JP7099102B2 - Display device - Google Patents

Description

The disclosure by this specification relates to a display device.

Conventionally, a display device is known. The apparatus disclosed in Patent Document 1 includes a light source unit and a translucent display plate. The light source unit provides light source light. The translucent display plate has a light emitting display unit that displays light emission by introducing light from a light source into the plate and receiving the light source light guided through the inside of the plate. When the light source unit is turned on, the light source light emitted from the light source unit is incident on the end surface of the translucent display plate to guide the inside of the plate.

Japanese Unexamined Patent Publication No. 2016-121891

However, in the configuration of Patent Document 1, the light source light from the light source unit enters through the end face as described above and reaches the light emission display unit as it is, so that the influence of the intensity distribution caused by the light emission form of the light source unit remains as it is. Since the light is transmitted to the light source display unit, the illumination unevenness is large, and as a result, there is a concern that the brightness unevenness in the light source display unit may occur.

One object disclosed is to provide a good looking display device.

The display device of the embodiment disclosed herein includes a light source unit (50) that provides light source light and a light source unit (50).
It is a plate member that is formed in the shape of a translucent plate and introduces the light source light into the inside of the plate from the light source light introduction unit (40). A translucent display board (30) having a light emission display unit (33),
A light guide relay that is arranged between the light source unit and the light source light introduction unit of the translucent display plate, relays the light source light from the light source unit, and guides the light from the light source light introduction unit of the translucent display plate to the inside of the plate. With the member (60)
By providing the light-transmitting display plate and the light guide relay member so as to face each other, an opposed portion (OS) through which the light source light is passed from the light guide relay member to the light-transmitting display plate is formed. A diffuser (DS) that diffuses light is provided ,
The light emitting display unit has a plurality of reflecting elements (35) having a shape recessed from the plate surface (31b) of the translucent display plate and provided with a reflecting surface for reflecting the light source light introduced inside the plate to the visual recognition side. , The design (34) formed by the set of reflective elements is illuminated and displayed.
In the facing portion, the translucent display plate and the light guide relay member face each other in the direction along the translucent display plate to form an air gap (AG).
The translucent display plate protrudes toward the light guide relay member from a position deviated from the facing portion in the plate thickness direction (TD), and abuts on the light guide relay member in the plate thickness direction to partition a part of the air gap. Has a contact (42) and
A cushioning member (70) having a cushioning property, which is arranged on the opposite side of the light guide relay member with the protruding contact portion,
Further, a holding portion (SW) for sandwiching and holding the projecting contact portion, the light guide relay member, and the cushioning member in the plate thickness direction is further provided .

According to such an aspect, a diffusing portion for diffusing the light source light is provided at the facing portion where the light source light is passed from the light guide relay member to the translucent display plate. That is, the light guide relay member that relays the light source light from the light source unit to the inside of the translucent display plate once guides the light source light from the light source unit to efficiently transmit the light source light to the diffuser unit. Can be guided. Further, since the light source light is diffused by the diffusing portion at the facing portion, the influence of the light emitting form of the light source portion is reduced in the light source light introduced into the plate, so that the light emitting form of the light source portion does not matter. , It is possible to realize more uniform illumination to the light source display unit. Therefore, the uneven brightness in the display of the light emitting display unit is also reduced, and it is possible to provide a display device having a good appearance.

It should be noted that the reference numerals in parentheses exemplify the correspondence with the parts of the embodiments described later, and are not intended to limit the technical scope.

It is a front view which shows the display device for a vehicle of 1st Embodiment. FIG. 2 is a sectional view taken along line II-II of FIG. FIG. 3 is a sectional view taken along line III-III of FIG. FIG. 6 is a sectional view taken along line IV-IV of FIG. FIG. 5 is a sectional view taken along line VV of FIG. It is an enlarged plan view of the area where the composite reflection element of the light emission display part of FIG. 1 is arranged. 6 is a sectional view taken along line VII-VII of FIG. FIG. 7 is a sectional view taken along line VIII-VIII of FIG. It is a top view which shows the part of a part of a light source part, a light guide relay member, and a part of a translucent display board in an enlarged manner. 9 is a cross-sectional view taken along the line X-X of FIG. 9 is a sectional view taken along line XI-XI of FIG. 9 is a sectional view taken along line XII-XII of FIG. It is a figure corresponding to FIG. 2 in the modification 7.

One embodiment will be described with reference to the drawings.

(First Embodiment)
As shown in FIG. 1, the display device 100 according to the first embodiment of the present disclosure is a vehicle display device used for a vehicle, and faces a seat on which an occupant as a viewer who visually recognizes the device 100 sits. It is installed on the instrument panel. The display device 100 can display vehicle information toward the visual recognition side where the occupant is located. Of the upper surface portion of the instrument panel, the portion located above the display device 100 is formed in a gently curved surface shape that is convex upward.

