JP6428078B2 - Head-up display device for vehicle - Google Patents

Description

  The present invention relates to a vehicle head-up display device.

  Conventionally, there are laser scanners provided with a laser light source in a housing, in which a fan is provided in the housing. In this laser scanner, the wind from the fan is blown to a light transmitting window provided in the housing to reduce the humidity near the light transmitting window. Thereby, the cloudiness of the translucent window can be eliminated. For example, a laser scanner described in Patent Document 1.

JP-A-5-28295

  The present inventors tried to apply the laser scanner to a vehicle head-up display device. As a result, the present inventors have found that the laser light source of the vehicle head-up display device needs to emit high output light. Therefore, it is necessary to flow a large current to the light source, and the temperature of the light source becomes high as time passes. When the light source becomes high temperature, it becomes difficult to irradiate high-power light, so it is necessary to cool the light source. Therefore, the inventors tried to provide a cooling device for cooling the light source in the laser scanner.

  As a result, the housing is cooled as the light source cools by the cooling device. As the housing is cooled, the light transmission window is cooled, and water droplets are generated in the light transmission window. Then, if water droplets are generated in the light transmission window, it becomes difficult for the passenger to visually recognize the light emitted from the light source as a virtual image. Therefore, it is desired to eliminate the water droplets, but the present inventors have found that it is difficult to eliminate the water droplets only with the wind from the fan.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a vehicle head-up display device that can prevent an occupant from visually recognizing light emitted from a light source as a virtual image due to water droplets generated in a translucent window. It is to be.

In order to achieve the above object, in the first aspect of the present disclosure, the vehicle head-up display device is a vehicle head-up display device that reflects light to a windshield or a combiner and visually recognizes a virtual image to an occupant. A sealed housing, a light source provided in the housing for irradiating light, a cooling device for cooling the light source, and light provided from the light source directed from the inside of the housing to the outside of the housing A translucent window that passes through the inner wall of the housing, and a metal portion is provided on a side wall in which the translucent window is provided, in a downward region that is a gravitational direction from the translucent window. And
Further, in the second aspect of the present disclosure, the vehicle head-up display device is a vehicle head-up display device that reflects light to a windshield or a combiner to visually recognize a virtual image to an occupant, and includes a sealed housing and A light source provided in the housing for irradiating light, a cooling device for cooling the light source, and a light transmitting window provided in the housing for transmitting light emitted from the light source from the inside of the housing toward the outside of the housing The metal part is provided in the whole surface of the bottom wall in which the cooling device is provided among the inner walls of the housing.
Further, in the third aspect of the present disclosure, the vehicle head-up display device is a vehicle head-up display device that reflects light to a windshield or a combiner and visually recognizes a virtual image to an occupant, and includes a sealed housing and A light source provided in the housing for irradiating light, a cooling device for cooling the light source, and a light transmitting window provided in the housing for transmitting light emitted from the light source from the inside of the housing toward the outside of the housing The metal part is provided along the bottom wall in which the cooling device is provided among the inner walls of the housing, and the metal part is in contact with the cooling device from the direction along the bottom wall. .

According to the first aspect of the present disclosure, when the cooling device cools the light source, the metal part that is more likely to transmit heat than the translucent window is rapidly cooled, and the temperature of the metal part becomes the temperature of the translucent window. Compared to the dew point temperature first. For this reason, water droplets are first generated in the metal part , and the amount of water vapor in the vicinity of the metal part is reduced. Therefore, even if the temperature of the translucent window is lower than the dew point temperature before the water droplet is generated on the metal portion after the water droplet is generated on the metal portion, the occurrence of the water droplet on the translucent window is suppressed in the first place. I can do it. Further, the side wall provided with the light-transmitting window is provided with a metal part in the downward region, so that even if condensation occurs on the metal part, the condensed water is prevented from being applied to the light-transmitting window. Can do.
According to the second aspect of the present disclosure, since the metal portion is provided on the entire bottom wall where the cooling device is provided, the amount of water vapor in the housing is easily reduced.
According to the third aspect of the present disclosure, since the metal portion is in contact with the cooling device, when the light source is cooled by the cooling device, the metal portion is also cooled, and condensation can be easily generated in the metal portion. .

