those skilled in the art, substantially the same, and those having an equal range.

For example, in the above embodiment, the case where the vehicle lamp body according to the present invention is applied to the sub light unit 30 constituting the tail light unit 10 provided at the rear of the vehicle has been described as an example. Not limited. For example, it may be applied in combination with a headlight which is a headlight provided at the front of the vehicle. In this case, the millimeter wave M can be used to detect the distance to the vehicle in front, which can be applied to forward monitoring and the like.

Further, in the above embodiment, the sub-outer lens 50 is made to emit light by using the light O2 from the second light source 71, and the light O2 guided into the sub-outer lens 50 by using the rough surface portion 75 is a predetermined pattern. The millimeter-wave radar 60 is configured to be difficult to see from the outside by injecting the light source in, but the present invention is not limited to this case. For example, the sub-outer lens 50 may be a simple transparent member that does not have a light guide function.
In this case, for example, a light guide member may be arranged between the sub outer lens 50 and the millimeter wave radar 60 to make the millimeter wave radar 60 difficult to see.
However, when configured as in the above embodiment, the millimeter wave radar 60 can be made difficult to see from the outside to ensure good design, and the attenuation of the millimeter wave M can be suppressed to improve the radar performance. It is more preferable because it can improve heat dissipation and serviceability.

Further, in the above embodiment, the boss portion 59 is formed so as to be arranged between the seal frame 58 and the radar mounting hole 57, but the present invention is not limited to this case, and the seal is not limited to this case, for example, as shown in FIG. The boss portion 59 may be arranged on the outside of the frame 58. In this case, since the seal member 68 can be arranged closer to the radar mounting hole 57 than the insertion hole 64a formed in the flange piece 64, the airtightness in the light chamber 56 can be further improved.

Further, in the above embodiment, the seal member 68 is sandwiched between the seal frame 58 and the flange piece 64 in a compressed state, but the present invention is not limited to this case. For example, as shown in FIG. 10, instead of the seal frame 58, an annular seal wall portion 69 surrounding the periphery of the radar main body 61 is formed so as to extend from the flange piece 64 toward the sub-housing 40 side. Then, the seal member 68 may be arranged so as to be fitted inside the seal wall portion 69, and the seal member 68 may be sandwiched between the seal wall portion 69 and the boss portion 59. Even in this case, the same effect can be achieved.

Further, in the above embodiment, the case where the rough surface portion 75 is formed by using the plurality of convex portions 76 has been described as an example, but the present invention is not limited to this case. For example, the rough surface portion 75 may be formed by forming a plurality of concave portions (for example, valley-shaped, hemispherical, etc.) recessed toward the rear, which is the outside of the vehicle, on the front surface of the top lens 52, or a plurality of convex portions. The rough surface portion 75 may be formed by using both the portion 76 and the plurality of recesses. Even in these cases, the light distribution can be controlled in the same manner as in the case of forming the rough surface portion 75 by using the convex portion 76, and the desired light emission pattern can be easily and easily obtained. Can be successful.

M ... Millimeter wave 30 ... Sublight unit (vehicle light body)
40 ... Sub-housing (housing)
50 ... Sub outer lens (light guide lens)
56 ... Light room 60 ... Millimeter wave radar 68 ... Seal member 70 ... First light source 71 ... Second light source 75 ... Rough surface part 76 ... Convex part

Claims (4)

With the housing
An outer lens that is combined with the housing so as to cover the housing from the outside of the vehicle and forms a light chamber between the housing and the housing.
It is equipped with a millimeter-wave radar that is located inside the vehicle from the outer lens and can transmit millimeter waves toward the outside of the vehicle.
The outer lens is made capable of transmitting the millimeter wave.
The millimeter-wave radar is held in the housing in a state of being combined with the housing from the inside of the vehicle, and at least a part thereof is exposed to the outside of the light room.
A seal member is provided between the millimeter wave radar and the housing to block communication between the inside and the outside of the lamp chamber through the gap between the millimeter wave radar and the housing .
In the portion of the housing facing the outer lens, a radar mounting hole is formed so as to penetrate the housing in the front-rear direction of the vehicle, and an annular seal is formed so as to surround the opening of the radar mounting hole. The frame is formed,
The millimeter wave radar is
The radar body that transmits and receives the millimeter wave and
A bracket body that surrounds the periphery of the radar body, and a radar bracket that has a flange piece integrally formed with the bracket body and supports the radar body.
A vehicle lamp body , wherein the seal member is arranged in an annular shape between the seal frame and the flange piece, and is attached in a compressed state in the front-rear direction of the vehicle. In the vehicle lamp body according to claim 1,
A light source is provided in the lighting chamber.
The outer lens emits light by light from the light source, and at the same time, guides the light so that it can be emitted to the outside of the vehicle.
A vehicle lamp body having a rough surface portion formed on the outer lens to emit the guided light in a predetermined light emission pattern. In the vehicle lamp body according to claim 2,
The rough surface portion is a vehicle lamp body formed on the inner surface of the outer lens facing the millimeter wave radar side. In the vehicle lamp body according to claim 3,
The rough surface portion has at least one of a plurality of protrusions protruding toward the millimeter wave radar side and a plurality of recesses recessed toward the outside of the vehicle, whereby the outer lens is outside the vehicle. The surface roughness is formed to be rougher than the outer surface facing
A vehicle lamp body in which the plurality of protrusions and the plurality of recesses reflect the light guided into the outer lens to be emitted to the outside of the vehicle in the light emission pattern.

Images