In this embodiment, the directions indicated by up / down, front / rear, and left / right are described with reference to the vehicle on the horizontal plane.

As shown in FIGS. 2 to 5, such a display device 100 includes a case portion 10, a main body portion 20, a translucent display plate 30, a light source portion 50, a light guide relay member 60, and the like.

The case portion 10 has a back side case 11, a visual recognition side case 12, a facing member 13, and a front plate 14. The back side case 11 is formed with a light-shielding property, for example, by using synthetic resin, and covers the main circuit board 26 from the back side opposite to the visual recognition side.

The visual recognition side case 12 arranged on the visual recognition side with respect to the rear side case 11 is formed of, for example, a synthetic resin so as to have a light-shielding property, and the deformed tubular outer frame portion 12a surrounding the main body portion 20 from the outer peripheral side of the device 100. And the partition portion 12b that partitions the internal space of the case are integrally formed. The outer peripheral side of the device 100 as used herein is defined as the radial direction in which the direction from the center of the device to each position on the side of the device and the opposite direction when viewed from the visual side are defined as the radial direction. , Indicates the radial outside. Further, the inner peripheral side of the device 100 indicates the inner side in the radial direction.

The facing member 13 is formed to have a light-shielding property by, for example, synthetic resin, and is arranged on the viewing side with respect to the viewing side case 12. The facing member 13 has openings on the visual recognition side and the back surface side, and is formed in a deformed tubular shape along the outer periphery of the device 100.

The front plate 14 is formed of a translucent resin such as a colored acrylic resin or a polycarbonate resin into a curved plate shape that closes the entire surface of the viewing side opening of the facing member 13. As a result, the optically exposed portion of the main body 20 and the translucent display plate 30 are visible to the occupant through the front plate 14. The front plate 14 of the present embodiment has a visible light transmittance of about 30% due to smoke-like coloring, but may be set to any value of 30% or more.

In addition to the main circuit board 26 described above, the main body portion 20 has a light-shielding display plate 21, a pointer portion 22, and an image display portion 25.

The light-shielding display plate 21 is also generally called a dial, and is arranged so as to close the opening opened on the visual recognition side in the visual recognition side case 12. As shown in FIG. 1, the light-shielding display plate 21 has a main portion arranged in a region on the left side and a region on the right side of the device 100, and is provided so as to sandwich the image display portion 25 on the left and right. In particular, in the present embodiment, the light-shielding display plate 21 is arranged separately on the left and right, but the left and right may be connected so as not to interfere with the light emitting display unit 33. The light-shielding display plate 21 is partially or wholly printed on the surface of a base material made of, for example, a translucent synthetic resin, and has a dark color (for example, black) as a whole. It is formed in the shape of a flat plate. Instead of printing, painting may be applied.

A plurality (pair) of the pointer portions 22 are provided by individually arranging the light-shielding display plate 21 in the left side region and the right side region in which they are arranged. Here, since the two pointer units 22 have the same configuration as each other, the pointer unit 22 on the right side will be described as a representative.

As shown in FIG. 2, the pointer unit 22 has a stepping motor 23 and a pointer 24. The stepping motor 23 is held on the main circuit board 26 sandwiched between the rear side case 11 and the visual recognition side case 12.

The pointer 24 integrally has a connecting portion 24a and an indicating portion 24b. The connecting portion 24a is arranged through a through hole formed in the light-shielding display plate 21 and is connected to the rotating shaft of the stepping motor 23. The indicator portion 24b is arranged on the visual recognition side with respect to the light-shielding display plate 21, and has a needle shape. The pointer 24 rotates around a rotation axis according to the output of the stepping motor 23, and by instructing the index 21a, information on the vehicle according to the instructed position is displayed. Further, the pointer 24 emits light by being illuminated by the light emitting element 26a mounted on the main circuit board 26.

As shown in FIG. 1, the index 21a is formed by arranging a scale and characters corresponding to the scale in a partial annular shape by printing on the light-shielding display plate 21. In the present embodiment, the index 21a corresponding to the pointer portion 22 on the left side is an index for displaying the engine speed of the vehicle. On the other hand, the index 21a with respect to the pointer portion 22 on the right side is an index for displaying the speed of the vehicle.

As shown in FIG. 1, the image display unit 25 is arranged in the central region of the device 100 sandwiched between the two pointer units 22. As shown in FIGS. It is a display. In particular, the image display unit 25 of the present embodiment employs a so-called TFT type liquid crystal display using a thin film transistor (TFT). As the image display unit 25, another type of display such as an organic EL display can be adopted.

Such an image display unit 25 has a contour rectangular and flat display screen 25a for displaying an image on the visual recognition side. The display screen 25a is surrounded by a frame (bezel) 25b for hiding wiring or the like arranged on the outer edge of the image display unit 25. The light of the image displayed on the display screen 25a passes through the translucent display plate 30 and further the front plate 14.

