JP6079920B2 - Image display light generation device and head-up display - Google Patents

Description

  The present invention relates to an image display device, and more particularly to an image display device used for presenting an image based on image display light to a user as a virtual image.

  An image display device called a head-up display is known and is being put into practical use in aircraft and automobiles. For example, a head-up display for a vehicle mounted on an automobile uses an optical element called a combiner that transmits light entering from outside the vehicle and reflects image display light projected from an optical unit arranged inside the vehicle. It is an image display device that displays information superimposed on the scenery. The head-up display has been attracting attention in recent years because the driver who is viewing the scenery outside the vehicle can recognize the information of the image projected from the optical unit with almost no change in line of sight and focus.

Japanese Patent Laid-Open No. 10-278629

  Some head-up displays for vehicles and the like use a reflective liquid crystal device called LCOS (Liquid crystal on silicon) for forming image display light. In such a system, the light from the light source is polarized and then incident on the reflective liquid crystal device.

  Since the reflective liquid crystal device generates image display light, from the viewpoint of suppressing the generation of noise caused by dust or dirt, the space between the polarizing element that polarizes light and the reflective liquid crystal device must be sealed. Is desirable. On the other hand, since the reflective liquid crystal device is an electronic circuit, heat is generated by energization during operation. For this reason, it is required to efficiently dissipate the heat generated by the reflective liquid crystal device.

  The present invention has been made in view of such a situation, and an object thereof is to provide a technique for achieving both dust prevention and heat dissipation of an optical component in a head-up display.

  In order to solve the above-described problems, an image display light generation device according to an aspect of the present invention includes a quarter wavelength plate that converts linearly polarized light and circularly polarized light into each other, and a circularly polarized light that has passed through the quarter wavelength plate. A metal aperture mask that includes a first opening that defines an irradiation area, and a quarter-wave plate is attached so as to cover the entire surface of one surface of the first opening, and an image to be displayed Based on the signal, the printed board includes an image display element that reflects the circularly polarized light that has passed through the aperture mask to generate image display light, and the second opening, and the aperture mask is the first of the second openings. A mounting base that is mounted so as to cover the entire surface side of the second opening, and is mounted so that the printed circuit board covers the entire second surface side of the second opening with the image display element positioned in the second opening. Including. The printed circuit board is provided with a metal layer in a region in contact with the mounting base in a region on the surface of the substrate.

  ADVANTAGE OF THE INVENTION According to this invention, the technique for making dust prevention and heat dissipation of an optical component compatible in a head-up display can be provided.

1 is a perspective view showing a head-up display that is an image display device for a vehicle according to an embodiment of the present invention, as viewed from the inside of the vehicle. It is a perspective view shown by the visual field from the windshield side about the head-up display of FIG. It is a figure which shows the internal structure of an optical unit with the path | route of light. It is a figure which shows the internal structure of an optical unit with the path | route of light. It is a figure shown about a part inside optical unit and a part inside board | substrate storage part. It is a disassembled perspective view of the image display light production | generation part which concerns on embodiment. FIG. 7A is a top view when the printed circuit board to which the image display element is attached is viewed from the incident direction of light from the light source. FIG. 7B is a side view of the printed circuit board to which the image display element is attached. It is a perspective view at the time of seeing the image display light generation part which concerns on embodiment toward the emission direction of image display light. It is a perspective view at the time of seeing the image display light production | generation part which concerns on embodiment from the incident direction of the light from a light source. It is a figure for demonstrating adjustment of the attachment position in the image display light production | generation part which concerns on embodiment.

  Embodiments of the present invention will be described below with reference to the drawings. Specific numerical values and the like shown in the embodiment are merely examples for facilitating understanding of the invention, and do not limit the present invention unless otherwise specified. In the present specification and drawings, elements having substantially the same function and configuration are denoted by the same reference numerals, and redundant description is omitted, and elements not directly related to the present invention are not illustrated. To do. The image display device according to the embodiment described below is premised on a vehicle display control device used in a vehicle, but the image display device according to the embodiment is not limited to a vehicle, and is an aircraft, a game machine, an amusement facility. Etc. can also be used.

