JP7261980B2 - Display system and moving device - Google Patents

Description

The present disclosure relates to display systems and mobile devices.

Patent Literature 1 discloses a display device used as a head-up display. This display device includes a liquid crystal module that projects an image. This liquid crystal module includes a liquid crystal panel, a holding member for holding the liquid crystal panel from the display surface side of the liquid crystal panel, and a cushion member arranged between the peripheral portion of the liquid crystal panel and the holding member.

JP 2017-161661 A

Patent Document 1 does not disclose a member that defines the shape of light emitted from the liquid crystal panel. That is, Patent Document 1 does not describe or suggest suppressing an increase in the number of parts in a display system having a light shielding member that defines the shape of light emitted from the display surface of the display.

The present disclosure has been made in view of the above reasons, and an object thereof is to provide a display system capable of suppressing an increase in the number of parts, and a mobile device having the same.

A display system according to an aspect of the present disclosure has the following configuration. A display system includes a display, an elastic member, and a light shielding member. The display has a display surface for displaying an image. The light shielding member has an opening through which light emitted from the display surface passes. The light shielding member defines the shape of the light emitted from the display surface and sandwiches the elastic member between itself and the display. The indicator presses the elastic member against the light shielding member.

A mobile device according to an aspect of the present disclosure has the following configuration. The mobile device includes a mobile device body and the display system. The display system is mounted on the mobile device body.

A display system and a moving device according to an aspect of the present disclosure can suppress an increase in the number of parts.

FIG. 1 is a perspective view of a display system of one embodiment. FIG. 2 is a perspective view of the same display system as seen from a direction different from that of FIG. FIG. 3 is a cross-sectional view of the same display system. FIG. 4 is a conceptual diagram of a mobile device equipped with the same display system. FIG. 5 is a conceptual diagram for explaining the operation of the same display system. FIG. 6 is an exploded perspective view of the same display system. 7 is an enlarged view of a main portion of FIG. 3. FIG. FIG. 8 is a perspective view of a projection unit included in the display system; FIG. 9 is an exploded perspective view of a projection unit included in the same display system. FIG. 10 is a cross-sectional view showing an opening of the first member of the display system; FIG. 11 is a perspective view of a second member of the same display system; FIG. 12 is a front view showing an image projected by the same display system. FIG. 13 is a front view showing an image projected by the display system of the comparative example. 14A to 14C are cross-sectional views of the vicinity of the display in the display system of the modified example. FIG. 15 is an exploded perspective view of a first member and a second mirror in the same display system; FIG. 16 is a perspective view of a second member included in the display system;

(1) Embodiments (1.1) Mobile Device FIGS. 1 to 3 show a display system 1 and FIG. 4 shows a mobile device 8 with the display system 1 . The display system 1 is used as a head-up display in the mobile device 8 .

The mobile device 8 is an automobile. The mobile device 8 includes a mobile device main body 80 that constitutes the main body of the mobile device 8 and the display system 1 mounted on the mobile device main body 80 . The moving device main body 80 is a vehicle body that can move along the road surface 94 . The moving device main body 80 of this embodiment has a driver's seat 81 and a handle 82 on the right half of the moving device main body 80 .

The mobile device main body 80 has a windshield (front glass) 83 and a dashboard 84 . A dashboard 84 is positioned below the windshield 83 . The display system 1 is installed in the moving device main body 80 so as to irradiate the windshield 83 with light that forms an image 91 from below. The display system 1 of this embodiment is installed inside the dashboard 84 and positioned in front of the driver's seat 81 . As shown in FIG. 5, when the windshield 83 is irradiated with light emitted from the display system 1, the light is reflected by the windshield 83 and enters the eyes of the user, who is the driver.

(1.2) Display System The display system 1 projects a virtual image 91 in a target space 93 set in front of the automobile as shown in FIG. 4 by irradiating the windshield 83 with light. . This image 91 is hereinafter referred to as a virtual image 91 . In this case, the user visually recognizes the virtual image 91 projected onto the target space 93 through the windshield 83 . A “virtual image” in the present disclosure means an image formed by the diverging light beams as if there were an actual object when the light emitted from the display system 1 hits a reflecting member such as the windshield 83 and diverges. Therefore, the user driving the mobile device 8 can see the virtual image 91 projected by the display system 1 superimposed on the real space that spreads out in front of the automobile. Therefore, according to the display system 1, for example, various driving support information such as vehicle speed information, navigation information, pedestrian information, forward vehicle information, lane deviation information, and vehicle condition information are displayed as a virtual image 91, and the user can be visually recognized. As a result, the user can see the driving support information only by slightly moving the line of sight from the state in which the line of sight is directed forward of the windshield 83 .

The display system 1 forms a virtual image 91 on a virtual plane 90 that intersects the optical axis 92 of the display system 1 . In this embodiment, the optical axis 92 is along the road surface 94 in the target space 93 in front of the moving device 8 . A virtual plane 90 on which the virtual image 91 is formed is substantially perpendicular to the road surface 94 . For example, when the road surface 94 is horizontal, the virtual image 91 is displayed along the vertical plane. In the following, three axes, the X-axis, the Y-axis, and the Z-axis, which are orthogonal to each other, are set, and as shown in FIGS. The display system 1 will be described with the direction D2 as the direction D2 and the Z-axis direction as the third direction D3.

As shown in FIG. 5, the display system 1 comprises a projection unit 2 and an optical system 6. As shown in FIG. The projection unit 2 has a display surface 32 . The display surface 32 displays an image projected in the target space 93 as a virtual image 91 (see FIG. 4). The optical system 6 guides the light emitted from the image displayed on the display surface 32 of the projection unit 2 to the windshield 83 . That is, the optical system 6 irradiates a predetermined position with light emitted from the display surface 32 . The light emitted from the image displayed on the display surface 32 is hereinafter referred to as display light.

The display system 1 further comprises a housing 7 shown in FIGS. 1 and 2. FIG. The housing 7 holds the optical system 6 (see FIG. 3). As shown in FIG. 6, the housing 7 has a first member 71 and a second member 72 that can be separated in the third direction D3. Each of the first member 71 and the second member 72 is made of resin. The first member 71 and the second member 72 are combined by moving toward each other in the third direction D3.

The first member 71 is a lower case that forms the lower half of the housing 7 when the display system 1 is installed on the mobile device 8 . The first member 71 is formed in a box shape opening toward the second member 72 . The first member 71 has a bottom portion 710 and a peripheral wall portion 711 protruding from the peripheral edge of the bottom portion 710 toward the second member 72 .

The second member 72 is an upper case that constitutes the upper half of the housing 7 when the display system 1 is installed on the moving device 8, and is shaped like a box that opens toward the first member 71. there is The second member 72 has a ceiling portion 720 facing the bottom portion 710 of the first member 71 and a peripheral wall portion 721 projecting from the peripheral edge of the ceiling portion 720 toward the first member 71 . The second member 72 is configured such that the end portion of the peripheral wall portion 721 on the side of the first member 71 and the end portion of the peripheral wall portion 711 of the first member 71 on the side of the second member 72 are butted against each other. is fixed to the first member 71 by Each fastener 73 is a screw. Each fastener 73 may be a bolt, nail, rivet, or the like.

As shown in FIG. 3, an internal space 74 is formed inside the housing 7 . The internal space 74 is a space surrounded by the bottom portion 710 and the peripheral wall portion 711 of the first member 71 and the ceiling portion 720 and the peripheral wall portion 721 of the second member 72 . A bottom portion 710 of the first member 71 is formed with an opening 712 through which display light emitted from the display surface 32 of the projection unit 2 enters. The opening 712 is a hole passing through the bottom portion 710 and communicates with the internal space 74 of the housing 7 .

A ceiling portion 720 of the second member 72 is formed with an exit port 722 through which display light that has entered the internal space 74 of the housing 7 from the display surface 32 of the projection unit 2 exits. The exit port 722 is a hole passing through the ceiling portion 720 and communicates with the internal space 74 of the housing 7 . The housing 7 further has a translucent cover 75 . The cover 75 is attached to the second member 72 so as to cover the emission port 722 of the second member 72 .

The projection unit 2 is attached to the first member 71 while being positioned along the outer surface of the bottom portion 710 of the first member 71, as shown in FIG. The display surface 32 of the projection unit 2 faces the opening 712 of the housing 7 and faces the internal space 74 of the housing 7 through the opening 712 . As shown in FIG. 3 , the optical system 6 is positioned in the internal space 74 of the housing 7 . The display light emitted from the display surface 32 of the projection unit 2 passes through the opening 712 of the housing 7 and enters the internal space 74, is then guided to the exit port 722 by the optical system 6, and passes through the cover 75. The light is irradiated toward the windshield 83 (see FIG. 5, etc.). That is, the internal space 74 of the housing 7 is used as a path for display light.

The optical system 6 has two mirrors, a first mirror 61 and a second mirror 62 . Each mirror 61 , 62 is positioned in an internal space 74 of the housing 7 . The first mirror 61 has a mirror surface 610 and the second mirror 62 has a mirror surface 620 . Hereinafter, the mirror surface 610 will be referred to as the first mirror surface 610 and the mirror surface 620 will be referred to as the second mirror surface 620 .

The first mirror surface 610 faces the display surface 32 of the projection unit 2 . The first mirror surface 610 is concave. Note that the first mirror surface 610 may be either spherical or aspherical. Also, the first mirror surface 610 may be flat or convex. The first mirror surface 610 reflects the display light emitted from the projection unit 2 toward the second mirror 62 .

The second mirror surface 620 faces the first mirror surface 610 . The second mirror surface 620 is concave. The second mirror surface 620 may be either spherical or aspherical. Also, the second mirror surface 620 may be flat or convex. The second mirror surface 620 reflects the display light reflected by the first mirror surface 610 toward the windshield 83 (see FIG. 4). The display light reflected by the second mirror surface 620 passes through the cover 75 and irradiates the windshield 83 . As a result, the virtual image 91 is projected onto the target space 93 .

(1.3) Projection Unit FIG. 8 shows a perspective view of the projection unit 2, and FIG. 9 shows an exploded perspective view of the projection unit 2. As shown in FIG. The projection unit 2 has a display 3 . The display 3 is a liquid crystal panel that displays an image using light emitted from a backlight. As shown in FIG. 9, the display 3 has a front surface 30 and a back surface 31. As shown in FIG. The front surface 30 is one surface in the thickness direction of the plate-shaped display device 3 , and the back surface 31 is the surface of the display device 3 opposite to the front surface 30 . Surface 30 has a display surface 32 (see FIG. 10) for displaying an image projected into object space 93 . The display surface 32 is part of the surface 30 of the display 3 . Note that the display surface 32 may be the entire surface 30 of the display 3 .

