JP2020087626A - Display formation device - Google Patents

Abstract

To eliminate a need to provide adhesiveness to a heat transmission sheet in a structure in which a heat radiation portion, such as a heat sink, is formed as a part of a case.SOLUTION: A display formation device includes: a housing including a heat radiation portion; a substrate on which a light source is mounted; a lens member which transmits light emitted from the light source; a holding member which is supported by the housing and holds the lens member; a plate spring member fixed to the holding member and having a first portion which biases the lens member to the substrate; and a heat transmission sheet sandwiched between the heat radiation portion and the substrate. The plate spring member further has a second portion which biases the heat transmission sheet to the substrate. The display formation device is disclosed.SELECTED DRAWING: Figure 12

Description

The present disclosure relates to a display forming device.

A lighting device for a display forming device is known in which a substrate on which a light source is mounted is thermally connected to a heat sink via a heat conductive sheet.

JP, 2017-126468, A

In the prior art as described above, the heat sink forms a part of the lighting device and is separate from the case in which the lighting device is housed. Therefore, the lighting device is in a state where the heat conductive sheet is assembled (the substrate and the heat sink). It can be assembled to the case in a state of being gripped between and.

However, in a configuration in which a heat dissipation part such as a heat sink is formed as a part of the case, before the lighting device (the lighting device that does not include the heat dissipation part) is assembled to the case, heat transfer between the heat dissipation part of the case and the substrate is performed. Cannot hold the sheet. Therefore, it becomes necessary to attach the lighting device (the lighting device that does not include the heat dissipation part) to the case in a state where the heat conductive sheet is made to have adhesiveness and is attached to the heat dissipation part or the substrate. Use of such a heat conductive sheet having adhesiveness is disadvantageous in terms of cost and the like.

Therefore, in one aspect, the present invention has an object to eliminate the need to impart adhesiveness to a heat conductive sheet in a configuration in which a heat dissipation portion such as a heat sink is formed as a part of the case.

In one aspect, a housing including a heat dissipation part,
A substrate on which the light source is mounted,
A lens member through which the light emitted from the light source is transmitted,
A holding member that is supported by the housing and holds the lens member;
A leaf spring member fixed to the holding member and having a first portion for urging the lens member toward the substrate;
A heat conductive sheet sandwiched between the heat dissipation portion and the substrate;
The display forming apparatus is provided in which the leaf spring member further includes a second portion that urges the heat conductive sheet toward the substrate.

In one aspect, according to the present invention, it is possible to eliminate the need to impart adhesiveness to the heat conductive sheet in a configuration in which a heat dissipation portion such as a heat sink is formed as a part of the case.

FIG. 3 is a perspective view showing the internal configuration of the display forming apparatus according to an embodiment from the upper side. It is a figure which shows roughly the vehicle mounting state of a display formation apparatus by vehicle side view. FIG. 3 is a perspective view of the TFT panel unit in a single item state. It is an exploded perspective view of a TFT panel unit. It is a perspective view of a single unit of the backlight unit. It is an exploded perspective view of a backlight unit. It is a top view which shows the state with which the backlight unit was attached to the case. FIG. 7 is a cross-sectional view taken along the line AA of FIG. 6. FIG. 7 is a schematic cross-sectional view taken along the line BB of FIG. 6. It is explanatory drawing of the force generated by screw tightening. It is a perspective view for explaining a method of assembling the backlight unit to the case. It is explanatory drawing of the structure of the back surface side (Y direction negative side) of a backlight unit. FIG. 12 is a partial cross-sectional perspective view taken along the XY plane including the line CC of FIG. 11. It is a perspective view of a second lens spring in a single item state. It is explanatory drawing of the assembling method of a board|substrate. It is explanatory drawing of the assembly method of a heat conductive sheet.

Hereinafter, each embodiment will be described in detail with reference to the accompanying drawings. Note that, in FIG. 1A and the like, for ease of viewing, a plurality of parts having the same attribute may be given only some reference signs.

[Configuration of display forming device]
FIG. 1A is a perspective view showing the internal configuration of a display forming apparatus 1 according to an embodiment from the upper side. FIG. 1B is a diagram schematically showing a state where the display forming apparatus 1 is mounted on a vehicle as seen from the side of the vehicle. Note that in FIG. 1A, illustration of some of the components of the display forming apparatus 1 is omitted. In FIG. 1A, the X direction, the Y direction, and the Z direction that are three directions orthogonal to each other are defined in the right-handed system. In the following, the Z direction is the vertical direction, the positive side is the upper side, and the negative side is the lower side.