The translucent display plate 30 is formed of a translucent synthetic resin such as acrylic resin or polycarbonate resin in a flat plate shape having a pair of plate surfaces 31a and 31b extending vertically and horizontally on the viewing side and the back surface side. .. The translucent display plate 30 is provided substantially parallel to the display screen 25a of the light-shielding display plate 21 and the image display unit 25. As shown in FIGS. 2 and 3, the translucent display plate 30 is arranged between the opening 21b and the image display unit 25. The front plate surface 31a facing the visual recognition side of the translucent display plate 30 is arranged so as to face the front plate 14 with the opening 21b interposed therebetween. The back plate surface 31b facing the back side of the translucent display plate 30 faces the display screen 25a of the image display unit 25 through a slight gap.

The light-shielding sheet member 27 is arranged between the translucent display plate 30 and the frame 25b of the image display unit 25. The light-shielding sheet member 27 is formed in the form of a sheet by, for example, the surface of a base material made of a translucent synthetic resin, which is entirely printed with light-shielding properties (dark color printing such as black). The light-shielding sheet member 27 has an outer peripheral portion 27a formed to be one size larger than the image display unit 25 and a rectangular opening hole 27b one size smaller than the display screen 25a, whereby the frame of the image display unit 25 is formed. It has a rectangular frame shape that covers 25b.

Further, on the outer peripheral portions 32 on the left and right sides of the translucent display plate 30, the light-shielding display plate 21 is extended to the translucent display plate 30 side, so that the light-shielding display plate 21 overlaps the outer peripheral portion 32 in an eaves shape. The eaves portion 21c is formed. The eaves portion 21c has a light-shielding property by being printed with a light-shielding property as a whole. In the present embodiment, the overlap allowance (creeping distance) in which each eaves portion 21c overlaps the outer peripheral portion 32 is set to be smaller than the overlap allowance in which the light-shielding sheet member 27 overlaps the outer peripheral portion 32.

The light-shielding sheet member 27 improves the appearance of the image display unit 25 by covering the frame 25b of the image display unit 25. On the other hand, the eaves portion 21c shields the diffused light that may be generated when the light source light (details will be described later) introduced into the inside of the translucent display plate 30 hits the left and right side surfaces of the translucent display plate 30. And by absorbing the light, the leakage of the light source light from the outer peripheral portion 32 to the visual recognition side is restricted, and the appearance of the diffused display plate 30 is improved.

Further, the light-shielding sheet member 27 has a through hole 27c penetrating in the plate thickness direction TD in the extending portion 27d extending to the upper portion thereof.

As shown in FIGS. 1, 3 to 5, the light source unit 50 provides the light source light to the translucent display plate 30. The light source unit 50 is formed between the return member 13 and the viewing side case 12 on the upper side of the image display unit 25, the translucent display plate 30, and the light guide relay member 60 in the device 100, so that the light source unit 50 is formed from the inside to the outside of the device. It is arranged in the light leakage control space SP where the light leakage to the light source is regulated. The light source unit 50 is arranged on the back side with respect to the back member 13 so as not to be visually recognized by the occupant. Specifically, the light source unit 50 is composed of a holding member 51, a pair of light source substrates 52, a plurality of light emitting elements 53, a pair of optical sheet members 54, and the like, and is a light source unit that can be collectively attached to and detached from the case unit 10. Is forming.

The holding member 51 is formed of, for example, a light-shielding base material made of synthetic resin, and is held by fastening to the visible side case 12, for example, with a screw 55. In particular, in the present embodiment, the holding member 51 is integrally composed of a pair of elongated plates 51a which are elongated and elongated at lower sides so as to match the shapes of the translucent display plate 30 and the light guide relay member 60. Have in. Each elongated plate 51a has a plurality of through holes 51b penetrating the elongated plate 51a.

The pair of light source substrates 52 are individually provided corresponding to the pair of elongated plates 51a, and are held on the corresponding elongated plates 51a on the surface facing the side opposite to the translucent display plate 30. Each light source substrate 52 mounts the same number of light emitting elements 53 as the through holes 51b. The light emitting elements 53 are arranged in the corresponding through holes 51b so that they are arranged with each other. A point light source-like light emitting diode is adopted for each light emitting element 53, and each light emitting element 53 emits light by being connected to a power source through a conduction pattern on the light source substrate 52. The plurality of light emitting elements 53 are provided so as to be able to switch on or off at the same time, and emit light from a light source in the same color as each other. In particular, each light emitting element 53 of the present embodiment is adapted to emit white light source light.

As shown in FIGS. ing. Each optical sheet member 54 is formed in a thin plate shape by applying semi-translucent printing to the entire one side of a translucent base material such as acrylic resin or polycarbonate resin. Each optical sheet member 54 is colored in, for example, blue, which is translucent, and is a color filter that converts the color tone of the light source light emitted by each light emitting element 53 by closing the through hole 51b.