Projection unit 2 further comprises a light source 20 . A light source 20 is located on the opposite side of the display 3 from the surface 30 and serves as a backlight for the display 3 . That is, the projection unit 2 displays an image on the display surface 32 of the display 3 by irradiating the display 3 with light emitted from the light source 20 . The light emitted from the light source 20 toward the display 3 is hereinafter referred to as illumination light.

The projection unit 2 further has a housing 4 , a printed circuit board 23 , a radiator 26 , a lens 21 , a lens 22 , a radiator 25 , a heat transfer member 24 , a diffusion plate 27 , a temperature sensor 28 and an elastic member 5 . Hereinafter, the lens will be referred to as the first lens 21 and the lens will be referred to as the second lens 22 . Also, the radiator 25 is called a first radiator 25 and the radiator 26 is called a second radiator 26 .

The housing 4 accommodates the printed circuit board 23, the light source 20, the first lens 21, the second lens 22, part of the first radiator 25, the heat transfer member 24, the diffusion plate 27, the display 3, and the temperature sensor 28. there is The housing 4 is made of resin. The housing 4 has a tubular portion 40 and a partition portion 41 . The tubular portion 40 is formed in a rectangular frame shape when viewed from the axial direction of the tubular portion 40 . The tubular portion 40 has a wall portion 400 . The wall portion 400 constitutes one side of the rectangular frame-shaped tubular portion 40 and faces the rear side when the display system 1 is installed on the mobile device 8 . In addition, below, the one side in the axial direction of the tubular portion 40 is simply referred to as “one side”, and the side opposite to the one side is simply referred to as “the other side”.

As shown in FIG. 7 , one end surface of the cylindrical portion 40 extends along the outer surface of the bottom portion 710 of the first member 71 of the housing 7 via the elastic member 5 . The housing 4 is attached to the first member 71 by a plurality of fasteners 42 (see FIG. 2) along the outer surface of the housing 7 in this way. The projection unit 2 is thereby fixed to the housing 7 . Each fastener 42 is a screw. Each fastener 73 may be a bolt, nail, rivet, or the like.

The partition part 41 is positioned inside the tubular part 40 and is integrally connected to the tubular part 40 . The partition part 41 partitions the inside of the cylindrical part 40 into a first area 401 located on the other side and a second area 402 located on the one side. A hole 410 is formed in the partition portion 41 so as to extend through the partition portion 41 in the axial direction of the cylindrical portion 40 . Hole 410 communicates with first region 401 and second region 402 .

As shown in FIG. 9, the housing 4 further has a plurality of ribs 43. As shown in FIG. Each rib 43 is located in the second region 402 and connected to the partition portion 41 and the tubular portion 40 . The housing 4 further has a plurality of hooks 44 . Each hooking portion 44 protrudes from the partition portion 41 toward one side.

The housing 4 further has a plurality of protrusions 45 (see FIG. 8). Each protrusion 45 is formed on the tubular portion 40 . Each protrusion 45 protrudes toward one side from the end surface of the tubular portion 40 on one side (the first member 71 side).

As shown in FIG. 7, the printed circuit board 23 and the light source 20 are located in the first area 401. As shown in FIG. The printed circuit board 23 extends along the other side of the partition portion 41 . The light source 20 has a plurality of light emitting diodes 200 mounted on one surface of the printed board 23 . The plurality of light emitting diodes 200 are opposed to the holes 410 of the partition section 41 . A plurality of light emitting diodes 200 emit illumination light to holes 410 of partition 41 . The light source 20 may have at least one light emitting diode 200, and may have only one light emitting diode 200, for example. Further, the light-emitting element included in the light source 20 is not limited to the light-emitting diode 200, and may be a light bulb, a discharge lamp, an organic electroluminescence, or the like.

The second radiator 26 dissipates the heat generated by the printed circuit board 23 and the light source 20 to the outside of the housing 4 . Therefore, the printed circuit board 23 and the light source 20 are unlikely to reach high temperatures. The second radiator 26 is made of metal and has better heat conductivity than the housing 4 . The second radiator 26 is made of die-cast aluminum, for example. The second radiator 26 extends along the other end surface of the tubular portion 40 of the housing 4 . The second radiator 26 covers the first area 401 and the printed circuit board 23 located in the first area 401 from the other side. The second radiator 26 and printed circuit board 23 are attached to the housing 4 by a plurality of fasteners 29 shown in FIG. Each fastener 29 is a screw. Each fastener 29 may be a bolt, nail, rivet, or the like.

Most of the second radiator 26 is a heat radiating portion 260 exposed to the outside of the housing 4 . The heat of the second radiator 26 is dissipated in the heat dissipation portion 260 . As shown in FIG. 7, the second radiator 26 is in contact with the printed board 23 . Thereby, the second radiator 26 is thermally connected to the printed circuit board 23 and the light source 20 .

As shown in FIG. 2 , the heat radiating portion 260 of the second radiator 26 includes a plate-like portion 261 along the other end face of the tubular portion 40 and a plate-like portion 261 extending from the plate-like portion 261 to the opposite side of the tubular portion 40 . It has a plurality of fin portions 262 projecting toward it.

The first lens 21 shown in FIG. 7 is sandwiched between the printed circuit board 23 and the partition portion 41 . Thereby, the first lens 21 is fixed to the housing 4 . The first lens 21 is made of resin. The first lens 21 refracts the illumination light emitted from the light source 20 and irradiates the second lens 22 with the illumination light. Thereby, the illumination light efficiently reaches the second lens 22 .

In the second area 402 of the housing 4, the second lens 22, the first radiator 25, the heat transfer member 24, the diffusion plate 27 and the indicator 3 are positioned. The second lens 22, the first radiator 25, the heat transfer member 24, the diffusion plate 27, and the display 3 are arranged in this order from the partition 41 toward one side.

The second lens 22 is made of resin. The second lens 22 extends along one side surface of the partition portion 41 . The second lens 22 is surrounded by a plurality of ribs 43 of the housing 4 shown in FIG. A plurality of ribs 43 restrict movement of the second lens in a direction crossing the axial direction of the housing 4 . A portion of the second lens 22 is positioned between the hook portion 44 of the housing 4 and the partition portion 41 and hooked on the hook portion 44 . The hooking portion 44 restricts the movement of the second lens 22 to one side. The second lens 22 covers the hole 410 of the partition 41 . The second lens 22 refracts the illumination light that has passed through the first lens 21 and irradiates the heat transfer member 24 with the illumination light. Thereby, the illumination light hits the heat transfer member 24 efficiently.

The first radiator 25 radiates the heat of the display 3 to the outside of the housing 4 . Therefore, even if the display 3 is irradiated with illumination light, sunlight, or the like, the temperature of the display 3 is unlikely to rise. The first radiator 25 is formed in a plate shape. Specifically, the first radiator 25 is made of sheet metal and is formed by bending a metal plate.

The first radiator 25 has a contact portion 250 and an extension portion 254 . The first radiator 25 consists of only the contact portion 250 and the extension portion 254 . The contact portion 250 is located in the second area 402 inside the housing 4 . The contact portion 250 has a rectangular frame shape when viewed in a direction orthogonal to the display surface 32 and is formed in a plate shape parallel to the display surface 32 of the display device 3 . A through hole 256 is formed inside the frame-shaped contact portion 250 . The through hole 256 is a rectangular hole penetrating the contact portion 250 in the axial direction of the tubular portion 40 . The illumination light that has passed through the second lens 22 passes through the through hole 256 and reaches the heat transfer member 24 .

The contact portion 250 is supported from the other side by the cylindrical portion 40 of the housing 4 and part of the plurality of ribs 43 . The tubular portion 40 and the plurality of ribs 43 restrict movement of the contact portion 250 in a direction crossing the axial direction of the housing 4 . The contact portion 250 contacts the heat transfer member 24 , the heat transfer member 24 contacts the diffusion plate 27 , and the diffusion plate 27 contacts the display 3 . Thereby, the contact portion 250 of the first radiator 25 is thermally connected to the display 3 through the heat transfer member 24 and the diffuser plate 27 . Therefore, the heat of the display device 3 is transferred to the contact portion 250 through the diffuser plate 27 and the heat transfer member 24 .

The extending portion 254 extends from the contact portion 250 . A portion of the extending portion 254 is a heat radiating portion 255 located outside the housing 4 . The heat of the contact portion 250 is transferred to the extension portion 254 and dissipated in the heat dissipation portion 255 . The extending portion 254 is connected to the edge of the contact portion 250 on the wall portion 400 side of the housing 4 . The extending portion 254 extends over the entire length of the edge of the contact portion 250 on the wall portion 400 side.

The extending portion 254 is formed in a U shape when viewed from the direction in which the edge of the contact portion 250 on the wall portion 400 side extends. The extending portion 254 has a first piece 251 , a second piece 252 and a third piece 253 . The first piece 251, the second piece 252 and the third piece 253 are continuous from one side of the contact portion 250 in this order. The first piece 251 protrudes to one side along the inner surface of the wall portion 400 from the edge of the contact portion 250 on the wall portion 400 side. The second piece 252 protrudes from the edge of the first piece 251 opposite to the contact portion 250 along one end surface of the wall portion 400 toward the side opposite to the contact portion 250 . The third piece 253 protrudes from the edge of the second piece 252 opposite to the first piece 251 along the outer surface of the wall portion 400 toward the other side. As shown in FIG. 7 , the surface of the third piece 253 opposite to the wall portion 400 is not covered with the housing 4 and is exposed to the outside of the housing 4 . In this embodiment, the third piece 253 forming one end of the first radiator 25 is the heat radiation portion 255 that radiates the heat of the first radiator 25 .

In the first radiator 25 shown in FIG. 9, only the second piece 252 and the third piece 253 located at one end of the first radiator 25 are located outside the housing 4, and the other portions are inside the housing 4. positioned. As a result, the first radiator 25 is covered with the housing 4 on three of the four sides of the first radiator 25 . For this reason, dust, dirt, and the like existing outside the housing 4 are less likely to adhere to the first radiator 25 . Here, the “four directions” are four directions that are parallel to a plane perpendicular to the thickness direction of the contact portion 250 and perpendicular to each other. At least one of the four sides of the first radiator 25 between the housing 4 and the first member 71 is covered by the housing 4 in order to prevent dust from adhering to the first radiator 25 . All you have to do is Therefore, the first radiator 25 may be covered by the housing 4 on only one or only two of its four sides. The first radiator 25 may be covered with the housing 4 on all four sides, or may not be covered with the housing 4 on all four sides.