It is a figure which shows a mode that the vehicle head-up display apparatus in 1st Embodiment is provided in a vehicle. It is the figure which looked at a part including a light source of a head up display device for vehicles in a 1st embodiment from the side. It is the figure which looked at part including the light source of the head-up display device for vehicles in a 2nd embodiment from the side. It is the 1st example which looked at a part including a light source of a head up display device for vehicles in other embodiments from the side. It is the 2nd example which looked at a part including a light source of a head up display device for vehicles in other embodiments from the side.

  Hereinafter, a plurality of modes for carrying out the invention will be described with reference to the drawings. In each embodiment, portions corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals and redundant description may be omitted. In each embodiment, when only a part of the configuration is described, the other configurations described above can be applied to other portions of the configuration.

(First embodiment)
As shown in FIG. 1, a vehicle head-up display device 2 (hereinafter referred to as “HUD2”) in the present embodiment is provided in a vehicle 80. HUD 2 is housed in the instrument panel of vehicle 80.

  The HUD 2 includes a projector 20, a reflecting mirror 21, and a concave mirror 22. The projector 20 irradiates the reflecting mirror 21 with the image as light 2021. The reflecting mirror 21 reflects the light 2021 emitted from the projector 20 toward the concave mirror 22. The concave mirror 22 reflects the light 2021 reflected from the reflecting mirror 21 toward the windshield 70. The windshield 70 reflects the light 2021 reflected from the concave mirror 22 toward the occupant 90. Then, the occupant 90 visually recognizes the light 2021 reflected from the windshield 70 as the virtual image 23. That is, the HUD 2 displays the light 2021 as the virtual image 23 so that the occupant 90 can visually recognize it.

  In the present embodiment, the direction of gravity when the vehicle 80 is located on the horizontal ground is the downward direction, and the opposite side of the downward direction is the upward direction. The projector 20 is arranged in a state where the bottom wall 2001 of the projector 20 makes a predetermined inclination with respect to the horizontal direction. In order to arrange the projector 20 in this way, the projector 20 irradiates light in an upward oblique direction. Further, the surface of the reflecting mirror 21 on which the light 2021 is reflected is directed in a downward diagonal direction. Therefore, even if sunlight enters from the windshield 70, the sunlight can be prevented from being reflected by the concave mirror 22 and the reflecting mirror 21 and reflected by the occupant 90.

  As shown in FIG. 2, the projector 20 includes a housing 201 whose inside is kept hermetically sealed by a seal member 209. The projector 20 includes a light source 202, a Peltier element 204, fins 205, a light transmission window 206, and a heat transfer holder 208.

  A cavity is previously opened in the bottom wall 2001 of the housing 201, and the Peltier element 204 is provided so as to be fitted into the cavity. The Peltier element 204 includes a heat absorbing surface 2041 that is a surface in the inner direction of the housing 201. The Peltier element 204 includes a heat generating surface 2042 that is a surface opposite to the heat absorbing surface 2041. The heat transfer holder 208 is provided on the heat absorption surface 2041. The heat generating surface 2042 is provided with heat dissipating fins 205. The light source 202 is held on the surface of the heat transfer holder 208 opposite to the surface in contact with the heat absorbing surface 2041. The housing 201 is made of resin or the like.

  In addition, a cavity is previously opened in the side wall 2002 of the housing 201 in the direction in which the light 2021 is emitted from the light source 202. A translucent window 206 is provided so as to be fitted into the cavity.

  The light source 202 is composed of a laser diode or the like. The light source 202 is supplied with a current from a battery (not shown), and irradiates light 2021 toward the light transmission window 206. The irradiated light 2021 is transmitted through the light transmission window 206 and then reflected by the reflecting mirror 21 and the like, and is visually recognized by the passenger 90 as the virtual image 23.

  When a current is supplied to the Peltier element 204 from a battery (not shown), the temperature of the heat absorbing surface 2041 decreases. When the current is supplied from the battery to the Peltier element 204, the temperature of the heat generating surface 2042 rises.

  The heat transfer holder 208 is made of a material such as aluminum metal. The heat transfer holder 208 holds the light source 202. The heat transfer holder 208 is in contact with the heat absorption surface 2041 of the Peltier element 204. Therefore, when a current is generated in the Peltier element 204, the light source 202 is cooled via the heat transfer holder 208.