The light source light emitted from each light emitting element 53 passes through the optical sheet member 54, passes through the light guide relay member 60, and then enters the inside of the translucent display plate 40 from the light source light introduction portion 40 of the translucent display plate 30. be introduced. The light source light introduced into the inside of the translucent display plate 30 travels inside the plate with the direction from the upper side to the lower side as the traveling direction PD. The light source light traveling inside the plate includes light traveling in various directions, and the traveling direction PD as used herein means a direction in which the various directions are averaged while adding intensity.

As shown in FIG. 1, the translucent display plate 30 has a light emitting display unit 33 at a portion overlapping with the display screen 25a in response to the introduction of the light source light into the plate. The light emission display unit 33 is adapted to display light emission (lighting display) by receiving light from a light source.

Specifically, as shown in FIGS. 6 to 8, the light emitting display unit 33 is an element having a shape of being recessed from the back plate surface 31b toward the front plate surface 31a, and has a fine recess depth of about 5 to 20 μm. It has a plurality of reflecting elements 35 of a size. As shown in FIG. 1, the light emitting display unit 33 can display the symbol 34, which is macroscopically visible to the occupant, as a set of the reflecting elements 35 by appropriately arranging a large number of reflecting elements 35. ing. In the present embodiment, the symbol 34 is formed by arranging a plurality of reflecting elements 35 two-dimensionally along the back plate surface 31b. Since each reflecting element 35 has a reflecting surface that reflects the light source light introduced into the plate to the visual recognition side, the symbol 34 emits light in a planar manner and is displayed.

Specifically, in the present embodiment, the symbol 34 is a decorative symbol that decorates the image display unit 25. The light emitting display unit 33 of the present embodiment is rectangular so as to border the outer peripheral portion of the display screen 25a as a symbol 34 by superimposing at least a part on the display screen 25a on the visual recognition side of the image display unit 25. A frame pattern formed in an annular shape is provided.

As shown in FIGS. 6 to 8, the plurality of reflecting elements 35 include a composite reflecting element 36. In particular, in the present embodiment, all the reflecting elements 35 constituting the light emitting display unit 33 are composite reflecting elements 36.

Each composite reflecting element 36 is formed by being recessed in a triangular pyramid shape from the back plate surface 31b toward the front plate surface 31a. In particular, as shown in FIG. 6, each composite reflecting element 36 has an isosceles triangle shape on a plan view taken along the plate thickness direction TD of the translucent display plate 30 perpendicular to the back plate surface 31b. .. Each composite reflective element 36 has a composite reflective surface 37 composed of two inclined surfaces 37a and 37b and an element back surface 38.

The two inclined surfaces 37a and 37b are arranged at positions corresponding to the equilateral sides in an isosceles triangle shape on the plan view. The two inclined surfaces 37a and 37b are two surfaces of the triangular pyramid-shaped composite reflecting element 36 facing the light source light introduction portion 40 into which the light source light is introduced, and the outer contours are triangular planes, respectively. It is formed.

Each composite reflecting element 36 has a linear connecting side 36b connecting two inclined surfaces 37a and 37b along a cross section that bisects an isosceles triangular apex angle (or base) on a plan view. Have. The connection side 36b is inclined so as to be further separated from the light source light introduction portion 40 from the back plate surface 31b side toward the front plate surface 31a side, and particularly in the plate thickness direction as shown in FIG. It has an inclination angle of, for example, 45 degrees with respect to TD. Similar to the connection side 36b, the inclined surfaces 37a and 37b are also inclined so as to be further separated from the light source light introduction portion 40 from the back plate surface 31b toward the front plate surface 31a. The inclined surfaces 37a and 37b also have an inclined angle of, for example, 45 degrees with respect to the plate thickness direction TD on the cross section parallel to the cross section that bisects the apex angle described above.

Further, the two inclined surfaces 37a and 37b are set so that their orientations are different from each other. Specifically, the two inclined surfaces 37a and 37b face each other diagonally sideways along the inclined sides of the isosceles triangle on the plan view. The left inclined surface 37a faces slightly to the left, and the right inclined surface 37b faces slightly to the right. Specifically, in the present embodiment, in the triangular pyramid-shaped composite reflecting element 36, the concave bottom portion 36a having the deepest recessed depth is included, and the above-mentioned apex angle is bisected on a vertical cross section perpendicular to the cross section. In particular, as shown in FIG. 8, the two inclined surfaces 37a and 37b are inclined in opposite directions with respect to the back plate surface 31b, for example, at an inclination angle of 10 degrees.