The display forming device 1 is for a head-up display, and is mounted in an instrument panel 9 of a vehicle. The display forming apparatus 1 may be mounted so that the Y direction in FIG. 1A substantially corresponds to the vehicle width direction.

The display forming apparatus 1 includes a case 2, a TFT (Thin Film Transistor) panel unit 3 (an example of an image forming unit), mirrors 4 and 5, and a backlight unit 6.

The case 2 forms a housing of the display forming device 1. The case 2 is a lower case that forms a lower portion of the housing of the display forming apparatus 1. The case 2 is combined with an upper case (not shown in FIG. 1A).

The case 2 is formed of a material having high heat conductivity such as aluminum. The case 2 includes a heat dissipation portion 21 as shown in FIG. 1A. The heat dissipation portion 21 is formed on the outer surface (the surface exposed to the outside) of the case 2. The heat radiating portion 21 has a function of radiating the heat generated from the backlight unit 6. The heat dissipation part 21 radiates heat to the air flowing outside the case 2.

The heat dissipation part 21 is formed integrally with the case 2. For example, the heat dissipation part 21 may be formed by casting together with the case 2. However, the heat dissipation portion 21 may be formed separately from the case 2 and integrated with the case 2.

The heat dissipation part 21 is in the form of a fin. The fins may have any shape, and may have a cylindrical shape or a straight fin shape as shown in FIG. 1A. Note that in FIG. 1A, the heat dissipation portion 21 is formed in such a manner that the straight fins extending in the vertical direction are arranged in the X direction.

The TFT panel unit 3 is a display device that uses the light from the backlight unit 6 as a backlight and emits image light according to a display image. The display image is arbitrary and may be, for example, an image representing navigation information, various vehicle information, or the like.

The TFT panel unit 3 is fixed to the case 2. For example, as shown in FIG. 1A, the TFT panel unit 3 is fastened with screws 90 at two positions on both sides in the X direction.

FIG. 2 is a perspective view of the TFT panel unit 3 in a single product state, and FIG. 3 is an exploded perspective view of the TFT panel unit 3.

The TFT panel unit 3 includes a TFT holder 31, a TFT panel 32, a diffusion sheet 33, and a TFT cover 34. The TFT holder 31 is fixed to the case 2 as described above. The TFT holder 31 holds the TFT panel 32. The TFT panel 32 is a dot matrix type TFT (Thin Film Transistor) panel or the like. The TFT panel 32 is provided so that the long side direction corresponds to the X direction. The TFT cover 34 is fitted and coupled to the TFT holder 31. The TFT panel 32 and the diffusion sheet 33 are held between the TFT cover 34 and the TFT holder 31 in the Y direction.

The mirrors 4 and 5 reflect the image light emitted from the TFT panel unit 3 and direct it toward the windshield glass WS (see FIG. 1B) of the vehicle. In this embodiment, two mirrors 4 and 5 are provided, but the number of mirrors is arbitrary. In the present embodiment, as an example, the mirror 4 is a plane mirror and the mirror 5 is a concave mirror. The mirror 5 may be rotatably supported with respect to the case 2 so that the vertical position of the region of the windshield glass WS on which the image light strikes can be adjusted.

When the windshield glass WS is irradiated with image light, as shown in FIG. 1B, a driver driving a vehicle displays a display image (virtual image) obtained by the irradiation in front of the windshield glass WS. Display) can be seen. As a result, the driver can visually recognize the display image by superimposing it on the front landscape, and can grasp the vehicle information and the like in a mode in which the line of sight does not move, thereby improving convenience and safety.

The backlight unit 6 is provided behind the TFT panel unit 3 (on the negative side in the Y direction). The backlight unit 6 cooperates with the TFT panel unit 3 to generate image light. The backlight unit 6 is fixed to the case 2.

FIG. 4 is a perspective view of the backlight unit 6 in a single product state, and FIG. 5 is an exploded perspective view of the backlight unit 6.

The backlight unit 6 has a function of emitting light from the light source 8 to the TFT panel unit 3 and transmitting heat generated by the light source 8 to the heat dissipation portion 21.

The backlight unit 6 includes a lens cover 61, a first lens spring 62, a condenser lens 63, a diffusion plate 64, a lens holder 65 (an example of a holding member), and a second lens spring 66 (of a leaf spring member). An example), a lens array 67 (an example of a lens member), a substrate 68, and a heat conductive sheet 69.