  A metal part 2012 is provided on the inner surface of the bottom wall 2001 of the housing 201. The metal part 2012 is provided on the entire surface of the bottom wall 2001. The metal part 2012 is made of aluminum or the like. The metal part 2012 provided on the bottom wall 2001 and the heat absorbing surface 2041 of the Peltier element 204 are in contact with each other. Therefore, when the Peltier element 204 starts cooling the light source 202, heat is immediately transmitted to the metal part 2012 provided on the bottom wall 2001. Therefore, when the Peltier element 204 starts cooling the light source 202, the metal part 2012 provided on the bottom wall 2001 is rapidly cooled.

  As a result, compared with the temperature of the translucent window 206, the temperature of the metal part 2012 falls below the dew point temperature first. Then, water droplets are generated on the metal part 2012.

  A metal part 2012 is provided on the inner surface of the side wall 2002 of the housing 201. Specifically, the metal portion 2012 is provided in a region below the translucent window 206 on the side wall 2002. For this reason, even if water droplets are generated in the metal part 2012, it is possible to prevent the water droplets from dripping onto the light transmitting window 206.

  Further, the metal part 2012 provided on the side wall 2002 and the translucent window 206 are not in contact with each other. Therefore, the heat of the metal part 2012 cooled by the Peltier element 204 is not directly transmitted to the light transmission window 206. Accordingly, it is possible to suppress the temperature of the light transmission window 206 from being lowered due to the cooling of the light source 202 performed by the Peltier element 204.

  The hygroscopic agent 2013 is disposed on the metal part 2012 of the bottom wall 2001. The hygroscopic agent 2013 is provided between the translucent window 206 and the light source 202. Therefore, water droplets generated on the metal part 2012 between the light transmission window 206 and the light source 202 are absorbed by the moisture absorbent 2013. Therefore, it is possible to prevent water droplets generated on the metal part 2012 between the light transmission window 206 and the light source 202 from coming into contact with the light source 202.

  Hereinafter, the effect of the HUD 2 of the present embodiment will be described.

  The HUD 2 reflects the light 2021 by the windshield 70 and causes the occupant 90 to visually recognize the virtual image 23. The HUD 2 includes a sealed housing 201. The housing 201 is provided with a light source 202, a Peltier element 204, and a translucent window 206. The light source 202 emits light 2021. The Peltier element 204 cools the light source 202. The translucent window 206 transmits light 2021 emitted from the light source 202 from the inside of the housing 201 toward the outside of the housing 201. A metal part 2012 is provided on the inner wall of the housing 201.

  In this way, when the Peltier element 204 cools the light source 202, the metal part 2012 that is more likely to transmit heat than the translucent window 206 is rapidly cooled. Therefore, the temperature of the metal part 2012 is first lower than the dew point temperature compared to the temperature of the translucent window 206. Accordingly, water droplets are first generated on the metal part 2012, and the amount of water vapor in the housing 201 is reduced. As a result, after water droplets are generated on the metal part 2012, even if the temperature of the light transmission window 206 is lower than the dew point temperature before the water droplets are generated on the metal part 2012, water droplets are generated on the light transmission window 206. Can be suppressed in the first place.

  Further, the metal part 2012 and the Peltier element 204 are in contact with each other.

  In this way, the heat of the Peltier element 204 is directly transmitted to the metal part 2012. Therefore, when the Peltier element 204 cools the light source 202, the metal part 2012 is rapidly cooled. Therefore, the temperature of the metal part 2012 is first lower than the dew point temperature as compared with the temperature of the light transmission window 206, water droplets are first generated on the metal part 2012, and the amount of water vapor in the housing 201 is reduced. From the above, even when water droplets are generated in the metal part 2012, even if the temperature of the light transmission window 206 is lower than the dew point temperature before the water droplets are generated in the metal part 2012, water droplets are generated in the light transmission window 206. It can be suppressed in the first place.

  In addition, the metal part 2012 is provided on the gravity direction side as compared to the light transmission window 206.

  Contrary to the configuration of the present embodiment, when the metal part 2012 is provided in the upward region opposite to the gravitational direction from the translucent window 206, water droplets generated on the metal part 2012 hang down on the translucent window 206. There is a possibility of end. On the other hand, with the above configuration, it is possible to prevent water droplets generated on the metal portion 2012 from dripping onto the light transmission window 206.

  Moreover, the metal part 2012 and the translucent window 206 are not in contact.