[External Configuration of Image Display Device for Vehicle According to this Embodiment]
As an example of a vehicle image display device according to the present embodiment, a head-up display that is used by being attached to a room mirror (rear mirror) included in the vehicle will be described as an example, and an external configuration thereof will be described with reference to FIGS. 1 and 2. explain. FIG. 1 is a perspective view showing an aspect in which the head-up display 10 according to the present embodiment is observed from a field of view toward a windshield (not shown) of a vehicle from a room mirror 600 to which the head-up display 10 is attached. FIG. 2 is a perspective view showing an aspect in which the head-up display 10 is observed with a field of view from the windshield (not shown) toward the room mirror 600. In the following description, the directions indicated by front and rear, left and right, and up and down are the front and rear of the vehicle, the left and right directions of the vehicle, the direction perpendicular to the road surface on which the vehicle is disposed and the direction from the surface to the vehicle, and vice versa. Means direction.

  The head-up display 10 accommodates a circuit board 111 (shown in FIG. 5) that generates an image signal related to an image displayed as a virtual image on the combiner 400 and outputs the generated image signal to the optical unit 200. A substrate storage unit 100 is provided. The circuit board 111 can receive an image signal output from an external device such as a navigation device or a media playback device, perform a predetermined process on the input signal, and then output the signal to the optical unit 200. . The substrate storage unit 100 is connected to an attachment member (not shown) which is one of the components of the head-up display 10, and the attachment member holds the room mirror 600, so that the head-up display 10 is connected to the room mirror 600. Attached to.

  The head-up display 10 includes an optical unit 200 to which an image signal output from the circuit board 111 is input. The optical unit 200 includes an optical unit main body 210 and a projection unit 300. The optical unit main body 210 accommodates a light source 231, an image display element 240, and various optical lenses described later. The projection unit 300 houses various projection mirrors and an intermediate image screen 360 described later. The image signal output from the circuit board 111 is projected as image display light from the projection port 301 onto the combiner 400 having a concave shape through the devices of the optical unit main body 210 and the devices of the projection unit 300. In the present embodiment, a case where LCOS (Liquid crystal on silicon), which is a reflection type liquid crystal display panel, is used as the image display element 240 is illustrated, but a DMD (Digital Micromirror Device) may be used as the image display element 240. In that case, the optical system and the driving circuit according to the display element to be applied are used.

  A user who is a driver recognizes the projected image display light as a virtual image via the combiner 400. In FIG. 1, the projection unit 300 projects the image display light of the character “A” onto the combiner 400. By viewing the combiner 400, the user recognizes as if the letter “A” is displayed, for example, 1.7m to 2.0m ahead (front of the vehicle) from the user, that is, recognizes the virtual image 450. it can. Here, the central axis of the image display light projected from the projection unit 300 onto the combiner 400 is defined as a projection axis 320.

  Although details will be described later, the optical unit 200 is configured to be rotatable with respect to the substrate storage unit 100. Furthermore, in the head-up display 10 according to the present embodiment, the projection unit 300 and the combiner 400 have a configuration in which the mounting direction can be changed with respect to a predetermined surface of the optical unit main body 210 and can be detached.

[Internal Configuration of Image Display Device for Vehicle According to this Embodiment]
Next, the internal configuration of the head-up display 10 will be described. 3 and 4 are diagrams for describing the internal configuration of the optical unit 200 of the head-up display 10 described above. FIG. 3 is a diagram showing an internal configuration of the optical unit main body 210 and a part of the internal configuration of the projection unit 300 together with an optical path related to image display light. FIG. 4 is a diagram illustrating an internal configuration of the projection unit 300 and a part of the internal configuration of the optical unit main body 210 together with an optical path related to image display light projected to the combiner 400.

  First, an internal configuration of the optical unit main body 210 and an optical path related to image display light will be described with reference to FIG. The optical unit main body 210 includes a light source 231, a collimating lens 232, a UV-IR (UltraViolet-Infrared Ray) cut filter 233, a polarizer 234, a fly-eye lens 235, a reflecting mirror 236, a field lens 237, a wire grid deflecting beam splitter 238, An image display light generation unit 244, an analyzer 241, a projection lens group 242, and a heat sink 243 are provided.

  The light source 231 includes a light emitting diode that emits light of three colors of white, blue, green, and red. A heat sink 243 is attached to the light source 231 for cooling the heat generated with light emission. The light emitted from the light source 231 is converted into parallel light by the collimating lens 232. The UV-IR cut filter 233 absorbs and removes ultraviolet light and infrared light from the parallel light that has passed through the collimating lens 232. The polarizer 234 changes the light that has passed through the UV-IR cut filter 233 into linearly polarized light without any disturbance. The fly-eye lens 235 uniformly adjusts the brightness of the light that has passed through the polarizer 234. Note that the linearly polarized light that has passed through the UV-IR cut filter 233 becomes P-polarized light in relation to the incident angle to the wire grid deflection beam splitter 238.