The lens cover 61 covers the front surface (the positive side in the Y direction) of the backlight unit 6. The lens cover 61 has an opening 611 through which the condenser lens 63 is exposed. The lens cover 61 is fitted and coupled to the lens holder 65. In the present embodiment, as an example, the lens cover 61 has claw portions 612 extending in the Y direction negative side at four corners, and the claw portions 612 are fitted and coupled to the lens holder 65.

The first lens spring 62 is in the form of a leaf spring and is provided between the lens cover 61 and the condenser lens 63 in the Y direction. The first lens springs 62 are provided as a pair in the vertical direction. Each of the first lens springs 62 is fixed to the upper and lower side surfaces of the lens cover 61. Each of the first lens springs 62 biases the condenser lens 63 together with the diffusion plate 64 toward the lens holder 65. As described above, the first lens spring 62 has a function of defining the positions of the condenser lens 63 and the diffusion plate 64 with respect to the lens holder 65 in the Y direction.

The diffusion plate 64 and the condenser lens 63 diffuse and condense the light from the light source 8 that is incident through the lens array 67 onto the front surface (the positive side in the Y direction) of the backlight unit 6. Has the function of emitting light. The diffusion plate 64 is formed of, for example, a resin material having a light-transmitting property, and has a plate shape in which at least one surface is subjected to fine uneven processing.

The diffusion plate 64 and the condenser lens 63 are held on the positive side in the Y direction of the lens holder 65. For example, the diffusion plate 64 and the condenser lens 63 each have through holes 641 and 631 through which the pin portion 650 of the lens holder 65 passes, and the positions in the Z direction and the X direction with respect to the lens holder 65 are defined.

The lens holder 65 holds the diffusion plate 64 and the condenser lens 63, and also holds the lens array 67. The lens holder 65 is fixed to the case 2. The backlight unit 6 is fixed to the case 2 by fixing the lens holder 65 to the case 2. A preferred example of a method for fixing the backlight unit 6 (lens holder 65) to the case 2 will be described later.

The second lens spring 66 is in the form of a leaf spring and is fixed to the lens holder 65. The second lens spring 66 has a function of urging the lens array 67 toward the substrate 68. In addition, in the present embodiment, the second lens spring 66 further has a function of urging the heat conductive sheet 69 toward the substrate 68 (hereinafter, also referred to as “heat conductive sheet holding function”). Details of the configuration of the second lens spring 66 and details of the heat conductive sheet holding function of the second lens spring 66 will be described later.

The lens array 67 is made of a translucent resin material, and is arranged so as to cover the positive side of the substrate 68 in the Y direction. The lens array 67 includes a collimator portion 671 having a conical convex outer peripheral surface obtained by rotating a substantially parabolic wire. The lens array 67 is located opposite to the light source 8 mounted on the substrate 68, and transmits the light emitted from the light source 8 to the positive side in the Y direction. The outer shape of the lens array 67 is substantially the same as the outer shape of the TFT panel unit 3 (and the TFT panel 32) (rectangular shape whose long side is in the X direction).

The substrate 68 is provided behind the lens array 67 (on the negative side in the Y direction). The light source 8 is mounted on the surface of the substrate 68 facing the lens array 67. The light source 8 is an LED (Light Emitting Diode). The arrangement method and the number of the light sources 8 are arbitrary. The light source 8 is provided so that the optical axis direction is perpendicular to the substrate 68. In this embodiment, the optical axis direction is the Y direction. The substrate 68 may be a glass epoxy substrate, a glass composite substrate, or the like. The substrate 68 may be positioned by the lens array 67 by being positioned by the lens holder 65.

The heat conductive sheet 69 is a sheet-shaped member having heat conductivity. The heat conductive sheet 69 may be formed of a thermal sheet, a TIM (Thermal Interface Material) or the like. The heat conductive sheet 69 may have a characteristic that the higher the pressure in the thickness direction, the smaller the thermal resistance. Note that this characteristic may be linear or non-linear.

The heat conductive sheet 69 is sandwiched between the case 2 and the substrate 68 in the Y direction. In particular, the heat conductive sheet 69 is sandwiched on the side of the case 2 so as to come into contact with the surface 2a (FIG. 10) of the case 2.

