JP6507889B2 - Display device - Google Patents

Description

  The present invention relates to a display device that displays information in a display area.

  Conventionally, for example, in a display device that causes a design part to emit light by transmitting light, for example, in Patent Document 1, a light source for causing the design part to emit light outside the projection range of the design part projected in the back direction. Are disclosed. In this display device, the light emitted from the light source is sequentially reflected by the wall portion positioned between the light source and the dial and the wall portion positioned in the back direction of the design portion to transmit and illuminate the design portion.

JP, 2013-242266, A

  The inventor of the present invention has attempted to form a light emitting unit to be transmitted and illuminated like the design unit of Patent Document 1 at the edge of the display area defined in the display device. Then, it became clear that it is difficult to secure a sufficient area for disposing the light source within a projection area of the circuit board in which the light emitting part is projected in the back direction. Therefore, the inventor of the present invention examined application of a configuration in which the light emitting unit is caused to emit light by reflecting the light of the light source disposed outside the projection range by a plurality of wall portions as in Patent Document 1.

  Here, in the display device in which the light emitting portion is formed at the edge of the display area, the wall portion for reflection needs to contribute to securing the rigidity and the strength of the display device as a part of the case body. Therefore, it is desirable that the plurality of walls be in a form continuous with each other. However, in the configuration in which a plurality of wall portions are arranged to overlap with each other in the display direction as in Patent Document 1, the degree of difficulty in forming each wall portion has to be extremely high.

  The present invention has been made in view of such problems, and the object of the present invention is to ensure mass productivity and to maintain rigidity and reduce unevenness of the light emitting portion formed at the edge of the display area. An object of the present invention is to provide a realized display device.

In order to achieve the above object, according to the invention as set forth in claim 1, a light emitting portion (17) for emitting light by transmitting light is formed at an edge (11a) of a display area (11) for displaying information. A light emitting unit, a circuit board (40) disposed along the display board in the back direction (BD) of the display board, and light emission among the circuit boards A light source (42) which is outside the projection range (PA) obtained by projecting the light source in the rear direction and is closer to the center of the circuit board than the projection range and emits light to emit light from the light emitter; An inner peripheral reflecting wall (61, 261) located between the plates for reflecting light emitted from the light source toward the outer peripheral side, and reflected by the inner peripheral reflecting wall located in the back direction of the light emitting portion An outer periphery that reflects light toward the light emitting portion in the front direction (FD) Reflecting wall (64) has a case body for accommodating the circuit board (50), provided with an outer peripheral side reflecting wall, avoiding the space (PS) obtained by projecting the inner peripheral side reflecting wall toward the back formation The case body is a light shielding wall (62, 262) which is erected from the edge (61c) on the outer peripheral side of the inner peripheral side reflecting wall toward the back direction and shields direct light (DL) from the light source toward the light emitting portion When is characterized Rukoto to Yusuke the connecting wall (66) which extends in a plate shape light shielding wall from the outer peripheral side reflecting wall, the.

  According to this invention, in the outer peripheral portion of the case body accommodating the circuit board, the inner peripheral side reflection wall and the outer peripheral side reflection wall are continuous. Therefore, the rigidity of the case body can be easily secured. In addition, the outer peripheral side reflection wall is formed avoiding the space in which the inner peripheral side reflection wall is projected in the back direction. By thus avoiding the overlapping of the outer peripheral reflection wall and the inner peripheral reflection wall, the formation of the continuous outer peripheral reflection wall and the inner peripheral reflection wall becomes easy to realize. Then, the light emitted from the light source is emitted from the light emitting portion while being diffused by being reflected by the inner peripheral side reflection wall and the outer peripheral side reflection wall. Therefore, the display device can realize the maintenance of the rigidity of the case body and the light emission of the light emitting unit with the unevenness reduced while mass productivity is ensured.

  Note that the reference numerals in the parentheses above merely show an example of the correspondence with specific configurations in the embodiments to be described later in order to facilitate understanding of the present invention, and limit the scope of the present invention in any way. It is not a thing.

FIG. 5 is a front view of a combination meter according to an embodiment of the present invention. It is a figure which shows the mechanical structure of a combination meter, Comprising: It is the II-II sectional view taken on the line of FIG. It is a figure which shows the detail of illumination structure. It is the IV-IV sectional view taken on the line of FIG. It is a figure which shows the modification of FIG.