  The reflecting mirror 236 changes the optical path of light that has passed through each cell of the fly-eye lens 235 by 90 degrees. The light reflected by the reflecting mirror 236 is collected by the field lens 237. The light collected by the field lens 237 is applied to the image display light generation unit 244 via a wire grid deflection beam splitter 238 that transmits P-polarized light.

  The image display light generation unit 244 generates image display light based on the light irradiated through the wire grid deflection beam splitter 238 and the image signal output from the circuit board 111 and emits the image display light as image display light. The image display light emitted from the image display light generation unit 244 enters the wire grid deflection beam splitter 238 again, but becomes S-polarized light in relation to the incident angle. The emitted S-polarized light is reflected by the wire grid deflection beam splitter 238, changes its optical path, passes through the analyzer 241, and then enters the projection lens group 242.

  The image display light transmitted through the projection lens group 242 exits the optical unit main body 210 and enters the projection unit 300. And the 1st projection mirror 351 with which the projection part 300 is provided changes the optical path of the image display light which entered.

  Next, an internal configuration of the projection unit 300 and an optical path related to image display light will be described with reference to FIG. The projection unit 300 includes a first projection mirror 351, a second projection mirror 352, and an intermediate image screen 360.

  As described above, the optical path of the image display light that has passed through the wire grid deflection beam splitter 238, the analyzer 241, and the projection lens group 242 included in the optical unit main body 210 is combined by the first projection mirror 351 and the second projection mirror 352. The optical path to 400 is changed. Meanwhile, a real image based on the image display light reflected by the second projection mirror 352 is formed on the intermediate image screen 360. The image display light related to the real image formed on the intermediate image screen 360 passes through the intermediate image screen 360 and is projected onto the combiner 400. As described above, the user recognizes the virtual image related to the projected image display light forward via the combiner 400.

  Next, the internal configuration of the optical unit 200 and the substrate storage unit 100 will be described with reference to FIG.

  FIG. 5 is a diagram illustrating a part of the inside of the optical unit 200 and a part of the inside of the substrate storage unit 100. In FIG. 5, the vicinity of the connection portion between the optical unit 200 and the substrate storage unit 100 is mainly shown. The optical system arrangement unit 245 included in the optical unit 200 accommodates various devices other than the heat sink 243 described above. In the optical unit 200, a heat sink 243 and a space 248 are provided in the vicinity of the connection portion of the optical system arrangement unit 245 with the substrate storage unit 100 on the substrate storage unit 100 side.

  The circuit board 111 electrically controls the image display element 240 and the light source 231 housed in the optical system arrangement unit 245. The circuit board 111 and the image display element 240 accommodated in the optical system arrangement unit 245 are connected by a flexible cable 246 that is a wiring. Here, the flexible cable 246 is an example, and a flexible board or other wiring for transmitting an electrical signal can be used. The optical unit 200 has an optical unit side opening 247 formed on one surface of the housing, and the substrate housing portion 100 has a substrate housing portion side opening 112 formed on one surface of the housing. The flexible cable 246 connects the circuit substrate 111 and the image display element 240 through the optical unit side opening 247 and the substrate storage unit side opening 112. The flexible cable 246 preferably has a length that allows the substrate storage unit 100 and the optical unit 200 to freely rotate.

  With the internal configuration as described above, the user can visually recognize a virtual image based on the image signal output from the circuit board 111 while being superimposed on an actual landscape via the combiner 400.

[Configuration and installation of image display light generator]
Next, the internal configuration and attachment of the image display light generation unit 244 according to the embodiment will be described.

  FIG. 6 is an exploded perspective view of the image display light generation unit 244 according to the embodiment. As shown in FIG. 3, the image display light generation unit 244 is installed perpendicular to the optical axis of the light emitted from the light source 231 in the optical system arrangement unit 245 in the optical unit main body 210. In the coordinate system shown in FIG. 6, the Z axis is an axis parallel to the optical axis, and a plane parallel to the XY plane formed by the X axis and the Y axis is a plane perpendicular to the optical axis. The image display light generation unit 244 is installed in parallel to the XY plane.