The heat transfer sheet 69 does not have adhesiveness on the surface. That is, the heat conductive sheet 69 does not have an adhesive layer on the surface. Therefore, the heat-transfer sheet 69 comes into contact (surface contact) with the other member (in this embodiment, the substrate 68 and the case 2) that comes into surface contact without being bonded. In addition, generally, the heat conductive sheet 69 having no adhesive layer is less expensive than the heat conductive sheet having an adhesive layer.

[How to fix the backlight unit (lens holder) to the case]
Next, with reference to FIGS. 6 to 10, a preferable example of a method for fixing the backlight unit 6 (lens holder 65) to the case 2 and a heat dissipation principle of the backlight unit 6 according to the present embodiment will be described.

6 is a top view showing a state where the backlight unit 6 is assembled to the case 2, FIG. 7 is a cross-sectional view taken along line AA of FIG. 6, and FIG. 8 is a line of FIG. It is a typical sectional view along BB. FIG. 9 is an explanatory diagram of a force generated by screw tightening. FIG. 10 is a perspective view for explaining a method of assembling the backlight unit 6 to the case 2.

As shown in FIG. 10, the backlight unit 6 is provided so as to be adjacent to the heat dissipation portion 21 of the case 2 in the Y direction. In this embodiment, as an example, in the case 2, the surface 2a of the heat dissipation portion 21 on the Y direction positive side projects to the Y direction positive side. The surface 2a of the heat dissipation portion 21 is a surface with which the heat conductive sheet 69 is in surface contact. In addition, in the present embodiment, as an example, the case 2 has the recesses 2b on both sides of the heat dissipation portion 21 in the X direction. The recess 2b receives a second biasing portion 663 of the second lens spring 66, which will be described later.

As shown in FIG. 10, the backlight unit 6 is fixed to the case 2 at two places with screws 94. The screw 94 is tightened in the direction in which it goes up and down. In this case, it is easier to secure the work area and the workability of tightening the screw 94 is significantly improved, as compared with the case where the work area is tightened in a direction that advances in the XY plane.

Specifically, the case 2 has first screw receiving portions 70 (an example of a first mounting portion) on both sides of the mounting space of the backlight unit 6 in the X direction, and the lens holder 65 of the backlight unit 6 is The first screw fastening portion 651 (an example of a second mounting portion) is provided on both sides in the X direction, and the first screw fastening portion 651 is fastened to the first screw receiving portion 70 by the screw 94.

The first screw fastening portion 651 has a seat portion 6511 that receives the lower surface of the head of the screw 94. The seat portion 6511 includes a notch 6512 that is open on the Y direction positive side. Therefore, the lens holder 65 can be displaced to the negative side in the Y direction with respect to the screw 94 until it is completely fastened.

As shown in FIG. 8, the first screw receiving portion 70, when viewed in the X direction (the long side direction of the lens array 67), faces the negative side in the Y direction (=the optical axis direction of the light source 8) toward the lower side. The surface 72 inclines in a manner (close to the heat dissipation portion 21). That is, when viewed from the Y direction positive side, the upper surface of the first screw receiving portion 70 is inclined downward. The inclination angle is arbitrary, but is, for example, about 45 degrees.

As shown in FIG. 8, the first screw fastening portion 651 has a lower surface 6513 along the surface 72 of the first screw receiving portion 70. Therefore, the lower surface 6513 is inclined downward when viewed from the Y direction positive side. Therefore, the first screw fastening portion 651 can be displaced along the surface with respect to the first screw receiving portion 70 until the lens holder 65 is completely fastened to the case 2 by the screw 94.

Therefore, as schematically shown in FIG. 9, when the screws 94 are fastened, the force F1 due to the screw tightening is a component (component force) Fy in the Y direction facing the negative side and a downward component (component force) Fz. Occurs in a manner that includes and. At this time, the component force Fy acts so as to displace the lens holder 65 with respect to the case 2 to the Y direction negative side. That is, when the tightening torque becomes relatively large during screw tightening, the lens holder 65 is displaced in the Y direction negative side with respect to the case 2 and obliquely downward.

In this way, in this embodiment, when the lens holder 65 is fastened to the case 2 with the screw 94, the lens holder 65 can be displaced to the negative side in the Y direction by a slight amount with respect to the case 2. The displacement of the lens holder 65 to the negative side in the Y direction with respect to the case 2 at the time of such fastening has a function of appropriately compressing the heat conductive sheet 69 between the substrate 68 and the heat dissipation portion 21 of the case 2.