The first piece 251 and the second piece 252 of the extending portion 254 are located on one side (surface 30 side) of the rear surface 31 of the display device 3 , and the second piece 252 and the third piece 253 are located outside the housing 4 . located in That is, the extending portion 254 has a portion configured by the second piece 252 , and this portion is located closer to the front surface 30 than the back surface 31 of the display 3 and outside the housing 4 . there is Therefore, while supporting the display device 3 from the back surface 31 side by the contact portion 250 , part of the extending portion 254 is located outside the housing 4 , thereby improving the heat dissipation performance of the first radiator 25 .

As shown in FIGS. 2 and 3, the projection unit 2 has a heat insulation structure 100. As shown in FIG. The heat insulating structure 100 is located between the first radiator 25 and the second radiator 26 to insulate the first radiator 25 and the second radiator 26 . The heat insulation structure 100 has a heat insulation space 101 and a heat insulation portion 102 . The heat insulating space 101 is a space within a recess 403 formed on the outer surface of the tubular portion 40 of the housing 4 . The recess 403 is formed on the outer surface of the wall portion 400 of the tubular portion 40 and has a rectangular shape when viewed in a direction orthogonal to the wall portion 400 . The recess 403 opens toward the other side (the second radiator 26 side).

The plate-like portion 261 of the second radiator 26 has an overlapping portion 263 overlapping the third piece 253 of the first radiator 25 when viewed from the axial direction of the housing 4 . The heat insulating space 101 is located between the third piece 253 of the first radiator 25 and the overlapping portion 263 of the second radiator 26 . Air having a lower thermal conductivity than the housing 4 exists in the heat insulating space 101 . For this reason, the heat of the heat radiating portion 260 of the second radiator 26 is less likely to be transferred to the heat radiating portion 255 of the first radiator 25, and the deterioration of the heat radiation performance of the first radiator 25 is suppressed.

The heat insulating portion 102 is a ridge formed on the outer surface of the tubular portion 40 of the housing 4 . The heat insulating portion 102 extends along the end surface of the third piece 253 of the first radiator 25 on the other side (the side opposite to the second piece 252 ). Note that the heat insulating portion 102 may contact the third piece 253 or may not contact the third piece 253 .

The surface of the heat insulating portion 102 on the other side (the side opposite to the third piece 253) constitutes the surface of the recess 403 on the one side (the side of the third piece 253). facing the overlapping portion 263 of the second radiator 26 . That is, the heat insulating portion 102 is positioned between the third piece 253 and the overlapping portion 263 of the second radiator 26 . Therefore, the heat radiated from the overlapping portion 263 of the second radiator 26 toward the third piece 253 of the first radiator 25 is likely to be blocked by the heat insulating wall, and the heat is less likely to be transferred from the overlapping portion 263 to the third piece 253. .

The heat transfer member 24 shown in FIG. 7 transfers the heat transferred from the display 3 through the diffusion plate 27 to the heat transfer member 24 to the first radiator 25 . The heat transfer member 24 is made of glass and has translucency. The heat transfer member 24 is formed in a rectangular shape elongated in the left-right direction when viewed from the direction orthogonal to the display surface 32, and is formed in a plate shape along the surface of the contact portion 250 of the first heat radiator 25 on the first member 71 side. It is That is, the heat transfer member 24 is a glass plate. The heat transfer member 24 is sandwiched between the contact portion 250 and the diffuser plate 27 . The heat transfer member 24 is surrounded by a plurality of ribs 43 and the tubular portion 40 of the housing 4 shown in FIG. The tubular portion 40 and the plurality of ribs 43 restrict movement of the heat transfer member 24 in a direction crossing the axial direction of the tubular portion 40 . The heat transfer member 24 covers the through hole 256 of the first radiator 25 . The illumination light that has passed through the through holes 256 of the first radiator 25 reaches the diffuser plate 27 through the heat transfer member 24 . One surface of the heat transfer member 24 is in contact with the entire or most part of the other surface of the diffuser plate 27 . Therefore, the heat of the diffuser plate 27 is easily transferred to the heat transfer member 24 .

The diffuser plate 27 diffuses the illumination light that has passed through the heat transfer member 24 . The diffusion plate 27 is made of resin and has translucency. The diffusion plate 27 is a substantially rectangular sheet. The diffuser plate 27 is sandwiched between the heat transfer member 24 and the display 3 . The diffuser plate 27 is surrounded by a plurality of ribs 43 of the housing 4 . The plurality of ribs 43 restrict movement of the diffuser plate 27 in a direction crossing the axial direction of the cylindrical portion 40 . The illumination light diffused by the diffuser plate 27 reaches the rear surface 31 of the display 3 . The surface of the diffuser plate 27 on the side of the display device 3 covers the entire or most of the rear surface 31 of the display device 3 . Therefore, the heat of the display 3 is easily transferred to the heat transfer member 24 via the diffuser plate 27 .

The display 3 is sandwiched between the diffusion plate 27 and the elastic member 5 . The display 3 is supported from the other side by the contact portion 250 of the first radiator 25 via the diffusion plate 27 and the heat transfer member 24 . That is, the first radiator 25 supports the display 3 from the side opposite to the display surface 32 . The indicator 3 is formed in a substantially rectangular plate shape. The indicator 3 is surrounded by the tubular portion 40 of the housing 4 and the plurality of ribs 43 . The tubular portion 40 and the plurality of ribs 43 restrict movement of the indicator 3 in a direction crossing the axial direction of the tubular portion 40 . That is, the housing 4 positions the indicator 3 .

A display surface 32 of the display 3 is a rectangular area on the surface 30 of the display 3 . The illumination light emitted from the diffusion plate 27 to the rear surface 31 of the display 3 passes through the display 3 and is emitted from the display surface 32 as display light. The display light emitted from the display surface 32 is light whose optical axis is perpendicular to the display surface 32 .

As shown in FIG. 10, the display surface 32 has a display area 33 and a non-display area . In addition, in FIG. 10, each of the peripheral edge of the display area 33 and the peripheral edge of the non-display area 34 is indicated by a two-dot chain line. The display surface 32 of this embodiment consists of only the display area 33 and the non-display area 34 . The display area 33 is an area for displaying an image, and is an area (active area) corresponding to the active liquid crystal of the display 3 on the display surface 32 . Images include, for example, characters, graphics, and the like. Note that the image may be either a still image or a moving image. The non-display area 34 is a frame-shaped area surrounding the display area 33 and is adjacent to the display area 33 . The non-display area 34 does not change its display state and does not display an image, but emits illumination light transmitted through the display 3 as display light.

The display area 33 is non-rectangular. Specifically, the display area 33 is a substantially quadrangular area surrounded by four sides, ie, a first side 331 to a fourth side 334 as outer peripheral edges. The first side 331 and the second side 332 are positioned apart in the second direction D2, and the third side 333 and the fourth side 334 are positioned apart in the first direction D1. When the display system 1 is installed on the mobile device 8 , the first side 331 is located to the left of the second side 332 and the third side 333 is located forward of the fourth side 334 .

The third side 333 connects one end of the first side 331 and one end of the second side 332 . The fourth side 334 connects the end of the first side 331 opposite to the third side 333 and the end of the second side 332 opposite to the third side 333 . Each of the first side 331 and the second side 332 is linear, and each of the third side 333 and the fourth side 334 is curved. The first side 331 is substantially parallel to the first direction D1, and the second side 332 is inclined with respect to the first direction D1 so as to separate from the first side 331 as it approaches the fourth side 334 . That is, when viewed from the direction orthogonal to the display surface 32, the inclination angle of the first side 331 with respect to the first direction D1 is greater than the inclination angle of the second side 332 with respect to the first direction D1. The third side 333 has an arcuate shape that protrudes toward the fourth side 334 side. The fourth side 334 is convex toward the side opposite to the third side 333 and has an arcuate curvature smaller than that of the third side 333 . In the first direction D1, the end of the first side 331 on the third side 333 side is located closer to the fourth side 334 than the end of the second side 332 on the third side 333 side. In the first direction D1, the end of the first side 331 on the fourth side 334 side is located on the opposite side of the third side 333 from the end of the second side 332 on the fourth side 334 side.

By making the display area 33 non-rectangular as described above, an area (first area 401 described later) formed by display light emitted from the display area 33 in the virtual image 91 (see FIG. 4) projected onto the target space 93 has a rectangular shape elongated in the horizontal direction (see FIG. 12). That is, the display light emitted from the non-rectangular display area 33 passes through the first mirror 61, the second mirror 62 and the cover 75 (see FIG. 5) and is corrected by hitting the curved inner surface of the windshield 83. . Thereby, a rectangular image formed by the display light emitted from the display area 33 is projected onto the target space 93 .

A temperature sensor 28 shown in FIG. 9 is a thermistor and detects the temperature of the display 3 . The temperature sensor 28 of this embodiment is attached to a portion other than the display area 33 on the surface 30 of the display 3 and is positioned on the surface of the display 3 facing the elastic member 5 . Temperature sensor 28 senses the temperature of surface 30 . The temperature detected by the temperature sensor 28 is used, for example, to detect an abnormality in the display 3 . Note that the temperature sensor 28 is not limited to a thermistor, and may be a thermocouple or the like.

The elastic member 5 shown in FIG. 3 relieves the force transmitted from the first member 71 of the housing 7 to the display 3 and the housing 4 and moderates the shock and vibration transmitted from the first member 71 to the housing 4 and the display 3 . The elastic member 5 is formed in a plate shape parallel to the display surface 32 of the display device 3 . As shown in FIG. 8, the elastic member 5 is formed in a frame shape having a rectangular outer shape when viewed from the direction orthogonal to the display surface 32 . The elastic member 5 is made of foamed urethane resin and has elasticity. The elastic member 5 is positioned along one end surface of the display surface 32 of the display device 3 and the cylindrical portion 40 of the housing 4 . Note that the elastic member 5 may be any member having elasticity, and may be rubber or the like.

A plurality of fitting holes 50 are formed in the elastic member 5 . Each fitting hole 50 penetrates the elastic member 5 in a direction orthogonal to the display surface 32 (thickness direction of the elastic member 5). A portion of the plurality of ribs 43 of the housing 4 and the plurality of protrusions 45 are respectively fitted into the plurality of fitting holes 50 . Some of the plurality of ribs 43 and the plurality of projections 45 restrict movement of the elastic member 5 in a direction crossing the axial direction of the tubular portion 40 . That is, the elastic member 5 is fixed to the housing 4 .