  The main optical members constituting the image display light generation unit 244 define a quarter-wave plate 239 that converts linearly polarized light and circularly polarized light into each other, and a circularly polarized light irradiation region that has passed through the quarter-wave plate 239. An image display element 240 that generates image display light by reflecting the circularly polarized light that has passed through the aperture mask 270 based on the image signal of the image to be displayed. The image display element 240 is provided on the printed circuit board 250.

  The aperture mask 270 includes an opening 271 for defining a light irradiation region, and the quarter wavelength plate 239 is configured to be attached so as to cover a surface on one end side of the opening 271. The aperture mask 270 is preferably made of a material that is thin but difficult to transmit light in order to allow only light passing through the opening 271 to pass therethrough and suppress light diffraction in the opening 271. Made of material. Further, in order to suppress the light reflected from the surface of the aperture mask 270 from becoming stray light, the surface of the aperture mask 270 is preferably a color having a high light absorption rate, for example, black after anodizing. It is preferable that

  The aperture mask 270 has a wave plate guide 272 for regulating the mounting position of the quarter wavelength plate 239 at a position facing the opening 271 on the surface on the side where the quarter wavelength plate 239 is mounted. The quarter-wave plate 239 is provided with a meniscus 273 along the wave-plate guide 272. After the quarter-wave plate 239 is attached to the aperture mask 270, the quarter-wave plate 239 is regulated by the wave-plate guide 272 and Z It can rotate around a rotation axis parallel to the axis.

  More specifically, the quarter wavelength plate 239 is attached to the aperture mask 270 by the attachment screw 293 in a state where the meniscus 273 is pressed by the holding spring 292. The holding spring 292 presses the quarter-wave plate 239 against the aperture mask 270 by the elastic force of the plate spring. For this reason, even after the attachment screw 293 is attached to the aperture mask 270, the quarter wavelength plate 239 is rotated within a predetermined angle range by moving the adjustment knob 274 of the quarter wavelength plate 239. be able to.

  The image display element 240 attached to the printed circuit board 250 reflects the light transmitted through the quarter wave plate 239 and generates image display light based on the image signal generated by the circuit board 111. More specifically, the image display element 240 includes red, green, and blue color filters for each pixel, and the light emitted to the image display element 240 has a color corresponding to each pixel, and image display is performed. Modulation is performed by the liquid crystal composition included in the element 240, and the light is output as S-polarized image display light in a direction reversed by 180 degrees from the incident direction. For this reason, it is important to align the quarter wavelength plate 239 and the image display element 240 so as to face each other.

  Therefore, the image display light generation unit 244 according to the embodiment includes an attachment base 260 for attaching the aperture mask 270 to which the quarter wavelength plate 239 is attached and the printed circuit board 250 to which the image display element 240 is attached. The mounting base 260 includes an opening 261 serving as an optical path. The aperture mask 270 to which the quarter wavelength plate 239 is mounted and the printed circuit board 250 to which the image display element 240 is mounted sandwich the opening 261 of the mounting base 260. It is attached in the position which opposes. More specifically, the aperture mask 270 provided with the quarter wavelength plate 239 is attached so as to cover the entire first surface which is the one end side surface of the opening 261 of the attachment base 260. The printed circuit board 250 is attached so that the image display element 240 is positioned in the opening 261 of the attachment base 260 and covers the entire second surface on the other end side of the opening 261 of the attachment base 260. Hereinafter, in this specification, the opening 271 of the aperture mask 270 may be referred to as a “first opening”, and the opening 261 of the mounting base 260 may be referred to as a “second opening”.

  The mounting base 260 also includes positioning pins 262 for restricting the mounting position of the aperture mask 270 and the printed circuit board 250. Here, the positioning pin 262 is provided so as to penetrate the mounting base 260 in a direction parallel to the optical axis. Aperture mask 270 and printed circuit board 250 are each provided with positioning holes 251 and 275 for fitting positioning pins 262, and the positions to be attached to mounting base 260 are determined by fitting positioning pins 262 into positioning holes 251 and 275. Since the positioning pin 262 for restricting the attachment position of the aperture mask 270 and the printed circuit board 250 is composed of a single member, it is possible to improve the accuracy of the attachment position.