In this embodiment, the substrate 68 is provided so that the force in the Y direction is transmitted between the substrate 68 and the lens holder 65. Specifically, as shown in FIG. 7, the lens holder 65 has a portion 654 that abuts on the substrate 68 in the Y direction (hereinafter, also referred to as “abutting portion 654”). In this case, the substrate 68 and the lens holder 65 have a relationship in which the force in the Y direction is transmitted via the contact portion 654. The contact portions 654 may be provided at a plurality of positions on the substrate 68 so that the heat conductive sheet 69 is uniformly compressed in the plane. As a result, when the lens holder 65 is displaced to the Y direction negative side, the Y direction gap between the substrate 68 and the heat dissipation portion 21 of the case 2 (that is, the thickness of the heat conductive sheet 69) is reduced. In the modification, the lens holder 65 may not have the contact portion 654, and the lens array 67 may have the similar contact portion 654. Also in this case, the substrate 68 is in a relationship in which the force in the Y direction is transmitted between the substrate 68 and the lens holder 65 via the lens array 67 and the second lens spring 66. Therefore, also in this case, when the lens holder 65 is displaced to the negative side in the Y direction, the gap in the Y direction between the substrate 68 and the heat dissipation portion 21 of the case 2 via the lens array 67 (that is, the thickness of the heat conductive sheet 69). Is reduced.

Here, as shown in FIG. 7, a heat conductive sheet 69 is interposed between the substrate 68 and the heat dissipation portion 21 of the case 2. Therefore, the heat of the substrate 68 (heat generated by the light source 8) is transferred to the heat dissipation portion 21 via the heat transfer sheet 69 and is emitted to the outside. In order to properly establish such a heat transfer path, it is useful that the heat conductive sheet 69 is in surface contact with both the substrate 68 and the heat dissipation portion 21 of the case 2 over the entire surface. Is usefully compressed in the Y direction.

Further, in the present embodiment, as described above, when the lens holder 65 is fastened to the case 2 with the screw 94, the lens holder 65 is displaced to the negative side in the Y direction with respect to the case 2 by a slight amount. The gap in the Y direction between the substrate 68 and the heat dissipation portion 21 of the case 2 (that is, the thickness of the heat conductive sheet 69) can be reduced by the reduction amount corresponding to the displacement via the lens array 67. Thereby, the heat conductive sheet 69 between the substrate 68 and the heat dissipation portion 21 of the case 2 can be appropriately compressed.

In this way, in this embodiment, when the lens holder 65 is fastened to the case 2 with the screw 94, even if the screw 94 is fastened downward, the board 68 and the heat dissipation portion 21 of the case 2 are fastened. The heat conductive sheet 69 between them can be appropriately compressed. That is, when the lens holder 65 is fastened to the case 2 with screws, the heat conductive sheet between the substrate 68 and the heat dissipation portion 21 of the case 2 does not have to be tightened in the direction of moving to the negative side in the Y direction. 69 can be properly compressed. As a result, in the present embodiment, when the lens holder 65 is fastened to the case 2, it is possible to eliminate the screw that is fastened in the direction toward the negative side in the Y direction, so that the number of screws can be reduced and the work at the time of fastening You can improve your sex. Regarding workability, if the screw is tightened in the direction of moving to the Y direction negative side, workability is not good from the viewpoint of work space. When the screws 94 are fastened in the direction of moving downward, the workability is good because the space above the lens holder 65 is an open space.

By the way, if the screw 94 is tightened excessively, the gap in the Y direction between the substrate 68 and the heat dissipation portion 21 of the case 2 (that is, the thickness of the heat conductive sheet 69) may be excessively reduced. It is desirable to provide a stopper mechanism that mechanically prevents such excessive tightening.

The stopper mechanism is arbitrary as long as it is a mechanism capable of restricting excessive displacement (displacement exceeding the upper limit value) of the lens holder 65 toward the negative side in the Y direction with respect to the case 2.