As shown in FIGS. 6 and 8, the element back surface 38 is arranged at a position corresponding to the base in an isosceles triangle shape on a plan view, and is formed so as to face the side opposite to the light source light introduction portion 40. The back surface 38 of the element has an outer contour formed in a triangular planar shape. The back surface 38 of the element is inclined so as to approach the light source light introduction portion 40 into which the light source light is introduced from the back plate surface 31b side toward the front plate surface 31a side, for example, with respect to the plate thickness direction TD. It has an inclination angle of 5 degrees.

As shown in FIG. 6, in the present embodiment, each composite reflecting element 36 has an arrangement pitch PT1 and 1, respectively, set in the arrangement directions D1 and D2 by passing through a flat portion 39 formed flat on the back plate surface 31b. Only PT2s are separated from each other and are arranged one by one in isolation. The arrangement direction D1 is along the direction from the upper side to the lower side, which is the main traveling direction PD of the light source light, and the arrangement direction D2 is a direction substantially perpendicular to the arrangement direction D1.

The plurality of composite reflection elements 36 are arranged in a so-called zigzag pattern in which the positions of the concave bottom portions 36a are shifted by half of the arrangement pitches PT1 and PT2 for each row. According to the staggered arrangement of the composite reflecting element 36, a gentle impression can be given to the symbol 34.

Then, in order to realize high brightness and uniform brightness of the symbol 34 of the light emission display unit 33, the efficiency of guiding light from the light source unit 50 to the light emission display unit 33 is increased, and uneven illumination of the light emission display unit 33 is achieved. It is effective to reduce. Based on these findings, in the present embodiment, the light guide relay member 60 that relays the light source light from the light source unit 50 is adopted.

The light guide relay member 60 shown in FIG. 9 is formed of a translucent synthetic resin such as acrylic resin or polycarbonate resin, and is arranged between the light source unit 50 and the light source light introduction unit 40 of the translucent display plate 30. Has been done. The light guide relay member 60 relays the light source light from the light source unit 50 and guides the light from the light source light introduction unit 40 to the inside of the translucent display plate 30. The light guide relay member 60 is arranged on the back side with respect to the back member 13 so as not to be visually recognized by the occupant. As shown in FIGS. 10 to 12, the light guide relay member 60 has an introduction mirror surface 61, a light guide unit 62, a handle portion 64, an insertion protrusion 65, and an injection diffusion surface 63. The broken line arrows in FIGS. 10 to 12 schematically show the behavior of the light source light.

The introduction mirror surface 61 faces the optical sheet member 54 of the light source unit 50 via a slight gap of about 1 to 2 mm, and is formed in a mirror surface shape and a flat shape. The introduction mirror surface 61 is an elongated surface extending in the left-right direction according to the arrangement direction of the light emitting elements 53. In particular, in the present embodiment, corresponding to the arrangement of the light emitting elements 53 along the pair of light source substrates 52, the introduction mirror surfaces 61 are provided in pairs so as to form an obtuse angle on the light guide portion side of each other. There is. Each introduction mirror surface 61 is formed so that the light source light from the light source unit 50 can be introduced into the member of the light guide relay member 60 without giving a diffusion action. Since each introduced mirror surface 61 is formed in a mirror surface shape, the light source light can be efficiently taken into the member as it is.

The light guide portion 62 is formed in a plate shape extending between the introduction mirror surface 61 and the injection diffusion surface 63. Since the light guide unit 62 forms an optical path that can guide the light source light in a straight line, the intensity unevenness caused by the arrangement of the light source elements 53 in the shape of a point light source is caused with respect to the light source light from the light source unit 50. A mitigating optical path length is provided, and efficient light guidance to the emission diffusion surface 63 of the light source light is realized.

As shown in FIG. 11, the handle portion 64 is formed in a protrusion shape that protrudes toward the visual recognition side substantially perpendicular to the stretching direction of the light guide portion 62 (in other words, the handle portion 64 is formed. It protrudes along the TD in the plate thickness direction). The handle portion 64 is used to temporarily hold the light guide relay member 60 at the time of manufacturing the display device 100, particularly in the step of assembling the light guide relay member 60.

As shown in FIG. 12, the insertion protrusion 65 is formed in a protrusion shape that protrudes toward the back surface substantially perpendicular to the stretching direction of the light guide portion 62 (in other words, the insertion protrusion 65 has a plate thickness. (Protruding along the direction TD). The insertion protrusion 65 is arranged in a state of being inserted into the through hole 27c of the light-shielding sheet member 27, so that the light-shielding sheet member 27 and the light guide relay member 60 are positioned with each other.