  The aperture mask 270 is fixed to the mounting base 260 by mounting screws 294. Similarly, the printed circuit board 250 is fixed to the mounting base 260 by mounting screws 290. Thereby, the quarter wavelength plate 239 attached to the aperture mask 270 and the image display element 240 attached to the printed circuit board 250 can be easily attached to a predetermined attachment position.

  Incidentally, the image display element 240 attached to the printed circuit board 250 is an electronic circuit, and generates heat when energized. Therefore, the mounting base 260 is made of a metal material so that the heat generated by the image display element 240 is dissipated through the printed circuit board 250. More specifically, a metal layer made of a metal foil serving as a ground for the image display element 240 is formed on at least a region of the printed circuit board 250 on the surface of the substrate that comes into contact with the mounting base 260 when attached to the mounting base 260. Is provided.

  FIG. 7A is a top view when the printed circuit board 250 to which the image display element 240 is attached is viewed from the incident direction of light from the light source 231. FIG. 7B is a side view of the printed circuit board 250 to which the image display element 240 is attached.

  The image display element 240 is attached to the printed circuit board 250 according to the following process. First, an adhesive 256 is applied on the printed circuit board 250 as shown in FIG. The image display element 240 is mounted at a predetermined position on the printed circuit board 250 using the adhesive 256. When the image display element 240 is mounted on the printed circuit board 250, the image display element 240 is electrically connected to the printed circuit board 250 by wire bonding 254. Thereafter, a liquid crystal seal 253 is applied, and a counter glass 252 is attached. A protective resin 255 for protecting the last wire bonding 254 is applied. The connector 257 connects the flexible cable 246 described above with reference to FIG. 5 and transmits the image signal generated by the circuit board 111 to the image display element 240.

  As shown in FIG. 7A, the printed circuit board 250 is provided with two positioning holes 251 for restricting the position when the printed circuit board 250 is attached to the attachment base 260. By passing the positioning pin 262 through each of the positioning holes 251, the image display element 240 attached to the printed circuit board 250 can be easily attached to a predetermined attachment position of the attachment base 260.

  By the way, in general, a printed circuit board is often formed of a phenol resin or an epoxy resin. For this reason, it is possible to increase the thermal conductivity by providing a metal layer having a higher thermal conductivity than that of the above-described resin on a region in contact with the mounting base 260. In FIG. 7A, a hatched area on the surface of the printed circuit board 250 is an area that comes into contact with the mounting base 260 when mounted on the mounting base 260. The printed circuit board 250 according to the embodiment is provided with a metal layer serving as the ground of the image display element 240 in a region indicated by hatching in FIG. Since the mounting base 260 is made of a metal material, the heat of the image display element 240 can be easily dissipated, and the mounting base 260 can also function as the ground of the image display element 240.

  On the other hand, when the mounting base 260 is formed of a metal material, the light reflected on the surface of the mounting base 260 may become stray light. Therefore, as in the case of the aperture mask 270, the surface of the mounting base 260 is preferably a color having a high absorption rate in order to suppress stray light. For example, the surface of the mounting base 260 is preferably black after being subjected to an alumite treatment. .

  FIG. 8 is a perspective view when the image display light generation unit 244 according to the embodiment is viewed in the emission direction of the image display light. As shown in FIG. 8, the side on which the image display light generated by the image display element 240 is incident on the opening 261 of the attachment base 260 is attached to the attachment base 260 by attaching the printed circuit board 250 to which the image display element 240 is attached. It is blocked.

  FIG. 9 is a perspective view when the image display light generation unit 244 according to the embodiment is viewed from the incident direction of light from the light source 231. As shown in FIG. 9, the incident direction side of the light from the light source 231 in the opening 261 of the mounting base 260 is blocked by mounting the aperture mask 270 with the quarter wavelength plate 239 mounted on the mounting base 260. Can be removed. More specifically, the aperture mask 270 is fixed to the mounting base 260 by the mounting screw 294, and the quarter wavelength plate 239 is pressed against the aperture mask 270 by the elastic force of the pressing spring 292.

  As described above, the attachment base 260 attaches the quarter-wave plate 239 and the aperture mask 270 to the first surface, which is one end of the opening 261, and the printed circuit board 250 to which the image display element 240 is attached. Is attached to the second surface side, which is the surface on the other end side of the opening 261, so as to cover both ends of the opening 261. More specifically, the quarter-wave plate 239 and the aperture mask 270 are attached to the first surface that is the surface on the incident direction side of the light from the light source 231 among the surfaces of the attachment base 260. The printed circuit board 250 to which the image display element 240 is attached is attached to a second surface that is a surface on the light emission direction side of the light source 231 among the surfaces of the attachment base 260.