In this embodiment, as an example, the case 2 has the second screw receiving portions 74 on both sides of the mounting space of the backlight unit 6 in the X direction, and the lens holder 65 of the backlight unit 6 has a center in the X direction. The screw passage 652 is provided on the upper side and on the negative side in the Y direction. The screw passing portion 652 is formed at a position corresponding to the second screw receiving portion 74. The first screw receiving portion 70 and the second screw receiving portion 74 have screw holes for receiving the screws 95. The screw passage portion 652 is in the form of a notch that is open on the Y direction negative side, and allows the shaft portion of the screw 95 to pass therethrough. The positional relationship in the Y direction between the screw passing portion 652 and the second screw receiving portion 74 is adapted so that the stopper mechanism described above functions properly. Specifically, when the tightening amount of the screw 94 is increased and the lens holder 65 is displaced in the Y direction negative side with respect to the case 2, the screw passage portion 652 of the lens holder 65 is moved to the Y direction with respect to the shaft portion of the screw 95. Abut in the direction. When the screw passage portion 652 of the lens holder 65 comes into contact with the shaft portion of the screw 95 in the Y direction, the lens holder 65 is less likely to be displaced in the Y direction negative side with respect to the case 2. Will work.

In a modification, a stopper mechanism may be separately provided, and the lens holder 65 may be fastened to the case 2 at a position corresponding to the second screw receiving portion 74. Even in this case, although the number of screws as the fastening members is three, the screws to be fastened in the direction toward the negative side in the Y direction can be eliminated, so that workability at the time of fastening can be improved.

Further, in another modification, as the other stopper mechanism, the above-mentioned abutting portion 654, a protrusion for positioning which may be provided on the back surface (surface on the negative side in the Y direction) of the lens holder 65, or the like is used as the stopper mechanism. May function as.

[Details of Second Lens Spring Configuration and Heat Transfer Sheet Holding Function]
Next, the configuration of the second lens spring 66 and the function of holding the heat conductive sheet by the second lens spring 66 will be described in detail.

FIG. 11 is an explanatory view of the configuration of the back surface side (negative side in the Y direction) of the backlight unit 6, and is a perspective view showing a part of the display forming apparatus 1 excluding the case 2. FIG. 12 is a partial cross-sectional perspective view taken along the XY plane including the line CC of FIG. 11. FIG. 13 is a perspective view of the second lens spring 66 in a single product state. FIG. 14 is an explanatory diagram of the method of assembling the substrate 68, and FIG. 15 is an explanatory diagram of the method of assembling the heat conductive sheet 69. The substrate 68 is shown very schematically in FIGS. 14 and 15 for purposes of illustration.

As described above, the second lens spring 66 has the function of urging the lens array 67 toward the substrate 68 and the heat conductive sheet holding function. As shown in FIG. 11, the second lens springs 66 are provided on both side parts 658 of the lens holder 65 in the X direction. That is, the second lens springs 66 are located on both sides of the lens holder 65 in the X direction and form a pair. The respective second lens springs 66 on both sides in the X direction are symmetrical in the X direction. Hereinafter, unless otherwise specified, one of the second lens springs 66 will be described.

As shown in FIG. 13, the second lens spring 66 includes a fixing portion 661, a first urging portion 662 (an example of a first portion), a second urging portion 663 (an example of a second portion), and a protrusion. Section 664.

The fixing portion 661 is a portion fixed to the lens holder 65. The fixed portion 661 includes a pair of holding portions 6611 that holds the side portion 658 of the lens holder 65, and a fitting portion 6612 that fits into the convex portion 6581 of the side portion 658 of the lens holder 65.

The first urging unit 662 urges the lens array 67 toward the substrate 68. The first biasing portion 662 is formed so as to be continuous with the fixed portion 661. The first biasing portion 662 extends in the X direction and is elastically deformed by receiving a force from the lens array 67 toward the positive side in the Y direction. The first urging portions 662 are provided at two upper and lower positions around the vertical center of the side portion 658 of the lens holder 65. In this case, the first biasing portion 662 can bias the lens array 67 toward the substrate 68 substantially vertically. This is because the vertical center of the lens holder 65 and the vertical center of the lens array 67 substantially coincide with each other.

The second urging portion 663 realizes a heat conductive sheet holding function by urging the heat conductive sheet 69 toward the substrate 68. The second biasing portion 663 is formed so as to be continuous with the fixed portion 661. The second urging portion 663 bends at a position further away from the lens array 67 than the heat conductive sheet 69 in the Y direction (hereinafter, also referred to as “bending position”, see P1 in FIG. 12) (an example of the first position). After that, it extends toward a position (hereinafter, also referred to as “contact position”, see P2 in FIG. 12) in contact with the heat conductive sheet 69 (an example of the second position). Therefore, the second biasing portion 663 includes a portion extending to the Y direction negative side with respect to the heat conductive sheet 69, and a part of the portion is located inside the recess 2b (see FIG. 10) of the case 2.