The emission diffusion surface 63 is arranged so as to face the light source light introduction portion 40 of the translucent display plate 30 in the side-by-side direction (direction perpendicular to the plate thickness direction TD) of the translucent display plate 30. The emission diffusion surface 63 is an elongated surface extending in the left-right direction so as to match the arrangement direction of the light emitting elements 53. The emission diffusion surface 63 is formed in a diffusion surface shape and a planar shape in which the light source light guided by the light guide portion 62 is diffused and emitted to the light source light introduction portion 40 side of the translucent display plate 30. In the present embodiment, the injection diffusion surface 63 is formed into a rough surface by embossing, but a diffusion layer (diffusion paint, diffusion sheet) or the like that diffuses the light source light is arranged on the surface of the mirror surface. May be formed.

An air gap AG as an air layer is formed between the injection diffusion surface 63 of the light guide relay member 60 and the light source light introduction portion 40 of the light transmission display plate 30. The air gap AG is set to have a substantially uniform gap width over the entire area, and has a gap width of, for example, 1 mm.

An introduction diffusion surface 41 is provided as a light source light introduction portion 40 of the translucent display plate 30 on the side opposite to the injection diffusion surface 63 with the air gap AG interposed therebetween. The introduction diffusion surface 41 faces the injection diffusion surface 63 of the light guide relay member 60 in the longitudinal direction of the translucent display plate 30. The introduction diffusion surface 41 is an elongated surface extending in the left-right direction so as to match the injection diffusion surface 63. The introduction diffusion surface 41 is formed in a diffusion surface shape that diffuses the light source light from the light guide relay member 60 side while introducing it into the plate. In the present embodiment, the introduced diffusion surface 41 is formed into a rough surface by embossing, but a diffusion layer (diffusion paint, diffusion sheet) or the like that diffuses the light source light is arranged on the surface of the mirror surface. May be formed.

In this way, by providing the light-transmitting display plate 30 and the light guide relay member 60 so as to face each other, the facing portion OS in which the light source light is passed from the light guide relay member 60 to the light-transmitting display plate 30 is formed. Has been done. An injection diffusion surface 63, an air gap AG, and an introduction diffusion surface 41 are provided in the facing portion OS to form a diffusion portion DS that diffuses the light source light. In the present embodiment, substantially all the light source light from the light source unit 50 to the inside of the translucent display plate 30 passes through the diffuser unit DS. As a result of the light source light passing through the diffusing portion DS being subjected to the diffusing action of the injection diffusing surface 63, the air gap AG and the introduced diffusing surface 41, the illumination unevenness becomes extremely small.

Further, the translucent display plate 30 has a protruding contact portion 42 that protrudes toward the light guide relay member 60 side (also on the light source portion 50 side or the upper side) from a position displaced from the facing portion OS on the back surface side in the plate thickness direction TD. have. The protruding contact portion 42 is in contact with the side surface of the light guide portion 62 of the light guide relay member 60 and the TD in the plate thickness direction.

Further, as shown in FIG. 3, a cushioning member 70 having a cushioning property (for example, elasticity) is arranged on the opposite side of the protruding contact portion 42 with the light guide portion 62 interposed therebetween. The cushioning member 70 of the present embodiment is adhered to the side surface of the light guide portion 62 by an adhesive. As the cushioning member 70, a member having excellent cushioning properties such as microcell polyurethane foam represented by PORON (registered trademark) can be adopted.

The protruding contact portion 42, the light guide portion 62, and the cushioning member 70 are collectively sandwiched in the plate thickness direction TD by the sandwiching portion SW. In particular, in the present embodiment, the light-shielding sheet member 27 forms an extending portion 27d extending to a position opposite to the light guide portion 62 with the projecting contact portion 42 interposed therebetween, and the protruding contact portion 42 is formed. The hemispherical protrusion 43 (see FIG. 11) protruding toward the back surface abuts on the extending portion 27d, so that the light-shielding sheet member 27 is also collectively sandwiched by the sandwiching portion SW.

Specifically, the holding portion SW is composed of a sandwiching protrusion 13a of the back member 13 and a pedestal 12c of the viewing side case 12. The sandwiching protrusion 13a abuts on the cushioning member 70 and compresses the cushioning member 70 with a light pressure. The pedestal 12c is located on the side opposite to the hemispherical protrusion 43 of the translucent display plate 30 with the extension portion 27d interposed therebetween, and is in contact with the extension portion 27d. In this way, the translucent display plate 30 and the light guide relay member 60 are held by the sandwiching portion SW.

(Action effect)
The effects of the first embodiment described above will be described again below.

According to the first embodiment, in the facing portion OS in which the light source light is passed from the light guide relay member 60 to the translucent display plate 30, a diffuser DS that diffuses the light source light is provided. That is, the light source relay member 60 that relays the light source light from the light source unit 50 to the inside of the transparent display plate 30 once guides the light source light from the light source unit 50, thereby efficiently transmitting the light source light. Can be guided to the diffuser DS. Further, since the light source light is diffused by the diffusion unit DS in the facing unit OS, the influence of the light source light emission form of the light source unit 50 is reduced in the light source light introduced into the plate, so that the light source unit 50 emits light. Regardless of the form, it is possible to realize more uniform illumination of the light emission display unit 33. Therefore, the uneven brightness in the display of the light emitting display unit 33 is also reduced, and the display device 100 having a good appearance can be provided.