  A combination meter 100 according to an embodiment of the present invention shown in FIG. 1 is a display device for a vehicle mounted on a vehicle. The combination meter 100 is accommodated in an instrument panel provided in a vehicle compartment of a vehicle. The combination meter 100 is attached to an instrument panel or the like with the display area 11 on the front side shown in FIG. 1 facing the driver's seat. In the following description, the direction in which the display area 11 of the combination meter 100 is directed is referred to as a front direction FD, and the direction opposite to the front direction FD is referred to as a back direction BD (see FIG. 2).

  The combination meter 100 displays various information on the vehicle in the display area 11. In the display area 11, in addition to the tachometer 10, for example, it is possible to provide a plurality of pointer display units such as a speedometer, a hybrid system indicator, a water thermometer, a fuel gauge, an oil temperature gauge, and a battery residual gauge.

  The tachometer 10 is formed in a circular shape in the display area 11. The tachometer 10 displays the rotational speed of the output shaft of the internal combustion engine mounted on the vehicle as a pointer in the display area 11 as information. The display of the tachometer 10 is formed by the pointer 20 and the display plate 30 or the like. The pointer 20 rotates along the display plate 30. The pointer 20 has a pointer 21 extending along the radial direction RD of the tachometer 10. The pointer 21 is formed in a rod shape by a translucent resin material. The pointer 20 can cause the pointer 21 to emit light.

  The display plate 30 shown in FIGS. 1 and 2 is formed in a thin plate shape from a translucent resin material such as polycarbonate resin. A plurality of light emitting designs 13 are formed on the display plate 30 by printing or the like using a light shielding property and a light transmitting property. The light emitting design 13 emits light by transmitting light in the front direction FD. The light emission design 13 has a scale 14, a numeral 15, and a zone portion 17 as a display configuration for indicating the rotational speed of the internal combustion engine.

  The graduations 14 are annularly arranged at intervals along the rotation path of the tip of the pointer 21. The numeral 15 is disposed on the inner peripheral side of the scale 14. The scale 14 and the numeral 15 are displayed in a luminous manner, for example, when the surroundings of the vehicle are dark, for example, at night and in a tunnel. The zone portion 17 is provided on the outer peripheral side of the scale 14 and is located at the edge 11 a of the display area 11. The zone portion 17 is shaped so as to extend in a strip shape with the circumferential direction of the tachometer 10 as the extension direction ED. The zone portion 17 indicates the upper limit region of the rotational speed of the internal combustion engine, that is, a so-called red zone by being displayed in red. For example, when the combination meter 100 is in the operating state, the zone unit 17 is always displayed by light.

  The pointer 20 and the display plate 30 described above are accommodated in the case 50 together with the circuit board 40. The circuit board 40 is formed in a plate shape, and is disposed along the display plate 30 in the back direction BD of the display plate 30. The circuit board 40 is formed with an electronic circuit for displaying information of the vehicle on the display area 11. The display board light source 41 and the zone light source 42 are mounted on the mounting surface located in the front direction FD among the both surfaces of the circuit board 40. The display board light source 41 can emit light that causes the scale 14 and the numeral 15 to emit light. The zone light source 42 can emit light that causes the zone portion 17 to emit light. Each of the light sources 41 and 42 is, for example, a light emitting diode or a cold cathode tube. In addition, on the circuit board 40, a stepper motor for rotating the pointer 20, and a microcomputer for controlling light emission of the light sources 41 and 42 and rotation of the stepper motor are mounted.

  The housing 50 is configured by mutually assembling the front panel 51, the peripheral wall member 52, the case main body 53, the rear cover 54, and the like. The front panel 51 is formed of a translucent resin material. The peripheral wall member 52, the case main body 53, and the rear cover 54 are formed of a resin material such as polypropylene resin and ABS resin. The peripheral wall member 52 has a peripheral wall portion 52a. The peripheral wall 52 a has a shape surrounding the periphery of the display area 11 to form a facing plate (window plate) of the display area 11. A front panel 51 is fitted to an end of the peripheral wall portion 52a in the front direction FD.

  The case body 53 is located in the back direction BD of the peripheral wall member 52. The case main body 53 supports the peripheral wall 52a, the display plate 30, and the like from the back side, and supports the circuit board 40 from the front side. The rear cover 54 is formed in a bottomed container shape, and is attached to the case main body 53 from the rear side. The case body 53 and the rear cover 54 form a space for housing the circuit board 40.

  Next, the details of the illumination structure 70 for causing the zone portion 17 to emit light will be described based on FIGS.