The second biasing portion 663 has an inclined surface 6632. As shown in FIG. 12, the inclined surface 6632 is formed between the bending position (see P1 in FIG. 12) and the contact position (see P2 in FIG. 12). The inclined surface 6632 is closer to the center of the lens array 67 in the X direction in the contact position (see P2 in FIG. 12) than in the bent position (see P1 in FIG. 12) when viewed in the Z direction (up and down direction). In an aspect, it tilts. As shown in FIG. 12, the inclined surface 6632 may be formed entirely between the bent position (see P1 in FIG. 12) and the contact position (see P2 in FIG. 12). However, in the modification, the inclined surface 6632 may be formed only in a part between the bending position (see P1 in FIG. 12) and the contact position (see P2 in FIG. 12). By having such an inclined surface 6632, the assembly of the substrate 68 becomes easy.

Specifically, after the second lens spring 66 and the like are attached to the lens holder 65, when the substrate 68 is attached in the Y direction from the Y direction negative side as shown by an arrow R1 in FIG. Then, it is possible to move to the positive side in the Y direction along the inclined surface 6632. That is, the second lens spring 66 can be elastically deformed in such a manner that the substrate 68 is guided to the positive side in the Y direction. At this time, the second urging portion 663 elastically deforms in the direction in which the bending angle becomes narrower (see arrow R2 in FIG. 14), and allows the substrate 68 to further advance (assemble) to the Y direction positive side. Then, finally, the substrate 68 reaches the Y direction positive side of the second urging portion 663, and the second urging portion 663 restores in a mode in which the bending angle returns to the original state. However, even in this state (the state in which the substrate 68 has been assembled), the second urging unit 663 is still urging the substrate 68 toward the lens array 67. Alternatively, in a state where the substrate 68 is completely assembled (a state before the heat conductive sheet 69 is assembled), the second biasing portion 663 contacts the substrate 68 without biasing the substrate 68 toward the lens array 67. It may be just in the state of being.

The protrusion 664 is formed on the surface of the second biasing portion 663 on the negative side in the Y direction (the side far from the lens array 67). The protrusion 664 is formed so as to be continuous with the second biasing portion 663.

The protrusion 664 has a function of improving the assembling property when the heat transfer sheet 69 is mounted on the substrate 68. Specifically, the heat conductive sheet 69 is assembled after the substrate 68 is assembled to the lens holder 65 as described above, but the second urging portion 663 places the heat conductive sheet 69 on the substrate 68. It extends in a manner to overlap the surface. Therefore, the second urging portion 663 becomes an obstacle when the heat conductive sheet 69 is assembled. In other words, in order to assemble the heat conductive sheet 69 onto the substrate 68, the second urging portion 663 is temporarily elastically deformed to the Y direction negative side (see the dotted line in FIG. 15), and the substrate 68 and the second attaching member 663 are attached. It is necessary to form a gap Δ1 (see FIG. 15) into which the heat conductive sheet 69 is inserted, between the biasing portion 663.

In this regard, when the protrusion 664 is provided, as shown by an arrow R3 in FIG. 15, a force is applied to the protrusion 664 to easily elastically deform the second urging portion 663 to the Y direction negative side. Accordingly, even when the second lens spring 66 has the second biasing portion 663 for the heat conductive sheet holding function, the heat conductive sheet 69 can be easily assembled.

The protrusion 664 is preferably inclined in the same direction as the inclined surface 6632 of the second biasing portion 663 when viewed in the Z direction. That is, the protrusion 664 is closer to the center of the lens array 67 in the X direction at the root position (see P3 in FIG. 13) on the second biasing portion 663 side than in the tip position (see P4 in FIG. 13). It inclines and extends. In this case, it becomes easy to temporarily apply elastic force to the protrusion 664 to elastically deform the second urging portion 663 to the Y direction negative side.

Thus, in this embodiment, the backlight unit 6 in the assembled state in which the heat conductive sheet 69 is held by the second lens spring 66 can be configured. As a result, there is no need to add an adhesive layer to the heat conductive sheet 69, and the cost of the heat conductive sheet 69 can be reduced.