  Thereby, it is possible to realize a dustproof structure that suppresses dust and the like entering the opening 261 without using a dustproof component for the opening 261 of the mounting base 260. In particular, in order to suppress dust and dust from entering the opening 261, the step of attaching the quarter-wave plate 239, the aperture mask 270, and the printed circuit board 250 to the opening 261 of the attachment base 260 is performed in a clean room. Is preferred.

  Further, as described above, since the metal layer serving as the ground of the image display element 240 is provided in the region on the printed board 250 in contact with the mounting base 260, the mounting base 260 functions as the ground of the image display element 240 at the same time. It is also possible to dissipate heat from the printed circuit board 250.

  Of the quarter-wave plate 239, dust or dirt may be attached to the surface on the light incident direction side of the light source 231. However, the surface of the quarter wavelength plate 239 on the light incident direction side of the light source 231 is separated from the image display element 240 that generates image display light by at least the thickness of the mounting base 260. For this reason, dust or dirt on the surface of the ¼ wavelength plate 239 on the light incident direction side from the light source 231 is defocused and becomes inconspicuous.

  As described above, the quarter wavelength plate 239 is a device that converts linearly polarized light into circularly polarized light when linearly polarized light is incident and converts circularly polarized light into linearly polarized light when circularly polarized light is incident. . The conversion efficiency of the quarter-wave plate 239 depends on the rotation angle of the quarter-wave plate 239 with respect to the light incident on the quarter-wave plate 239. Therefore, in order to optimize the conversion efficiency of the quarter wavelength plate 239, the rotation angle of the quarter wavelength plate 239 with respect to the optical axis is adjusted.

  As shown in FIG. 9, since the quarter wave plate 239 is attached to the aperture mask 270 by the elastic force of the holding spring 292, the quarter wave plate 239 is rotated about the optical axis by moving the adjustment knob 274. Can rotate as an axis. This makes it possible to optimally adjust the conversion efficiency of the quarter-wave plate 239, for example, during assembly on the production line. Further, by fixing the quarter wave plate 239 to the aperture mask 270 after optimizing the conversion efficiency, it is possible to keep the conversion efficiency in an optimum state after the product is shipped.

  As described above, the aperture mask 270 to which the quarter wavelength plate 239 is attached is attached to one end of the opening 261 of the attachment base 260, and the printed circuit board to which the image display element 240 is attached is attached to the other end of the opening 261. Thus, alignment between the quarter-wave plate 239 and the image display element 240 can be realized. On the other hand, since the image display device according to the embodiment is a head-up display, adjustment is performed so that the image display light generated by the image display light generation unit 244 forms an image at a predetermined position on the intermediate image screen 360. The

  FIG. 10 is a diagram for explaining the adjustment of the attachment position to the optical system arrangement unit 245 in the image display light generation unit 244 according to the embodiment. As shown in FIG. 10, the attachment base 260 and the aperture mask 270 are provided with attachment holes 263 for allowing attachment screws 290 to pass. As shown in FIG. 10, the attachment holes 263 are provided at three locations, and the image display light generation unit 244 is installed in the optical system arrangement unit 245 by being screwed with three attachment screws 290.

  Here, the diameter of the mounting hole 263 serving as the screw hole of the mounting screw 290 is larger than the screw diameter of the mounting screw 290, and the clearance of the installation position of the image display light generation unit 244 is secured. More specifically, the diameter of the attachment hole 263 is 1.2 to 1.3 times the screw diameter of the attachment screw 290.

  In this way, the image display light generation unit 244 is installed in the optical system arrangement unit 245 by screwing the image display light generation unit 244 with the attachment screw 290 having a screw diameter smaller than the diameter of the attachment hole 263 by a predetermined ratio. In doing so, it is possible to slide in all directions on a plane parallel to the XY plane shown in FIG. 6, and the attachment position can be adjusted. As a result, the image display light generated by the image display light generation unit 244 forms an image at a predetermined position of the intermediate image screen 360 (for example, the central portion of the intermediate image screen 360). The installation position can be adjusted. In this sense, the attachment hole 263 and the attachment screw 290 function as an installation position adjusting unit for the attachment base 260.