The elastic member 5 is fixed to one end surface of the cylindrical portion 40 of the housing 4 with double-sided tape. A part of the plurality of ribs 43 and each of the plurality of projections 45 of the housing 4 are press-fitted into corresponding fitting holes 50 . Thereby, the elastic member 5 is fixed to the housing 4 . The elastic member 5 is removable from the housing 4 . Therefore, by removing the elastic member 5 from the housing 4 , the indicator 3 , the diffusion plate 27 , the heat transfer member 24 , the first radiator 25 and the like held down by the elastic member 5 can be removed from the housing 4 . The method of fixing the elastic member 5 to the housing 4 can be changed. For example, the elastic member 5 may be fixed to the housing 4 only with double-sided tape. Alternatively, the elastic member 5 may be fixed to the housing 4 only by pressing some of the plurality of ribs 43 and each of the plurality of projections 45 into the corresponding fitting holes 50 . Alternatively, the elastic member 5 may be fixed to the housing by other means such as an adhesive.

A sensor hole 53 is formed in the elastic member 5 . The sensor hole 53 penetrates the elastic member 5 in a direction perpendicular to the display surface 32 . The sensor hole 53 faces the temperature sensor 28 (see FIG. 9) attached to the surface 30 of the display 3 . That is, the sensor hole 53 is formed in a portion of the elastic member 5 corresponding to the temperature sensor 28 .

The temperature sensor 28 is located in the sensor hole 53 and is not in contact with the elastic member 5 . Therefore, for example, even if force is applied to the elastic member 5 from the first member 71 or the like, the force is unlikely to be applied to the temperature sensor 28 via the elastic member 5 . Therefore, temperature sensor 28 is less susceptible to external force.

As shown in FIG. 7, the elastic member 5 fixed to the housing 4 contacts the display 3, and the first radiator 25, the diffusion plate 27, the heat transfer member 24 and the display 3 move to one side. regulate things. That is, the elastic member 5 also serves as a pressing member that restricts the movement of the first radiator 25, the diffusion plate 27, the heat transfer member 24, and the display 3 to one side.

The elastic member 5 is directly pressed against the first member 71 by the surface 30 of the display 3 and one end surface of the cylindrical portion 40 . Thereby, the elastic member 5 is sandwiched between the display device 3 and the first member 71 and sandwiched between the housing 4 and the first member 71 . The elastic member 5 extends over the entire circumferential length of the cylindrical portion 40 and seals the space between the cylindrical portion 40 and the first member 71 . For this reason, it is difficult for dust and dirt to enter the interior of the housing 4 where the indicator 3 and the like are present.

As shown in FIG. 11 , the first member 71 further has an inner clamping portion 723 , an outer clamping portion 724 and a plurality of ribs 725 . The inner clamping portion 723 is a frame-shaped portion surrounding the opening 712 in the bottom portion 710 of the first member 71 , and is located outside the periphery of the opening 712 .

The outer clamping portion 724 protrudes from the peripheral portion of the inner clamping portion 723 in the bottom portion 710 toward the projection unit 2 side (the outer surface side of the bottom portion 710). The outer clamping portion 724 is formed in a rectangular frame shape surrounding the inner clamping portion 723 . The frame-shaped outer clamping portion 724 is positioned outside the frame-shaped inner clamping portion 723 . A plurality of ribs 725 protrude from an annular region 728 between the inner clamping portion 723 and the outer clamping portion 724 of the bottom portion 710 toward the outer surface of the bottom portion 710 . The plurality of ribs 725 are spaced apart in the circumferential direction of the annular region 728 . Each rib 725 extends linearly in the same direction when viewed from the direction perpendicular to the display surface 32 . A portion of the annular region 728 of the bottom portion 710 where the plurality of ribs 725 does not exist forms a recess that is recessed toward the inner surface side of the bottom portion 710 . The frame-shaped inner clamping portion 723 and the frame-shaped outer clamping portion 724 are connected via a plurality of ribs 725 .

As shown in FIG. 7, the end surface of the inner holding portion 723 on the side of the projection unit 2, the end surface of the outer holding portion 724 on the side of the projection unit 2, and the end surfaces of the ribs 725 on the side of the projection unit 2 are continuously flush and flat. and is in contact with the surface of the elastic member 5 opposite to the display 3 . The elastic member 5 is sandwiched and compressed between a portion of the bottom portion 710 consisting of the inner holding portion 723 , the outer holding portion 724 and the plurality of ribs 725 and a portion of the projection unit 2 consisting of the display 3 and the cylindrical portion 40 . there is

In the display device 3 , the first portion (the portion corresponding to the inner clamping portion 723 ) surrounding the portion corresponding to the opening 712 in the elastic member 5 is pressed against the first member 71 . A second portion surrounding the first portion (a portion corresponding to the outer clamping portion 724 ) is pressed against the first member 71 . Therefore, the elastic member 5 is sandwiched between two portions, a frame-shaped inner sandwiching portion 723 and a frame-shaped outer sandwiching portion 724 positioned outside the frame-shaped inner sandwiching portion 723 . Therefore, it is difficult for dust, dirt, or the like to enter the tubular portion 40 from between the bottom portion 710 of the first member 71 and the tubular portion 40 of the housing 4 . An end surface 726 of each rib 725 on the projection unit 2 side is a flat surface and forms a guide surface along the surface of the elastic member 5 opposite to the display device 3 . Therefore, when the projection unit 2 is attached to the first member 71 , the elastic member 5 of the projection unit 2 can be slid along the guide surfaces of the plurality of ribs 725 . Easier to install.

As shown in FIG. 8, inside the frame-shaped elastic member 5, a window hole 54 is formed through the elastic member 5 in a direction orthogonal to the display surface 32 (thickness direction of the elastic member 5). The window hole 54 is positioned on the path of display light emitted from the display surface 32 of the display device 3 . The window hole 54 is larger than the display area 33 (see FIG. 10) of the display surface 32 when viewed in a direction orthogonal to the display surface 32 and has a similar shape to the display area 33 . Of the display light emitted from the display surface 32, the window hole 54 allows only the display light emitted from the entire display area 33 and the display light emitted from the inner periphery of the frame-shaped non-display area 34 to pass therethrough. That is, of the display light emitted from the display surface 32, the elastic member 5 blocks only the display light emitted from the outer peripheral portion of the frame-shaped non-display area 34, thereby blocking the entire display area 33 and the inner circumference of the non-display area 34. The display light emitted from the part is not blocked. Note that the elastic member 5 does not have to block the display light emitted from the display surface 32 . That is, in this case, all of the display light emitted from the display surface 32 passes through the window holes 54 .

The display light that has passed through the window hole 54 of the elastic member 5 passes through the opening 712 of the first member 71 shown in FIG. 7 and irradiates the first mirror 61 (see FIG. 3). That is, the opening 712 is positioned on the path of display light emitted from the display surface 32 . The opening 712 is smaller in size than the window hole 54 of the elastic member 5 when viewed in the direction orthogonal to the display surface 32 , and the periphery of the opening 712 is located inside the periphery of the window hole 54 . Therefore, the peripheral portion of the opening 712 in the first member 71 blocks the progress of the peripheral portion of the display light emitted from the display surface 32 of the display device 3, thereby defining the shape of the display light. That is, in this case, the first member 71 functions as a light shielding member that defines the shape of display light emitted from the display surface 32 of the display device 3 . That is, the light shielding member is part of the housing 7 .

As shown in FIG. 10 , the peripheral edge of the opening 712 of the first member 71 has a shape along the outer peripheral shape of the display area 33 when viewed from the direction orthogonal to the display surface 32 . Here, the "shape along the outer peripheral shape of the display area 33" in the present disclosure includes a shape that completely matches the peripheral edge of the display area 33 when viewed from the direction perpendicular to the display surface 32, and a shape that completely matches the peripheral edge of the display area 33. and similar shapes.

The peripheral edge of the opening 712 of the first member 71 of this embodiment has a shape similar to the peripheral shape of the display area 33 . In addition, when viewed from the direction orthogonal to the display surface 32 , the opening 712 of the first member 71 is larger in size than the display area 33 , and the peripheral edge of the opening 712 is located outside the outer peripheral edge of the display area 33 . . Therefore, even if there is an error in the size, mounting position, etc. of each member in the display system 1 , the display light emitted from the display area 33 is less likely to be blocked by the periphery of the opening 712 of the first member 71 . Note that the “similar shape” in the present disclosure includes not only a shape in which the shape of the peripheral edge of the display area 33 and the shape of the peripheral edge of the opening 712 are completely similar, but also the shape of the peripheral edge of the display area 33 and the peripheral edge of the opening 712. A case in which the shape is substantially similar and the distance between the peripheral edge of the display area 33 and the peripheral edge of the opening 712 when viewed from the direction perpendicular to the display surface 32 changes within a predetermined range is also included.

Specifically, the peripheral edge of the opening 712 has first to fourth sides 7121 to 7124 corresponding to the first to fourth sides 331 to 334 of the display area 33 when viewed from the direction orthogonal to the display surface 32. ing. The opening 712 is a substantially quadrilateral area surrounded by four sides of a first side 7121 to a fourth side 7124 as peripheral edges. The first side 7121 and the second side 7122 are positioned apart in the second direction D2, and the third side 7123 and the fourth side 7124 are positioned apart in the first direction D1. When the display system 1 is installed on the mobile device 8 , the first side 7121 is located to the left of the second side 7122 and the third side 7123 is located forward of the fourth side 7124 .

The third side 7123 connects one end of the first side 7121 and one end of the second side 7122 . The fourth side 7124 connects the end of the first side 7121 opposite to the third side 7123 and the end of the second side 7122 opposite to the third side 7123 . Each of the first side 7121 and the second side 7122 is linear, and each of the third side 7123 and the fourth side 7124 is curved. The first side 7121 is substantially parallel to the first direction D1, and the second side 7122 is inclined with respect to the first direction D1 so as to separate from the first side 7121 as it approaches the fourth side 7124 . That is, when viewed from the direction orthogonal to the display surface 32, the inclination angle of the first side 7121 with respect to the first direction D1 is greater than the inclination angle of the second side 7122 with respect to the first direction D1. The third side 7123 has an arcuate shape that protrudes toward the fourth side 7124 side. The fourth side 7124 is convex toward the side opposite to the third side 7123 and has an arcuate curvature smaller than that of the third side 7123 . In the first direction D1, the end of the first side 7121 on the third side 7123 side is positioned closer to the fourth side 7124 than the end of the second side 7122 on the third side 7123 side. In the first direction D1, the end of the first side 7121 on the fourth side 7124 side is located on the opposite side of the third side 7123 from the end of the second side 7122 on the fourth side 7124 side.