  The combination meter 100 is provided with an illumination structure 70 for illuminating the zone portion 17 in order to realize the light emission of the zone portion 17 independent of the scale 14 and the numeral 15. As shown in FIGS. 2 and 3, the illumination structure 70 is configured by a plurality of wall portions and the like provided in the back surface direction BD of the zone portion 17 in the case main body 53. The illumination structure 70 has a function of guiding the light emitted from the zone light source 42 to the zone portion 17.

  The zone light source 42 is located out of the projection range PA of the circuit board 40 where the zone portion 17 is projected in the back direction BD. The arrangement of the zone light source 42 is caused by the difficulty in the arrangement of the zone light source 42 because the projection range PA immediately below the zone portion 17 is the outer edge 40 a of the circuit board 40. Therefore, the zone light source 42 is located closer to the center of the circuit board 40 than the projection range PA. A plurality (three) of the zone light sources 42 are mounted within the circuit board 40 in a range closer to the inner peripheral side of the tachometer 10 than the zone section 17. The plurality of zone light sources 42 are arranged on the circuit board 40 at equal intervals along the circumferential direction of the tachometer 10 which is the extension direction ED of the zone portion 17.

  The case main body 53 is a plurality of wall portions constituting the illumination structure 70 between the display plate 30 and the circuit board 40, and the inner peripheral side reflection wall 61, the light shielding wall 62, the outer peripheral side reflection wall 64, and the connection wall 66. have.

  The inner peripheral side reflection wall 61 is located between the zone light source 42 and the display plate 30. The inner peripheral side reflection wall 61 is slightly curved, extends along the circumferential direction of the tachometer 10, and is formed in a plate shape slightly curved on the inner peripheral side. The inner peripheral side reflection wall 61 is inclined in the front direction FD as it goes to the outer peripheral side. The edge portion 61 b on the inner peripheral side of the inner peripheral side reflection wall 61 supports the circuit board 40 on the inner peripheral side of the zone light source 42. The edge portion 61 c on the outer circumferential side of the inner circumferential side reflection wall 61 supports the display plate 30 on the outer circumferential side of the zone light source 42. The inner peripheral side reflection wall 61 forms a first reflection wall surface 61a and a display reflection wall surface 61d.

  The first reflection wall surface 61 a is a wall surface located in the back direction BD among both surfaces of the light shielding wall 62. The first reflection wall surface 61a is located in the front direction FD of the zone light source 42, and can reflect the illumination light IL emitted from the zone light source 42 toward the outer peripheral side. The display reflection wall surface 61 d is a wall surface located in the front direction FD among both surfaces of the light shielding wall 62. The display reflection wall surface 61 d can reflect the illumination light IL emitted from the display plate light source 41 toward each scale 14 in the front direction FD.

  The light shielding wall 62 is erected in a plate shape from the edge portion 61 c on the outer peripheral side of the inner peripheral side reflection wall 61 toward the back surface direction BD. The light blocking wall 62 is slightly curved along the circumferential direction of the tachometer 10. The light shielding wall 62 is integrally configured with the inner peripheral side reflecting wall 61. The light shielding wall 62 is located on the outer peripheral side of the zone light source 42 and on the inner peripheral side of the zone portion 17. The light blocking wall 62 can block the direct light DL directed from the zone light source 42 toward the zone portion 17 between the zone light source 42 and the zone portion 17. The light shielding wall 62 forms a top surface 62 a facing the circuit board 40. The top surface 62 a is formed in a planar shape along the plate surface direction of the circuit board 40. The top surface 62a can reflect the light emitted from the zone light source 42 toward the outer peripheral side.

  The light shielding wall 62 forms a recessed groove 63 between itself and the inner circumferential reflection wall 61. The recessed groove 63 is located in the front direction FD of the zone light source 42, and is recessed from the top surface 62 a of the light shielding wall 62 in the front direction FD. The recessed groove 63 extends in the circumferential direction of the tachometer 10 in the same manner as the inner peripheral side reflection wall 61 and the light shielding wall 62. By the formation of the concave groove 63, the width of the first reflection wall surface 61a in the radial direction RD is expanded.