More specifically, in the configuration in which the heat dissipation portion 21 is formed as a part of the case 2 as in the present embodiment, before the backlight unit 6 is assembled to the case 2, the heat dissipation portion 21 of the case 2 and the substrate 68. It is not possible to hold the heat conductive sheet 69 between them. In this respect, even if the second biasing portion 663 is not provided unlike the second lens spring 66 of the present embodiment, if the heat conductive sheet 69 is provided with adhesiveness, the heat dissipation portion 21 or the substrate. It is also possible to assemble the backlight unit 6 to the case 2 with the heat transfer sheet 69 attached to 68. However, using the heat conductive sheet 69 having such adhesiveness is disadvantageous in terms of cost and the like.

In this respect, according to the present embodiment, as described above, the second lens spring 66 includes the second urging portion 663, so that the backlight unit in an assembled state in which the heat conductive sheet 69 is held by the second lens spring 66. 6 can be attached to the case 2. That is, it is possible to properly assemble the heat conductive sheet 69 without imparting tackiness to the heat conductive sheet 69. As a result, the cost of the heat conductive sheet 69 can be reduced.

Although the respective embodiments have been described above in detail, the invention is not limited to the specific embodiments, and various modifications and changes can be made within the scope of the claims. Further, it is possible to combine all or a plurality of the constituent elements of the above-described embodiments.

For example, in the above-described embodiment, the lens holder 65 has the notch 6512 in the first screw fastening portion 651 so that the lens holder 65 can be displaced in the Y direction positive side with respect to the case 2, but instead of the notch 6512, Y An elongated hole whose direction is the longitudinal direction may be formed.

1 Display Forming Device 2 Case 2a Surface 2b Recess 3 TFT Panel Unit 4 Mirror 5 Mirror 6 Backlight Unit 8 Light Source 9 Instrument Panel 21 Heat Dissipation Site 31 TFT Holder 32 TFT Panel 33 Diffusion Sheet 34 Cover 61 Lens Cover 62 First Lens Spring 63 Condensing Lens 64 Diffusion Plate 65 Lens Holder 66 Second Lens Spring 67 Lens Array 68 Substrate 69 Heat Transfer Sheet 70 First Screw Receiving Part 72 Surface 74 Second Screw Receiving Part 90 Screw 94 Screw 95 Screw 611 Opening 612 Claw 631 through hole 641 through hole 650 pin portion 651 first screw fastening portion 652 screw passing portion 654 contact portion 658 side portion 661 fixing portion 662 first biasing portion 663 second biasing portion 664 projection portion 671 collimator portion 6511 seat portion 6512 Notch 6513 Lower surface 6581 Convex portion 6611 Clamping portion 6612 Fitting portion 6632 Sloping surface

Claims (9)

A housing including a heat dissipation part,
A substrate on which the light source is mounted,
A lens member through which the light emitted from the light source is transmitted,
A holding member that is supported by the housing and holds the lens member;
A leaf spring member fixed to the holding member and having a first portion for urging the lens member toward the substrate;
A heat conductive sheet sandwiched between the heat dissipation portion and the substrate;
The said leaf|plate spring member is a display forming apparatus which further has a 2nd site|part which biases the said heat conductive sheet toward the said board|substrate. The display forming device according to claim 1, wherein the leaf spring members are provided on both sides of the holding member, respectively. The leaf spring member has a fixing portion fixed to the holding member,
The second part is formed from the fixing part, and is bent at a first position farther from the lens member than the heat conductive sheet in the optical axis direction of the light source, and is then in contact with the heat conductive sheet at a second position. The display forming apparatus according to claim 2, wherein the display forming apparatus extends toward. 4. The second portion has an inclined surface between the first position and the second position in a manner that the second position is closer to the center of the lens member than the first position. The display forming apparatus described in 1. The display formation according to any one of claims 2 to 4, wherein the leaf spring member has a protrusion on a surface of the second portion on a side farther from the lens member in the optical axis direction of the light source. apparatus. The display forming device according to claim 5, wherein the protrusion extends obliquely in such a manner that a root position on the second portion side is closer to the center of the lens member than a tip position. The display forming device according to claim 1, wherein the housing has a recess that receives the second portion. The housing has a first mounting portion,
The surface of the first mounting portion is inclined such that the surface thereof is closer to the heat radiating portion in the optical axis direction of the light source as it goes downward.
The holding member has a second mounting portion having a surface along the surface of the first mounting portion,
The holding member is fastened to the first mounting portion via a fastening member that passes through a hole or a notch formed in the second mounting portion, and the holding member is fastened to the first mounting portion. Display forming device. For head-up display,
The display forming apparatus according to claim 1, further comprising an image forming unit that is fixed to the housing and forms an image using light from the display forming apparatus.

Images