That is, the peripheral edge of the opening 712 of this embodiment is composed of two straight sides and two curved sides. Note that the shape of the peripheral edge of the opening 712 is not limited to the shape of the present embodiment as long as it follows the peripheral edge of the display area 33 . For example, the perimeter of the opening 712 may have only one curved side, or may have three or more curved sides. Also, the opening 712 may have a shape other than a substantially rectangular shape, such as a triangular shape, a substantially pentagonal shape, a circular shape, an elliptical shape, or the like. Also, the opening 712 may be rectangular.

The display light that has passed through the opening 712 of the first member 71 reaches the windshield 83 without being blocked by other members. Therefore, the virtual image 91 projected onto the target space 93 by the display system 1 is formed by the display light emitted from the display area 33 of the display surface 32 and the display light emitted from the inner periphery of the non-display area 34. . That is, as shown in FIG. 12, the virtual image 91 includes a first region 401 formed by display light emitted from the display region 33 and a second region 401 formed by display light emitted from the inner periphery of the non-display region 34 . 2 area 402 . Here, if an error occurs in the dimensions, mounting positions, etc. of each member in the display system 1, there is a possibility that part of the second area 402 will not be displayed, but the entire first area 401 can be displayed. highly sexual. This is because the periphery of the opening 712 of the first member 71 is larger than the periphery of the display area 33 as described above.

In the display system 1 of this embodiment, as shown in FIG. 10 , the peripheral edge of the opening 712 of the first member 71 has a shape along the outer peripheral shape of the display area 33 . For this reason, the virtual image 91 projected onto the target space 93 by the display system 1 tends to be an image in which the outer edge of the second area 402 follows the outer edge of the first area 401 and has a good appearance and is less likely to cause discomfort.

If the perimeter of the opening 712 of the first member 71 is rectangular, the virtual image 91 projected onto the target space 93 by the display system 1 is, as shown in FIG. It tends to be a shape that does not follow the outer periphery of 401 . By comparing FIG. 12 and FIG. 13, it can be understood that the display system 1 of this embodiment can make the virtual image 91 look good.

Moreover, as shown in FIG. 7, the elastic member 5 of the present embodiment is a holding member that restricts the movement of the first radiator 25, the diffusion plate 27, the heat transfer member 24, and the indicator 3 to the first member 71 side. It also serves as a component. Therefore, the number of parts of the projection unit 2 can be reduced. Further, if the projection unit 2 has a pressing member that restricts the movement of the elastic member 5 toward the first member 71 side, the elastic member 5 has a In addition, the pressing member is positioned, and the distance from the display surface 32 of the display device 3 to the opening 712 of the first member 71 tends to be long. In this case, the display light emitted from the display surface 32 is likely to be blocked by the peripheral portion of the opening 712 in the first member 71, and the range of the display surface 32 that can be used as the display area 33 is narrowed. However, the projection unit 2 of this embodiment does not need to include a pressing member in addition to the elastic member 5 . Therefore, the display light emitted from the display surface 32 is less likely to be blocked by the peripheral portion of the opening 712 in the first member 71, and the display area 33 of the display surface 32 can be effectively used.

The inner peripheral surface forming the peripheral edge of the opening 712 of the first member 71 of the present embodiment is parallel to the direction orthogonal to the display surface 32 of the display 3, but as shown in FIGS. 14A and 14B, the display surface 32 may be an inclined surface 713 that is inclined with respect to the direction orthogonal to 32 . The inclined surface 713 shown in FIG. 14A is inclined so that the portion closer to the display surface 32 is located outside the opening 712 . Also, the inclined surface 713 shown in FIG. 14B is inclined so that the portion closer to the display surface 32 is located inside the opening 712 . By forming the inner peripheral surface forming the peripheral edge of the opening 712 of the first member 71 as the inclined surface 713 in this way, the amount of the display light emitted from the display surface 32 that is blocked by the peripheral edge of the opening 712 is suppressed. The display area 33 of the surface 32 can be effectively used.

Further, in the present embodiment, the first member 71 is the light blocking member that defines the shape of the display light emitted from the display surface 32 of the display device 3, but a member other than the first member 71 may be used. FIG. 14C shows an example in which the elastic member 5 is used as the light shielding member. In this example, the shape of the display light emitted from the display surface 32 is defined by the peripheral edge of the window hole 54 in the elastic member 5, and the window hole 54 is an opening having the same shape and size as the opening 712 in the above embodiment. . By using the elastic member 5 detachable from the housing 4 as the light shielding member in this manner, the elastic member 5 can be replaced with another elastic member 5 having a different shape of the window hole 54 (opening). Therefore, for example, when the display system 1 is installed in another mobile device 8, the elastic member 5 can be simply replaced with an elastic member 5 having a window hole 54 having a shape suitable for the other mobile device 8. , it becomes possible to project a good-looking image 91 .

(1.4) First Mirror and Its Mounting Structure As shown in FIG. 15 , the first mirror 61 has a first mirror surface 610 and a holding member 611 that holds the first mirror surface 610 . The holding member 611 is made of resin. The holding member 611 has a holding portion 612 and a pair of fixing portions 613 . The holding part 612 is substantially parallel to the display surface 32 of the projection unit 2 and formed in a substantially rectangular plate shape when viewed in a direction orthogonal to the display surface 32 . The holding portion 612 is curved so that the surface on the side of the projection unit 2 is concave and the surface on the side opposite to the projection unit 2 is convex.

The first mirror surface 610 is provided on the surface of the holding portion 612 on the projection unit 2 side. The first mirror surface 610 is composed of, for example, a metal film formed on the surface of the holding section 612 on the projection unit 2 side by vapor deposition or the like.

A pair of fixing portions 613 are formed on both end surfaces of the holding portion 612 in the length direction. Each fixing portion 613 is formed integrally with the holding portion 612 and protrudes outward from the holding portion 612 in the longitudinal direction of the holding portion 612 .

The housing 7 has a positioning structure 76 and a sandwiching structure 77 . The sandwiching structure 77 sandwiches and holds the first mirror 61 in the third direction D3. The positioning structure 76 positions the first mirror 61 and restricts its movement in the direction intersecting the third direction D3. That is, the positioning structure 76 is arranged so that the first mirror 61 (more specifically, the mounting portion 614 described later) is positioned in the direction intersecting the sandwiching direction, which is the direction in which the first mirror 61 is sandwiched between the first member 71 and the second member 72 . Position 61. Specifically, the positioning structure 76 of the present embodiment is configured to move the first mirror 61 in a first direction D1 perpendicular to the third direction (sandwiching direction) D3 and in a direction perpendicular to both the third direction D3 and the first direction D1. Positioning is performed in both directions of the second direction D2.

A pair of fixing bases 714 corresponding to the pair of fixing portions 613 on a one-to-one basis is formed on the bottom portion 710 of the first member 71 of the housing 7 . Each fixed base 714 protrudes toward the second member 72 . Each fixing part 613 is fixed while being installed on a corresponding fixing base 714 . Thereby, the first mirror 61 is fixed to the first member 71 .

A first fixing portion 613a, which is one fixing portion 613 of the pair of fixing portions 613, has one mounting portion 614 and one positioning portion 615, and a second fixing portion, which is the other fixing portion 613. 613 b has two mounting portions 614 and one positioning portion 615 . That is, the holding member 611 has a total of three mounting portions 614 and a total of two positioning portions 615 .

Each mounting portion 614 is a protruding portion that is curved so as to protrude toward the side opposite to the corresponding fixing base 714 . Each positioning part 615 is a protruding part that is curved so as to protrude toward the side opposite to the corresponding fixing base 714 . The mounting portion 614 of the first fixing portion 613a is formed at one end of the first fixing portion 613a in the third direction D3, and the two mounting portions 614 of the second fixing portion 613b are formed in the second fixing portion 613b. They are formed at the ends on both sides of the three directions D3. A positioning portion 615 of each fixing portion 613 is formed in an intermediate portion of the fixing portion 613 in the third direction D3. The three mounting portions 614 and the two positioning portions 615 of the holding member 611 do not overlap each other when viewed in the third direction D3, and are positioned apart in the first direction D1 and the second direction D2.

A first fixing base 714a, which is the fixing base 714 corresponding to the first fixing portion 613a of the pair of fixing bases 714, includes one base portion 715 corresponding to the mounting portion 614 of the first fixing portion 613a and the first fixing base 715. and one fitting portion 716 corresponding to the positioning portion 615 of the portion 613a. The second fixing base 714b, which is the fixing base 714 corresponding to the second fixing part 613b of the pair of fixing bases 714, includes two base parts 715 respectively corresponding to the two mounting parts 614 of the second fixing part 613b, and one fitting portion 716 corresponding to the positioning portion 615 of the second fixing portion 613b.

Each base portion 715 is a projection protruding toward the corresponding mounting portion 614 . Each fitting portion 716 is a protrusion that protrudes toward the corresponding positioning portion 615 in the third direction D3, and is formed in a cylindrical shape whose axial direction is parallel to the third direction D3.

Each mounting portion 614 of the holding member 611 has a mounting portion 616 . An installation portion 616 of each attachment portion 614 is formed in a rectangular plate shape whose thickness direction is parallel to the third direction D3. An installation portion 616 of each attachment portion 614 is a flat surface having both sides in the thickness direction perpendicular to the third direction D3. Each base portion 715 of the first member 71 has an installation surface 717 orthogonal to the third direction D3. Each mounting portion 614 of the holding member 611 is installed such that one surface of the installation portion 616 in the thickness direction is in direct contact with the installation surface 717 of the corresponding base portion 715 . Only three mounting portions 614 of the first mirror 61 are in contact with the housing 7 .

A hole 617 penetrating in the third direction D3 is formed in each positioning portion 615 of the holding member 611 . Each fitting portion 716 of the first member 71 is fitted into a corresponding hole 617 of the positioning portion 615 . Each fitting portion 716 of the first member 71 restricts movement of the corresponding positioning portion 615 in a direction crossing the third direction D3. That is, in this embodiment, the positioning structure 76 is configured by the plurality of fitting portions 716 of the holding member 611 .

A hole 617 of the positioning portion 615 of the first fixing portion 613a is formed in a square shape when viewed from the third direction D3. The hole 617 of the positioning portion 615 of the first fixing portion 613a has substantially the same dimension in the first direction D1 and the dimension in the second direction D2 as the corresponding fitting portion 716 . Therefore, the positioning portion 615 of the first fixing portion 613a is restricted from moving in the first direction D1 and the second direction D2 by the corresponding fitting portion 716 .