  In this way, the metal part 2012 cooled by the Peltier element 204 can be prevented from directly cooling the light transmitting window 206. Therefore, the light transmission window 206 is hardly cooled, and the time until the temperature of the light transmission window 206 falls below the dew point temperature becomes longer. Accordingly, water droplets are first generated on the metal part 2012, and the amount of water vapor in the housing 201 is reduced. Therefore, even if the temperature of the light transmission window 206 is lower than the dew point temperature before the water droplet is generated on the metal portion 2012 after the water droplet is generated on the metal portion 2012, the water droplet is generated on the light transmission window 206. It can be suppressed in the first place.

(Second Embodiment)
In the HUD 2 in the first embodiment, the metal part 2012 is provided on the side wall 2002 where the bottom wall 2001 of the housing 201 and the light transmission window 206 are provided. In the present embodiment, in the HUD 2, the metal part 2012 is further provided on the side wall 2002 other than the ceiling wall 2003 and the translucent window 206 of the housing 201.

  As shown in FIG. 3, in the present embodiment, a metal portion 2012 is provided on almost the entire inner wall of the housing 201. Specifically, the metal part 2012 is provided with the metal part 2012 on the entire surface of the bottom wall 2001, the side wall 2002, and the ceiling wall 2003. However, in the side wall 2002 provided with the translucent window 206, it is prohibited to provide the metal portion 2012 in a region above the translucent window 206.

  As described above, the metal portion 2012 provided on almost the entire inner wall of the housing 201 can prevent the outside air including moisture from entering from the seal member 209 or the like.

  In addition, the metal part 2012 is not provided in a region above the light transmitting window 206 in the side wall 2002 provided with the light transmitting window 206. Therefore, it is possible to prevent water droplets generated on the metal part 2012 from dripping onto the light transmission window 206.

  The hygroscopic agent 2013 is provided on the ceiling wall 2003. Further, the hygroscopic agent 2013 is provided between the translucent window 206 and the light source 202. Therefore, water droplets generated on the metal part 2012 of the ceiling wall 2003 are absorbed by the moisture absorbent 2013. Accordingly, water droplets generated on the metal part 2012 of the ceiling wall 2003 can be prevented from adhering to the light source 202.

  Hereinafter, the effect of HUD2 in this embodiment is demonstrated.

  Of the inner walls of the housing 201, the side wall 2002, the bottom wall 2001, and the ceiling wall 2003 are provided with the metal portion 2012, and the inner wall of the housing 201 in which the light-transmitting window 206 is provided. It is prohibited that the metal part 2012 is provided on the entire surface in the upward region which is the opposite direction.

  Contrary to the above configuration, there is a possibility that air containing humidity cannot be prevented from entering the housing 201 from the outside of the housing 201. Therefore, depending on the environment outside the housing 201, high-humidity air may enter the housing 201, and water droplets may be generated in the light transmission window 206. On the other hand, when the metal portion 2012 is provided on the bottom wall 2001, the side wall 2002, and the ceiling wall 2003 of the housing 201 as described above, air containing humidity may enter the housing 201 from the outside of the housing 201. The metal part 2012 can be suppressed. In addition, it is prohibited to provide the metal part 2012 in the upper region of the transparent window 206. Therefore, it is possible to prevent water droplets generated on the metal part 2012 from dripping onto the light transmission window 206. As described above, it is possible to prevent water droplets from being generated in the light transmitting window 206 while preventing air containing humidity from entering the housing 201 from the outside of the housing 201.

(Other embodiments)
The preferred embodiments of the present invention have been described above, but the present invention is not limited to the above-described embodiments, and various modifications can be made as illustrated below. Not only combinations of parts that clearly show that combinations are possible in each embodiment, but also combinations of the embodiments even if they are not explicitly stated unless there is a problem with the combination. Is also possible.

  For example, in the above embodiment, the virtual image 23 is visually recognized by the occupant 90 by reflecting the light 2021 emitted from the projector 20 to the windshield 70, but the present invention is not limited to this. A combiner may be provided separately from the windshield 70, and the occupant 90 may be caused to visually recognize the virtual image 23 by reflecting the light 2021 irradiated by the projector 20 to the combiner.

  Moreover, in the said embodiment, although the Peltier device 204 was used as a cooling device, you may make it use an air cooling type or a water cooling type cooling device instead of the Peltier device 204. FIG.