Further, according to the first embodiment, the light guide relay member 60 is formed in a diffused surface shape that faces the translucent display plate 30 in the facing portion OS, diffuses the light source light, and emits the light source light to the translucent display plate 30 side. It has an injection diffusion surface 63 that has been formed. Since the light source light emitted from the light guide relay member 60 can be imparted with a diffusion effect by the diffusion surface-shaped injection diffusion surface 63, the light source light is transmitted when it is introduced into the inside of the translucent display plate 30. The influence of the light emitting form of the light source unit 50 can be reduced.

Further, according to the first embodiment, in the facing portion OS, an air gap AG is formed between the light transmissive display plate 30 and the light guide relay member 60. A refractive index difference can be generated between the air gap AG and the base material of the light transmissive display plate 30 and the light guide relay member 60. This difference in refractive index induces multiple reflections of the light source light reciprocating between the translucent display plate 30 of the facing portion OS and the light guide relay member 60, and such multiple reflections cause a diffusion effect of the light source light. The diffusion effect can be promoted.

Further, according to the first embodiment, the translucent display plate 30 faces the light guide relay member 60 in the facing portion OS, and the light source light from the light guide relay member 60 side is introduced and diffused while being introduced into the plate. It has a diffusion surface 41. Since the introduction diffusion surface 41 having a diffusion surface shape can impart a diffusion effect to the light source light introduced into the translucent display plate 30, the light source light that guides the inside of the translucent display plate 30 is the light source unit 50. The influence of the light emission form of is reduced.

Further, according to the first embodiment, the holding portion SW holds the protruding contact portion 42, the light guide relay member 60, and the cushioning member 70 together by sandwiching them in the plate thickness direction TD. According to such a holding mode, by sandwiching the cushioning member 70, the protruding contact portion 42 and the light guide relay member 60 are in direct contact with each other while suppressing the influence of vibration that may be applied to the display device 100. As a result, the relative position between the translucent display plate 30 and the light guide relay member 60 is maintained. By maintaining such a relative position, the diffusion performance of the diffusion unit DS can be stably exhibited in the facing unit OS, so that the appearance can be kept good. Further, since the protruding contact portion 42 is provided on the translucent display plate 30 side, the need to provide a holding portion in the vicinity of the facing portion OS of the light guide relay member 60 is reduced, so that the light guide relay member 60 is provided. It is possible to prevent the light source light guided by the light source from getting lost in such a portion, and the light source light is efficiently guided. As a result, the light source light can be efficiently reached to the light emitting display unit 33, and the brightness of the light emitting display unit 33 can be improved.

Further, according to the first embodiment, the light emitting display unit 33 has a shape recessed from the plate surface 31b of the translucent display plate 30, and is provided with a reflecting surface that reflects the light source light introduced inside the plate to the visual recognition side. By having a plurality of reflecting elements 35 and appropriately arranging the reflecting elements 35, the symbol 34 formed by the set of the reflecting elements 35 is illuminated and displayed. The brilliance of the symbol 34 can improve the appearance of the display device 100.

Further, according to the first embodiment, an image display unit 25 which is arranged on the back side of the light emission display unit 33 and displays an image superimposed on the display of the light emission display unit 33 is further provided. By superimposing the display content of the light emitting display unit 33 and the image, the three-dimensional effect of the display can be enhanced and the appearance can be improved.

Further, according to the first embodiment, the light-shielding sheet member 27 covers the frame 25b of the image display unit 25, so that the appearance of the image display unit 25 is improved. Further, the insertion projection 65 of the light guide relay member 60 is inserted into the through hole 27c provided in the light-shielding sheet member 27 sandwiched between the light-transmitting display plate 30 and the image display unit 25. Therefore, the relative position between the light-transmitting display plate 30 and the light guide relay member 60 can be positioned by the light-shielding sheet member 27. By maintaining such a relative position, the diffusion performance of the facing portion OS can be stably exhibited, so that the appearance can be kept good.

(Other embodiments)
Although one embodiment has been described above, the present disclosure is not construed as being limited to the embodiment, and can be applied to various embodiments without departing from the gist of the present disclosure.

Specifically, as a modification 1, the diffusion portion DS provided in the facing portion OS is mainly composed of the injection diffusion surface 63 and the air gap AG by forming a mirror-like introduction surface instead of the introduction diffusion surface 41. It may be configured as.

As a modification 2, a mirror-shaped injection surface is formed instead of the injection diffusion surface 63, so that the diffusion portion DS provided in the facing portion OS is mainly composed of the air gap AG and the injection diffusion surface 63. May be.