The hole 617 of the positioning portion 615 of the second fixing portion 613b is formed in a rectangular shape whose dimension in the second direction D2 is longer than the dimension in the first direction D1 when viewed from the third direction D3. The dimension of the hole 617 of the positioning portion 615 of the second fixing portion 613b in the first direction D1 is substantially the same as the dimension of the corresponding fitting portion 716 in the first direction D1. The dimension of the hole 617 of the positioning portion 615 of the second fixing portion 613b in the second direction D2 is larger than the dimension of the corresponding fitting portion 716 in the second direction D2. Therefore, the positioning portion 615 of the second fixing portion 613b is restricted from moving in the first direction D1 while the corresponding fitting portion 716 allows movement in the second direction D2. Restricting the movement of the positioning portion 615 of the second fixing portion 613b in the first direction D1 in this way restricts the rotation of the holding member 611 about the fitting portion 716 of the first fixing base 714a. .

The first mirror 61 further has three cushions 618 . Each cushion member 618 is made of foamed urethane resin and has elasticity. Note that each cushion material 618 may be a member having elasticity, and may be rubber or the like. The three cushion members 618 correspond to the three mounting portions 614 of the holding member 611 one-to-one. Each cushion material 618 is formed in a rectangular plate shape when viewed from the third direction D3. Each cushion material 618 uses a double-sided tape on the second member 72 side surface (the surface opposite to the first member 71) of both sides in the thickness direction of the installation portion 616 of the corresponding mounting portion 614. installed. Note that the means for attaching each cushion material 618 to the corresponding attachment portion 614 is not limited to the double-sided tape, and may be, for example, an adhesive.

As shown in FIG. 16 , the second member 72 of the housing 7 has three pressing portions 727 . The three pressing portions 727 correspond to the three mounting portions 614 of the first mirror 61 one-to-one, respectively, and also correspond to the three cushion members 618 of the first mirror 61, respectively. Each pressing portion 727 is a protrusion that is bent to protrude toward the first member 71 . Each pressing portion 727 presses the installation portion 616 of the corresponding mounting portion 614 to the first member 71 side in the third direction D3 via the corresponding cushion material 618 . Thus, each mounting portion 614 of the first mirror 61 is sandwiched and fixed between the corresponding pressing portion 727 and the corresponding base portion 715 via the corresponding cushion material 618 . That is, in this embodiment, the sandwiching structure 77 sandwiching the first mirror 61 is configured by the three holding portions 727 , the three cushion members 618 and the three mounting portions 614 .

As described above, in the first mirror 61 of this embodiment, the plurality of mounting portions 614 are sandwiched between the first member 71 and the second member 72 of the housing 7 . Therefore, the first mirror 61 can be fixed using the housing 7 . Moreover, in this case, the first mirror 61 can be fixed to the housing 7 without using an adhesive, so that the manufacturing time of the display system 1 can be shortened. Moreover, in the display system 1 of the present embodiment, the cushion material 618 is positioned between the mounting portion 614 and the second member 72 . Therefore, even if the housing 7 thermally expands, it is difficult for the force to be transmitted from the housing 7 to the mounting portions 614 , and the first mirror 61 may be deformed by the force applied from the housing 7 to the mounting portions 614 . Suppressed. Particularly in this case, deformation of the first mirror surface 610, which is important in the display system 1 that projects the virtual image 91 by irradiating the display light, can be suppressed.

Further, in the display system 1 of the present embodiment, the cushion material 618 is positioned only between the mounting portion 614 and the second member 72, and the installation portion 616 of each mounting portion 614 corresponds to the base portion of the first member 71. Direct contact with 715. Therefore, the first mirror 61 can be accurately positioned with respect to the first member 71 . Also, in the first mirror 61 of this embodiment, only three mounting portions 614 are sandwiched between the first member 71 and the second member 72 . Therefore, the first mirror 61 can be sandwiched only at three points where the three mounting portions 614 are located. That is, in this case, the first mirror 61 can be accurately positioned by sandwiching the first mirror 61 with only the minimum three points required to determine the plane.

Further, the positioning structure 76 of the present embodiment has a pair of fitting structures each composed of a hole 617 of the positioning portion 615 and a fitting portion 716 fitted into the hole 617 . One of the pair of fitting structures is fitted into the hole 617 with the fitting portion 716 positioned in both the first direction D1 and the second direction D2. The other of the pair of fitting structures is fitted into the hole 617 with the fitting portion 716 positioned only in the first direction D1 out of the first direction D1 and the second direction D2. The fitting portion 716 of the other fitting structure in the positioning structure 76 is positioned only in the first direction D1, so it is easy to fit into the hole 617 . Therefore, it is possible to easily position the first mirror 61 in the first direction D1 and the second direction D2. In this embodiment, the fitting portion 716 is formed in the first member 71 and the hole 617 is formed in the first mirror 61. However, the fitting portion 716 is formed in the first mirror 61 and the hole 617 may be formed in first member 71 .

Each cushion member 618 of the present embodiment is attached only to the second member 72 side surface of the both sides of the installation portion 616 in the thickness direction. may be attached only to the surface of the first member 71 side. That is, in this case, the cushion material 618 is positioned between the mounting portion 614 and the second member 72 . Further, each cushion member 618 may be attached to both sides of the installation portion 616 in the thickness direction. That is, in this case, the cushion material 618 is positioned between the attachment portion 614 and the first member 71 and between the attachment portion 614 and the second member 72 . Also, the cushion material 618 may be attached to the corresponding pressing portion 727 of the second member 72 instead of the first mirror 61 . Further, even if the cushion material 618 is omitted and the installation portion 616 of each installation portion 614 is sandwiched between the first member 71 and the second member 72 while being in contact with each of the first member 71 and the second member 72, good. In this case, the installation portion 616 of each attachment portion 614 is brought into contact with the first member 71 and the second member 72 so that the first mirror 61 can be accurately positioned.

(1.5) Method for Manufacturing Display System Next, a method for manufacturing the display system 1 will be described. The manufacturing method of the display system 1 includes a projection unit mounting process, a built-in component mounting process, and a housing assembly process. The projection unit attachment step is a step of attaching the projection unit 2 to the first member 71 of the housing 7, as shown in FIG. In the projection unit mounting process, the housing 4 of the projection unit 2 is fixed to the first member 71 by a plurality of fasteners 42 (see FIG. 2). Thereby, the projection unit 2 is attached to the first member 71 . In the projection unit 2, as described above, the elastic member 5 fixed to the housing 4 moves the first radiator 25, the diffusion plate 27, the heat transfer member 24, and the display 3 toward the elastic member 5 side. regulate things. Therefore, when the housing 4 is fixed to the first member 71, the first radiator 25, the diffusion plate 27, the heat transfer member 24 and the indicator 3 are difficult to get out of the tubular portion 40, and the housing 4 is attached to the first member 71. It becomes possible to easily fix to the member 71 . Also, the projection unit 2 before being attached to the housing 7 can be easily carried.

The built-in part mounting process is a process of mounting the first mirror 61, the second mirror 62, etc., which are the parts built into the housing 7 shown in FIG. Note that the built-in component mounting process may be performed after the projection unit mounting process, or may be performed before the projection unit mounting process. In order to attach the first mirror 61 to the first member 71 in the built-in component attaching step, the first mirror 61 and the first member 71 should be brought close to each other in the third direction D3. In this case, the first mirror 61 may be moved parallel to the third direction D3 to bring it closer to the first member 71, or the first member 71 may be moved parallel to the third direction D3 to move the first mirror 61 closer to the first member 71. can be close to By bringing the first mirror 61 and the first member 71 close to each other in the third direction D3 in this manner, the mounting portions 616 (see FIG. 15) of the mounting portions 614 of the first mirror 61 are aligned with the corresponding portions of the first member 71. It is installed on the installation surface 717 of the base portion 715 , and each fitting portion 716 of the first mirror 61 is fitted into the corresponding hole 617 of the positioning portion 615 . As a result, the first mirror 61 is attached to the first member 71 .

The housing assembly process is executed after the built-in component mounting process. The housing assembly step is a step of combining the first member 71 and the second member 72 and then fixing the second member 72 to the first member 71 using a plurality of fasteners 73 . Note that the housing assembly process may be performed after the projection unit mounting process, or may be performed before the projection unit mounting process. In order to combine the first member 71 and the second member 72 in the housing assembly process, the first member 71 and the second member 72 should be brought closer together in the third direction D3. In this case, the first member 71 may be moved parallel to the third direction D3 to approach the second member 72, or the second member 72 may be moved parallel to the third direction D3 to move the first member 71 close to the second member 72. can be close to By bringing the first member 71 and the second member 72 closer together in the third direction D3 in this way, the installation portions 616 of the mounting portions 614 of the first member 71 are moved by the corresponding pressing portions 727 of the second member 72. The corresponding cushion material 618 is pressed against the first member 71 side in the third direction D3, and the first member 71 and the second member 72 are combined.

(2) Modifications The display system 1 of the above embodiment can be modified as appropriate. For example, in the above embodiment, the light shielding member (first member 71 ) that defines the shape of the light emitted from the display surface 32 of the display 3 is positioned on the path of the light emitted from the display surface 32 . However, the light shielding member may define the shape of the light emitted from the display surface 32 , and may define the shape of the illumination light emitted from the light source 20 to the display 3 .

Moreover, the display device 3 is not limited to a liquid crystal display. The display device 3 may be an image display device other than a liquid crystal display, such as an organic electroluminescence display or a laser display. Also, the display device 3 may not be the image display device itself. For example, the display device 3 may be a system comprising a projector and a screen for projecting an image of the projector, or a system comprising a laser scanning device and a screen for projecting an image obtained by laser scanning of the laser scanning device. may be Further, the display device 3 may be a screen itself, or may be a plane mirror for projecting an image from an image display device. That is, the display device 3 may display an intermediate image. Also, the optical system 6 may have only one mirror, or may have three or more mirrors. Also, the display system 1 may not include the optical system 6 .

Also, the shape of each of the first member 71, the second member 72, and the cover 75, the shape of each member of the first mirror 61, the shape of the second mirror 62, and the shape of each member of the projection unit 2 can be changed. . Also, the material of each of the first member 71, the second member 72, and the cover 75, the material of each member of the first mirror 61, the material of the second mirror 62, and the material of each member of the projection unit 2 can be changed. . Also, each member of the display system 1 can be omitted as appropriate. For example, display system 1 may be projection unit 2 .

Further, the mobile device 8 equipped with the display system 1 may be an automobile having a driver's seat 81 and a steering wheel 82 on the left half of the mobile device main body 80 . Moreover, the display system 1 is not limited to a head-up display used in automobiles. For example, the display system 1 can be applied to mobile devices 8 other than automobiles, such as motorcycles, trains, aircraft, construction machines, and ships. The display system 1 may also be used, for example, in an amusement facility or the like.