  Moreover, in the said embodiment, although the heat-transfer holder 208 and the metal part 2012 were comprised with aluminum etc., you may make it comprise with iron, copper, etc.

  Further, as shown in FIG. 4, the HUD 2 may be provided in the vehicle 80 so that the bottom wall 2001 is parallel to the horizontal direction. In this case, the second reflecting mirror 2022 is provided in the housing 201, and the translucent window 206 is provided so as to be fitted into the ceiling wall 2003.

  Further, in the side wall 2002 provided with the light transmission window 206 of the second embodiment, the metal part 2012 is completely prohibited from being provided in the region above the light transmission window 206. However, the present invention is not limited to this. Absent. In the side wall 2002 provided with the light transmission window 206, the metal portion 2012 may be provided as long as it is a part of the region above the light transmission window 206.

  Moreover, in the said embodiment, although the metal part 2012 was provided in the inner wall of the housing 201, it is not restricted to this. The metal part 2012 may be provided on the outer wall of the housing 201.

  Further, as shown in FIG. 5, the HUD 2 may be provided in the vehicle 80 so that the bottom wall 2001 is parallel to the horizontal direction. And it is provided so that it may be fitted in the ceiling wall 2003. FIG. Further, in the ceiling wall 2003, one end on the side where the translucent window 206 is provided is positioned in an upward direction compared to the other end opposite to the one end. For this reason, even if water droplets are generated on the metal part 2012 provided on the ceiling wall 2003, the metal part 2012 moves to the side opposite to the translucent window 206.

  In addition, although the metal part 2012 is not provided in the region above the translucent window 206 on the side wall 2002 of the first embodiment, the present invention is not limited to this. Specifically, the metal part 2012 may be provided in a region above the light transmitting window 206 on the side wall 2002 where the light transmitting window 206 is not provided. For example, the metal part 2012 may be provided on the side wall 2002 opposite to the side wall 2002 provided with the translucent window 206 in a region above the translucent window 206.

  2 Vehicle Head Up Display Device (HUD), 20 Projector, 2001 Bottom Wall, 2002 Side Wall, 2003 Ceiling Wall, 201 Housing, 2012 Metal Part, 2013 Hygroscopic Agent, 202 Light Source, 2021 Light, 204 Peltier Element, 205 Fin, 206 translucent window, 208 heat transfer holder, 21 reflecting mirror, 22 concave mirror, 23 virtual image, 70 windshield, 80 vehicle, 90 occupant.

Claims (4)

A vehicle head-up display device that reflects light (2021) to a windshield (70) or a combiner and makes a virtual image (23) visible to an occupant,
A sealed housing (201);
A light source (202) provided in the housing for irradiating the light;
A cooling device (204) for cooling the light source;
A translucent window (206) that is provided in the housing and transmits light emitted from the light source from the inside of the housing toward the outside of the housing;
Of the inner wall of the housing, the side wall (2002) on which the light transmission window is provided is provided with a metal part (2012) in a downward region which is a gravitational direction from the light transmission window. A vehicle head-up display device. A vehicle head-up display device that reflects light (2021) to a windshield (70) or a combiner and makes a virtual image (23) visible to an occupant,
A sealed housing (201);
A light source (202) provided in the housing for irradiating the light;
A cooling device (204) for cooling the light source;
A translucent window (206) that is provided in the housing and transmits light emitted from the light source from the inside of the housing toward the outside of the housing;
A vehicle head-up display device, wherein a metal portion (2012) is provided on an entire surface of a bottom wall (2001) on which the cooling device is provided , of an inner wall of the housing. A vehicle head-up display device that reflects light (2021) to a windshield (70) or a combiner and makes a virtual image (23) visible to an occupant,
A sealed housing (201);
A light source (202) provided in the housing for irradiating the light;
A cooling device (204) for cooling the light source;
A translucent window (206) that is provided in the housing and transmits light emitted from the light source from the inside of the housing toward the outside of the housing;
Of the inner wall of the housing, a metal part (2012) is provided along a bottom wall (2001) on which the cooling device is provided ,
The vehicle head-up display device , wherein the metal part is in contact with the cooling device from a direction along the bottom wall . The vehicle head-up display device according to claim 1, wherein the metal portion and the light-transmitting window are not in contact with each other.

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