As a modification 3, the air gap AG may not be provided, and the light guide relay member 60 and the translucent display plate 30 may be in contact with each other in the facing portion OS.

As a modification 4, the light guide relay member 60 may not be provided with the insertion projection 65.

As a modification 5, the translucent display plate 30 may not be provided with the projecting contact portion 42.

As a modification 6, the holding form of the light guide relay member 60 and the translucent display plate 30 is not limited to the one using the holding portion SW, and various holding forms such as engagement and screwing can be adopted.

As a modification 7, as shown in FIG. 13, the translucent display plate 30 may be arranged on the visual recognition side with respect to the light-shielding display plate 21.

As a modification 8, the symbol 34 does not have to be superimposed on the image display unit 25. For example, the position of the translucent display plate 30 may be changed so that the symbol 34 overlaps with the pointer 24, or may not overlap with other displays. Further, as the symbol 34, any symbol other than the frame symbol can be adopted, and the symbol 34 may be configured to display information.

As a modification 9, the light emitting display unit 33 is not limited to a light emitting display unit 33 that emits light in a planar manner by means of a set of fine reflecting elements 35. For example, it is a concave hole that is recessed from the back plate surface 31b toward the front plate surface 31a and is macroscopically visible to the occupant, and its outline is formed in the shape of a character or a scale so as to display information. A concave hole may be provided. Then, the side wall surface of the concave hole receives the light source light and shines, or the rough bottom surface of the concave hole receives the light source light and shines, so that the light emitting display unit 33 can function. ..

As the modification 10, the light source unit 50 is not limited to the one using the light emitting diode. For example, the light source unit 50 may be configured by using, for example, a fluorescent tube, an organic EL, or a laser light source.

As a modification 11, the display device 100 is not limited to that used for vehicles, for example, display devices used for moving objects such as aircraft and ships, home appliances such as refrigerators, information and communication devices such as smartphones, games, and pachinko. It may be a display device used for a game machine such as a game machine or a street advertisement.

100 Display device, 30 Translucent display board, 33 Light emission display unit, 40 Light source light introduction unit, 50 Light source unit, 60 Light guide relay member, DS diffuser unit, OS facing unit

Claims (5)

A light source unit (50) that provides light source light,
It is a plate member formed in a translucent plate shape and introduces the light source light into the inside of the plate from the light source light introduction unit (40), and by receiving the light source light guided inside the plate, the light source is received. A translucent display board (30) having a light emission display unit (33) for displaying light emission,
It is arranged between the light source unit and the light source light introduction unit of the translucent display plate, relays the light source light from the light source unit, and is inside the plate from the light source light introduction unit of the translucent display plate. With a light guide relay member (60) that guides light to
By providing the light-transmitting display plate and the light guide relay member so as to face each other, a facing portion (OS) through which the light source light is transferred from the light guide relay member to the light-transmitting display plate is formed. In the facing portion, a diffusing portion (DS) for diffusing the light source light is provided .
The light emitting display unit has a shape recessed from the plate surface (31b) of the translucent display plate, and is provided with a reflecting surface for reflecting the light source light introduced inside the plate to the visual recognition side (35). The design (34) formed by the set of the reflective elements is illuminated and displayed.
In the facing portion, the translucent display plate and the light guide relay member face each other in the longitudinal direction of the translucent display plate to form an air gap (AG).
The translucent display plate protrudes toward the light guide relay member from a position deviated from the facing portion in the plate thickness direction (TD), abuts on the light guide relay member in the plate thickness direction, and is a part of the air gap. Has a protruding contact portion (42) for partitioning the
A cushioning member (70) having a cushioning property, which is arranged on the opposite side of the light guide relay member with the protruding contact portion,
A display device further comprising a holding portion (SW) that holds the protruding contact portion, the light guide relay member, and the cushioning member together in the plate thickness direction . The light guide relay member is an injection diffusion surface (63) formed in a diffusion surface shape in the facing portion, which faces the translucent display plate, diffuses the light source light, and emits the light to the translucent display plate side. The display device according to claim 1. The translucent display plate is formed in a diffused surface shape that faces the light guide relay member at the facing portion and diffuses the light source light from the light guide relay member side while introducing it into the inside of the plate. The display device according to claim 1 or 2 , which has an introduction diffusion surface (41). The display according to any one of claims 1 to 3 , further comprising an image display unit (25) arranged on the back side of the light emission display unit and displaying an image superimposed on the display of the light emission display unit. Device. A light-shielding sheet member (27) that is sandwiched between the translucent display plate and the image display unit and that covers the frame of the image display unit is further provided.
The light-shielding sheet member has a through hole (51b) penetrating in the plate thickness direction.
The display device according to claim 4 , wherein the light guide relay member has an insertion protrusion (65) arranged in a state of being inserted into the through hole.

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