(3) Aspects As is clear from the embodiments and modifications described above, the display system (1) of the first aspect has the following configuration. A display system (1) comprises a display (3) and a light blocking member. The display (3) has a display surface (32) for displaying an image. The light blocking member has an aperture (712) through which light emanating from the display surface (32) passes. The light blocking member defines the shape of light emitted from the display surface (32). The display surface (32) includes a non-rectangular display area (33) for displaying an image. The peripheral edge of the opening (712) has a shape that follows the peripheral shape of the display area (33).

According to this aspect, by defining the shape of the light emitted from the display surface (32) by the peripheral edge of the opening (712), the shape of the outer peripheral edge of the light emitted from the display surface (32) can be changed from the display area (33). It can have a shape that conforms to the shape of the outer periphery of the emitted light. Therefore, it is possible to project an image (91) that looks good and does not cause discomfort in the target space (93).

The display system (1) of the second aspect can be realized in combination with the first aspect. The display area (33) of the second aspect displays an image displayed as a virtual image (91) in the object space (93).

According to this aspect, it is possible to project a virtual image (91) that looks good and does not cause discomfort in the target space (93).

The display system (1) of the third aspect can be realized by combining with the first or second aspect. The peripheral edge of the opening (712) of the third aspect has a curved shape on at least one side.

According to this aspect, when the display area (33) has at least one curved side, it is possible to project an image (91) that looks good and does not cause discomfort in the target space (93).

The display system (1) of the fourth aspect can be realized by combining with any one of the first to third aspects. A fourth embodiment aperture (712) is positioned in the path of light emitted from the display surface (32).

According to this aspect, the shape of the light emitted from the display surface (32) is defined by the peripheral edge of the opening (712), and the image (91) that looks good and does not cause discomfort is projected onto the target space (93). be able to.

The display system (1) of the fifth aspect can be realized by combining with the fourth aspect. The light shielding member of the fifth aspect includes an inclined surface (713). The sloping surface (713) constitutes the periphery of the opening (712). The inclined surface (713) is inclined so that the portion closer to the display surface (32) is located outside or inside the opening (712).

According to this aspect, the amount of light emitted from the display surface (32) that is blocked by the periphery of the opening (712) is suppressed, and the display area (33) of the display surface (32) can be effectively used.

The display system (1) of the sixth aspect can be realized by combining with the fifth aspect. The inclined surface (713) of the sixth aspect is inclined so that the portion closer to the display surface (32) is located outside the opening (712).

According to this aspect, of the light emitted from the display surface (32), the light traveling in a direction inclined toward the inside of the optical axis is less likely to be blocked by the peripheral edge of the opening (712), and the display surface (32) ) is blocked by the perimeter of aperture (712).

The display system (1) of the seventh aspect can be realized by combining with any one of the first to sixth aspects. The display system (1) of the seventh aspect has the following configuration. The display system (1) further comprises an elastic member (5). The elastic member (5) is sandwiched between the light blocking member and the display surface (32).

According to this aspect, the elastic member (5) can soften shock and vibration transmitted from the light shielding member to the display surface (32).

The display system (1) of the eighth aspect can be realized by combining with any one of the first to seventh aspects. In the display system (1) of the eighth aspect, the peripheral shape of the opening (712) and the peripheral shape of the display area (33) are similar shapes.

According to this aspect, by defining the shape of the light emitted from the display surface (32) by the peripheral edge of the opening (712), the shape of the outer peripheral edge of the light emitted from the display surface (32) can be changed from the display area (33). It can have a shape similar to the outer peripheral shape of the emitted light. Therefore, an image (91) with a better appearance can be projected onto the target space (93).

The display system (1) of the ninth aspect can be realized by combining with any one of the first to eighth aspects. The aperture (712) of the ninth aspect is larger in size than the display area (33).

According to this aspect, even if there is an error in the size, mounting position, etc. of each member in the display system (1), the light emitted from the display area (33) is blocked by the peripheral edge of the opening (712) of the light shielding member. It becomes difficult to be beaten. Therefore, an image (91) with a better appearance can be projected onto the target space (93).

The display system (1) of the tenth aspect can be realized by combining with any one of the first to ninth aspects. The light shielding member of the tenth aspect is removable.

According to this aspect, the light shielding member can be removed from other members in the display system (1) and replaced with another light shielding member having a different shape of the opening (712). Therefore, for example, even when the display system (1) is installed in another device, it is possible to project a good-looking image (91) simply by exchanging the light shielding member.

The mobile device (8) of the eleventh aspect has the following configuration. A mobile device body (80) and a display system (1) according to any one of the first to tenth aspects. The display system (1) is mounted on a mobile device body (80).

According to this aspect, the display system (1) can be used in a mobile device (8).

The display system (1) of the twelfth aspect has the following configuration. The display system (1) comprises a display (3), a housing (4) and a radiator (25). The display (3) has a display surface (32) for displaying an image. A housing (4) contains a display (3). A radiator (25) dissipates heat generated in the display (3). The housing (4) covers the radiator (25) from at least one of the four sides of the radiator (25).

According to this aspect, the housing (4) covers the radiator (25) on at least one of its four sides. Therefore, it becomes difficult for dust and dirt to adhere to the radiator (25).

The display system (1) of the thirteenth aspect can be realized by combining with the twelfth aspect. The housing (4) of the thirteenth aspect covers the radiator (25) from three of the four sides of the radiator (25).

According to this aspect, it is even more difficult for dust and dirt to adhere to the radiator (25).

The display system (1) of the fourteenth aspect can be realized by combining with the twelfth or thirteenth aspect. The radiator (25) of the fourteenth aspect supports the display (3) from the side opposite to the display surface (32).

According to this aspect, the radiator (25) can restrict the movement of the display (3) to the side opposite to the display surface (32).

The display system (1) of the fifteenth aspect can be realized by combining with the fourteenth aspect. The display system (1) of the fifteenth aspect has the following configuration. The radiator (25) has a contact portion (250) and an extension portion (254). The contact portion (250) is in contact with the surface of the display (3) opposite to the display surface (32). The extension (254) connects to the contact (250). The extending portion (254) is located closer to the display surface (32) than the surface of the display (3) opposite to the display surface (32) and is located outside the housing (4). have.

According to this aspect, part of the extending portion (254) is located outside the housing (44) to improve the heat dissipation of the radiator (25).

The display system (1) of the sixteenth aspect can be realized by combining with any one of the twelfth to fifteenth aspects. The radiator (25) of the sixteenth aspect is plate-shaped.

According to this aspect, the radiator (25) can be easily manufactured from a plate-like member.

The display system (1) of the seventeenth aspect can be realized by combining with any one of the twelfth to sixteenth aspects. The housing (4) of the seventeenth aspect positions the indicator (3).

According to this aspect, the function of the radiator (25) for positioning the display (3) can be omitted, or the structure of the radiator (25) can be simplified. Therefore, the radiator (25) can be easily manufactured.

The display system (1) of the eighteenth aspect can be realized by combining with any one of the twelfth to seventeenth aspects. The eighteenth aspect has the following configuration. The display system (1) further comprises a light source (20) and a second radiator (26). A second radiator (26) is thermally connected to the light source (20). The display (3) is a liquid crystal panel that forms an image using light emitted from the light source (20). The display system (1) further comprises an insulating structure (100) located between the first radiator (25), which is the radiator (25), and the second radiator (26).

According to this aspect, the heat insulating structure (100) makes it difficult for the heat of the second radiator (26) to be conducted to the first radiator (25), thereby suppressing the deterioration of the heat radiation performance of the first radiator (25). be.

The display system (1) of the nineteenth aspect can be realized in combination with the eighteenth aspect. The heat insulation structure (100) of the nineteenth aspect has a heat insulation space (101).

According to this aspect, the heat insulation space (101) makes it difficult for the heat of the second radiator (26) to be conducted to the first radiator (25).

The display system (1) of the twentieth aspect can be realized in combination with the nineteenth aspect. The twentieth aspect has the following configuration. Each of the first radiator (25) and the second radiator (26) has a heat dissipation portion (255, 260) located outside the housing (4). The heat insulating space (101) is located outside the housing (4) between the heat radiating portion (255) of the first radiator (25) and the heat radiating portion (260) of the second radiator (26). there is

According to this aspect, the heat in the heat radiating portion (260) of the second radiator (26) is less likely to be transmitted to the heat radiating portion (255) of the first radiator (25) due to the heat insulating space (101). A decrease in the heat dissipation of the container (25) is suppressed.

The mobile device (8) of the twenty-first aspect has the following configuration. A mobile device body (80) and a display system (1) according to any one of the twelfth to twentieth aspects. The display system (1) is mounted on a mobile device body (80).

According to this aspect, the display system (1) can be used in a mobile device (8).

The display system (1) of the twenty-second aspect has the following configuration. A display system (1) comprises a display (3), an elastic member (5) and a light blocking member. The display (3) has a display surface (32) for displaying an image. The light blocking member has an aperture (712) through which light emitted from the display surface (32) passes. The light shielding member defines the shape of light emitted from the display surface (32). The light shielding member has an elastic member (5) sandwiched between it and the display (3). The indicator (3) presses the elastic member (5) against the light blocking member.

According to this aspect, the elastic member (5) is fixed by pressing the elastic member (5) against the light shielding member by the display (3). Therefore, the number of parts of the display system (1) can be reduced compared to the case where the elastic member (5) is pressed against a member other than the light shielding member. Also, the distance from the indicator (3) to the light shielding member can be shortened. Therefore, the amount of light emitted from the display surface (32) that is blocked by the light shielding member is suppressed, and the display surface (32) can be effectively used.

The display system (1) of the twenty-third aspect can be realized by combining with the twenty-second aspect. The twenty-third aspect has the following configuration. The display system (1) further comprises a housing (4) holding the display (3). The housing (4) presses the elastic member (5) against the light blocking member.

According to this aspect, the elastic member (5) can be fixed more firmly by pressing the elastic member (5) against the light shielding member by the housing (4).

The display system (1) of the twenty-fourth aspect can be realized in combination with the twenty-third aspect. The twenty-fourth aspect has the following configuration. The indicator (3) presses the first portion surrounding the portion corresponding to the opening (712) in the elastic member (5) against the light shielding member. The housing (4) presses the second portion surrounding the first portion in the elastic member (5) against the light blocking member.

According to this aspect, the first portion and the second portion of the elastic member (5) are pressed against the light shielding member by the display (3) and the housing (4). Therefore, it becomes difficult for dust, dirt, etc. to enter the inside of the housing (4) from between the housing (4) and the light shielding member.