  As shown in FIG. 10, the mounting base 260 and the aperture mask 270 are C-chamfered, and the area where the mounting base 260 and the aperture mask 270 come into contact with each other is smaller than before the C-chamfering is performed. ing. For this reason, when the aperture mask 270 is attached to the attachment base 260, it is possible to relieve the mechanical stress generated in both. Further, since the image display light generation unit 244 is screwed by the three attachment holes 263 provided in the attachment base 260 and the aperture mask 270, the image display light generation unit 244 is caused by distortion generated in the attachment base 260 and the aperture mask 270 due to mechanical and heat. Stress can also be suppressed.

  As described above, the head-up display according to the embodiment of the present invention provides a technique for achieving both dust prevention and heat dissipation of an optical part, and a technique that can simplify the positioning of the optical part. can do.

  In particular, by fitting the aperture mask 270 provided with the quarter wavelength plate 239 and the printed circuit board 250 provided with the image display element 240 to the positioning pins 262 provided through the mounting base 260, The quarter wavelength plate 239, the aperture mask 270, and the image display element 240 can be easily positioned and the assembly can be simplified.

  Further, the opening 261 of the mounting base 260 is closed with the aperture mask 270 provided with the quarter-wave plate 239 and the printed circuit board 250 provided with the image display element 240, so that a separate dustproof member is not attached. Can build a dust-proof structure. Furthermore, by forming the mounting base 260 from a metal material, it is possible to provide a ground for the printed circuit board 250 and efficiently dissipate the heat generated by the printed circuit board 250.

  The image display light generation unit 244 configured by mounting the quarter-wave plate 239, the aperture mask 270, and the image display element 240 to the mounting base 260 is an adjustment that allows position adjustment when mounting to the optical system placement unit 245. Clearance is provided. For this reason, the image display light generated by the image display light generation unit 244 and the intermediate image screen 360 can be easily positioned, and assembly can be simplified.

  The present invention has been described based on the embodiments. The embodiments are exemplifications, and it will be understood by those skilled in the art that various modifications can be made to combinations of the respective constituent elements and processing processes, and such modifications are within the scope of the present invention. .

  10 head-up display, 50 image presentation unit, 100 substrate storage unit, 111 circuit board, 112 substrate storage unit side opening, 200 optical unit, 210 optical unit body, 231 light source, 232 collimating lens, 233 cut filter, 233 UV- IR cut filter, 234 polarizer, 235 fly eye lens, 236 reflector, 237 field lens, 238 wire grid deflecting beam splitter, 239 1/4 wavelength plate, 240 image display element, 241 analyzer, 242 projection lens group, 243 Heat sink, 244 image display light generation unit, 245 optical system placement unit, 246 flexible cable, 247 optical unit side opening, 248 space, 250 printed circuit board, 251 Positioning hole, 252 counter glass, 253 liquid crystal seal, 254 wire bonding, 255 protective resin, 256 adhesive, 257 connector, 260 mounting base, 261 opening, 262 positioning pin, 263 mounting hole, 270 aperture mask, 271 opening, 272 Wave plate guide, 273 meniscus, 292 holding spring, 300 projection unit, 301 projection port, 320 projection axis, 351 first projection mirror, 352 second projection mirror, 360 intermediate image screen, 400 combiner, 450 virtual image, 600 room mirror.

Claims (4)

A quarter-wave plate that converts linearly polarized light and circularly polarized light into each other;
A first opening that defines an irradiation area of circularly polarized light that has passed through the quarter-wave plate; and the quarter-wave plate is attached so as to cover the entire surface of one surface of the first opening. Metal aperture mask,
A printed circuit board including an image display element that generates image display light by reflecting the circularly polarized light that has passed through the aperture mask, based on an image signal of an image to be displayed;
A second opening, wherein the aperture mask is attached so as to cover the entire first surface of the second opening, and the printed circuit board positions the image display element in the second opening. And an attachment base attached to cover the entire second surface side of the second opening.
The image display light generation device according to claim 1, wherein the printed circuit board is provided with a metal layer in a region of the substrate surface in contact with the mounting base.   The image display light generation apparatus according to claim 1, wherein the second opening is sealed between the aperture mask and the printed board.   The image display light generation device according to claim 1, wherein the metal layer is a ground of the image display element. The image display light generation device according to any one of claims 1 to 3,
A head-up display comprising: an intermediate image screen on which a real image of the image display light projected from the image display light generation device is formed.

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