The display system (1) of the twenty-fifth aspect can be realized by combining with the twenty-third or twenty-fourth aspects. The twenty-fifth aspect has the following configuration. The elastic member (5) is fixed relative to the housing (4). The indicator (3) is fixed to the housing (4) by an elastic member (5).

According to this aspect, the indicator (3) is fixed by the elastic member (5) fixed to the housing (4). Therefore, the number of parts of the display system (1) can be reduced compared to the case where a member for fixing the display (3) is provided separately.

The display system (1) of the twenty-sixth aspect can be realized by combining with any one of the twenty-second to twenty-fifth aspects. The twenty-sixth aspect has the following configuration. The display system (1) further comprises an optical system (6) and a housing (7). The optical system (6) irradiates a predetermined position with light emitted from the display surface (32). A housing (7) holds an optical system (6). The light shielding member is part of the housing (7).

According to this aspect, the light shielding member can be configured by a part of the housing (7) that holds the optical system (6).

The display system (1) of the twenty-seventh aspect can be realized by combining with any one of the twenty-second to twenty-sixth aspects. The twenty-seventh aspect has the following configuration. The elastic member (5) has a window hole (54) corresponding to the opening (712). The peripheral edge of the window hole (54) is located outside the peripheral edge of the opening (712).

According to this aspect, light emitted from the display surface (32) can be guided to the opening (712) through the window hole (54) of the elastic member (5).

The display system (1) of the 28th aspect can be realized by combining with any one of the 22nd to 27th aspects. The twenty-eighth aspect has the following configuration. The display system (1) further comprises a temperature sensor (28). A temperature sensor (28) is located on the surface of the display (3) facing the elastic member (5) and detects the temperature of the display (3). A sensor hole (53) is formed in a portion of the elastic member (5) corresponding to the temperature sensor (28).

According to this aspect, even if force is applied to the elastic member (5) from the light shielding member or the like, this force is less likely to be applied to the temperature sensor (28) via the elastic member (5). Therefore, malfunction of the temperature sensor (28) is less likely to occur.

The display system (1) of the 29th aspect can be realized by combining with any one of the 22nd to 28th aspects. The twenty-ninth aspect has the following configuration. The light shielding member has a plurality of guide surfaces. Each of the plurality of guide surfaces is a plane along the surface of the elastic member (5) opposite to the indicator (3).

According to this aspect, the elastic member (5) can slide along the plurality of guide surfaces of the light shielding member. Therefore, the elastic member (5) can be easily arranged between the light shielding member and the display (3).

Further, the mobile device (8) of the thirtieth aspect has the following configuration. A mobile device body (80) and a display system (1) according to any one of the 22nd to 29th aspects. The display system (1) is mounted on a mobile device body (80).

According to this aspect, the display system (1) can be used in a mobile device (8).

The display system (1) of the thirty-first aspect has the following configuration. The display system (1) has a display (3), a mirror (61) and a housing (7). The mirror (61) has a specular surface (610) that reflects the light emitted from the display (3). A housing (7) accommodates a mirror (61). The mirror (61) further has a mounting portion (614). The housing (7) has a first member (71) and a second member (72). The second member (72) is fixed to the first member (71) and sandwiches the mounting portion (614) with the first member (71).

According to this aspect, the mirror (61) can be fixed using the housing (7).

The display system (1) of the thirty-second aspect can be realized by combining with the thirty-first aspect. The thirty-second aspect has the following configuration. The mirror (61) has a resin holding member (611) that holds the mirror surface (610). The mounting portion (614) is formed on the holding member (611).

According to this aspect, the mirror (61) having the resin-made holding member (611) holding the mirror surface (610) can be fixed to the housing (7).

The display system (1) of the 33rd aspect can be realized by combining with the 31st or 32nd aspects. The thirty-third aspect has the following configuration. A cushion material (618) is positioned between at least one of the mounting portion (614) and the first member (71) and between the mounting portion (614) and the second member (72).

According to this aspect, an elastic cushion material (618) is positioned between the mounting portion (614) and the first member (71) or between the mounting portion (614) and the second member (72). . For this reason, force is less likely to be transmitted from the housing (7) to the mounting portion (614), and deformation of the mirror surface (610) due to the force applied from the housing (7) to the mounting portion (614) is suppressed.

The display system (1) of the thirty-fourth aspect can be realized in combination with the thirty-third aspect. The cushion material (618) of the thirty-fourth aspect is located only between the mounting portion (614) and the first member (71) and between the mounting portion (614) and the second member (72). are doing.

According to this aspect, the portion of the attachment portion (614) opposite to the cushion material (618) is brought into contact with the first member (71) or the second member (72) to position the mirror (61) with high accuracy. be able to.

The display system (1) of the thirty-fifth aspect can be realized in combination with the thirty-first or thirty-second aspects. The attachment portion (614) of the thirty-fifth aspect is sandwiched between the first member (71) and the second member (72) while being in contact with each of the first member (71) and the second member (72). there is

According to this aspect, the mounting portion (614) can be brought into contact with the first member (71) and the second member (72) to accurately position the mirror (61).

The display system (1) of the thirty-sixth aspect can be realized by combining with any one of the thirty-first to thirty-fifth aspects. The thirty-sixth aspect has the following configuration. The mirror (61) has, as mounting portions (614), three mounting portions (614) positioned apart from each other. The mirror (61) has only three mounting portions (614) sandwiched between the first member (71) and the second member (72).

According to this aspect, the mirror (61) can be sandwiched by only the points where the three mounting portions (614) are located, that is, the minimum required three points for determining the plane, and the mirror (61) can be accurately mounted. can be positioned well.

The display system (1) of the thirty-seventh aspect can be realized by combining with any one of the thirty-first to thirty-sixth aspects. The mounting portion (614) of the thirty-seventh aspect is a protrusion formed on the mirror (61).

According to this aspect, the area of the portion sandwiched between the first member (71) and the second member (72) in the mounting portion (614) can be reduced, and the mirror (61) can be positioned with high accuracy. can.

The display system (1) of the thirty-eighth aspect can be realized by combining with any one of the thirty-first to thirty-seventh aspects. The thirty-eighth aspect has the following configuration. The housing (7) has a positioning structure (76). The positioning structure (76) positions the mirror (61) in a direction intersecting the sandwiching direction in which the mounting portion (614) is sandwiched between the first member (71) and the second member (72).

According to this aspect, the positioning structure (76) allows positioning of the mirror (61) in the direction crossing the pinching direction.

The display system (1) of the thirty-ninth aspect can be realized in combination with the thirty-eighth aspect. The positioning structure (76) of the thirty-ninth aspect is arranged to move the mirror (61) in a first direction (D1) perpendicular to the pinching direction and a second direction perpendicular to the pinching direction and perpendicular to the first direction (D1). (D2) and both directions.

According to this aspect, the positioning structure (76) allows the mirror (61) to move in a first direction (D1) perpendicular to the pinching direction and a second direction perpendicular to the pinching direction and perpendicular to the first direction (D1). (D2) can be positioned in both directions.

The display system (1) of the 40th aspect can be realized in combination with the 39th aspect. The fortieth aspect has the following configuration. The locating structure (76) has a pair of mating structures. Each of the pair of fitting structures has a hole (617) formed in one of the first member (71) and the mirror (61) and a fitting fitted in the hole (617) formed in the other. (716). One of the pair of fitting structures fits into the hole (617) with the fitting portion (716) positioned in both the first direction (D1) and the second direction (D2). I'm in. The other of the pair of inset structures is positioned in the hole (716) only in a first direction (D1) of the first direction (D1) and the second direction (D2). 617).

According to this aspect, the fitting portion (716) of the other fitting structure in the positioning structure (76) is positioned only in the first direction (D1), so it is easy to fit into the hole (617). Therefore, it is possible to easily position the mirror (61) in the first direction (D1) and the second direction (D2).

The mobile device (8) of the forty-first aspect has the following configuration. A moving device body (80) and a display system (1) according to any one of the 31st to 40th aspects. The display system (1) is mounted on a mobile device body (80).

According to this aspect, the display system (1) can be used in a mobile device (8).

REFERENCE SIGNS LIST 1 display system 28 temperature sensor 3 display device 32 display surface 4 housing 5 elastic member 53 sensor hole 54 window hole 6 optical system 7 housing 71 first member (light shielding member)
712 opening 8 moving device 80 moving device body

Claims (7)

a display device having a display surface for displaying an image;
an elastic member;
a light shielding member having an opening through which light emitted from the display surface passes, defining a shape of the light emitted from the display surface, and sandwiching the elastic member between the light shielding member and the display ;
a housing that holds the indicator ;
The indicator presses a first portion surrounding a portion corresponding to the opening in the elastic member against the light shielding member ;
wherein the housing presses a second portion surrounding the first portion of the elastic member against the light shielding member ;
display system. a display device having a display surface for displaying an image;
an elastic member;
a light shielding member having an opening through which light emitted from the display surface passes, defining a shape of the light emitted from the display surface, and sandwiching the elastic member between the light shielding member and the display;
a housing that holds the indicator;
The indicator presses the elastic member against the light shielding member,
the housing presses the elastic member against the light shielding member;
The elastic member is fixed with respect to the housing,
The indicator is fixed to the housing by the elastic member.
display system. a display device having a display surface for displaying an image;
an elastic member;
a light shielding member having an opening through which light emitted from the display surface passes, defining a shape of the light emitted from the display surface, and sandwiching the elastic member between the light shielding member and the display;
an optical system for irradiating a predetermined position with light emitted from the display surface;
A housing holding the optical system,
The indicator presses the elastic member against the light shielding member,
The light shielding member is a part of the housing,
display system. a display device having a display surface for displaying an image;
an elastic member;
a light shielding member having an opening through which light emitted from the display surface passes, defining a shape of the light emitted from the display surface, and sandwiching the elastic member between the light shielding member and the display;
a temperature sensor located on a surface of the display facing the elastic member and detecting a temperature of the display;
The indicator presses the elastic member against the light shielding member,
a sensor hole is formed in a portion of the elastic member corresponding to the temperature sensor;
display system. a display device having a display surface for displaying an image;
an elastic member;
a light shielding member having an opening through which light emitted from the display surface passes, defining a shape of the light emitted from the display surface, and sandwiching the elastic member between the light shielding member and the display;
The indicator presses the elastic member against the light shielding member,
The light shielding member is
having multiple guide surfaces,
each of the plurality of guide surfaces is a plane along a surface of the elastic member opposite to the indicator;
display system. The elastic member is
having a window hole corresponding to the opening;
The peripheral edge of the window hole is located outside the peripheral edge of the opening,
The display system according to any one of claims 1-5. a mobile device body;
A display system according to any one of claims 1 to 6 mounted on the mobile device main body,
mobile device.

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