  The outer peripheral side reflection wall 64 is positioned on the outer peripheral side of the inner peripheral side reflection wall 61 and in the back direction BD of the zone portion 17. The outer peripheral reflecting wall 64 is extended along the circumferential direction of the tachometer 10 while being slightly curved toward the inner peripheral side. The outer peripheral side reflection wall 64 is erected toward the inner peripheral side from the outer peripheral wall 65 formed to surround the outer peripheral side of the circuit board 40 in the case main body 53. The outer peripheral side reflection wall 64 is erected in a posture inclined with respect to the outer peripheral wall 65. The outer peripheral side reflection wall 64 brings the top surface 64 d located at the tip end in the standing direction into contact with the circuit board 40. The outer peripheral side reflection wall 64 is inclined in the back direction BD as it goes to the inner peripheral side, similarly to the inner peripheral side reflection wall 61. The outer peripheral side reflection wall 64 supports the circuit board 40 by the edge 64 b on the inner peripheral side including the top surface 64 d.

  The outer peripheral side reflection wall 64 is continuous with the inner peripheral side reflection wall 61 to form a cylindrical surrounding wall which surrounds the entire circumference of each zone light source 42 (see FIG. 3). The outer peripheral side reflection wall 64 is formed to avoid the projection space PS obtained by projecting the inner peripheral side reflection wall 61 in the rear direction BD. Therefore, the edge 64 b on the inner circumferential side of the outer circumferential reflection wall 64 is located on the outer circumferential side of the edge 61 c on the outer circumferential side of the inner circumferential reflection wall 61. The outer peripheral side reflection wall 64 forms a second reflection wall surface 64a on the outer peripheral side of the first reflection wall surface 61a. The second reflection wall surface 64a faces the first reflection wall surface 61a in the radial direction RD. The outer peripheral side reflection wall 64 can reflect the illumination light IL from the zone light source 42 reflected by the inner peripheral side reflection wall 61 toward the zone portion 17 in the front direction FD by the second reflection wall surface 64a.

  The connection wall 66 shown in FIG. 3 and FIG. 4 is disposed in the middle of the adjacent zone light sources 42 in the extending direction ED. The two connection walls 66 are located on the outer peripheral side of the zone light source 42 and are offset from the zone light source 42 in the circumferential direction. The connection wall 66 extends from the outer peripheral side reflection wall 64 and the outer peripheral wall 65 toward the light shielding wall 62 along the radial direction RD, and forms a substantially triangular plate-shaped reinforcing portion. The connection wall 66 connects the inner peripheral reflection wall 61 and the outer peripheral reflection wall 64 together with the light shielding wall 62. The height of the connecting wall 66 is higher than the height of each zone light source 42. The connection wall 66 forms a pair of reflective side surfaces 66a. The reflective side surfaces 66a are inclined so as to be closer to each other in the front direction FD. The connection wall 66 can reflect the illumination light IL emitted from each zone light source 42 by each reflection side surface 66 a toward the outer peripheral side reflection wall 64 and the zone portion 17.

  According to this embodiment described so far, the case main body 53 has a cylindrical structure in which the inner peripheral side reflection wall 61 and the outer peripheral side reflection wall 64 are connected in the outer peripheral portion. With such a structure, securing of the rigidity of the case main body 53 and hence the housing 50 is facilitated. In addition, the outer peripheral side reflection wall 64 is formed to avoid the projection space PS obtained by projecting the inner peripheral side reflection wall 61 in the back direction BD. As described above, in the configuration in which the overlapping of the outer peripheral reflecting wall 64 and the inner peripheral reflecting wall 61 is avoided, the formation of the continuous outer peripheral reflecting wall 64 and the inner peripheral reflecting wall 61 becomes easy to realize.

  In detail, in general, the case main body 53 integrally forming the outer peripheral reflection wall 64 and the inner peripheral reflection wall 61 is formed by resin molding using a mold. If the overlapping of the outer peripheral side reflection wall 64 and the inner peripheral side reflection wall 61 is avoided in the molding of the case main body 53 as described above, two molds in which the front direction FD and the rear direction BD are respectively demolding directions Formation of these reflective walls 61 and 64 is realized. As described above, if a mold having a simple configuration can be used for manufacturing the case main body 53, mass productivity of the case main body 53 is ensured.

  Then, the light emitted from the zone light source 42 is emitted from the zone portion 17 while being diffused by being sequentially reflected by the inner peripheral side reflecting wall 61 and the outer peripheral side reflecting wall 64. Therefore, the combination meter 100 can realize the maintenance of the rigidity of the housing 50 and the light emission of the zone portion 17 with the unevenness reduced while mass productivity is ensured.

  In addition, in the present embodiment, the direct light DL which tries to reach the zone portion 17 linearly from the zone light source 42 is blocked by the light shielding wall 62. Therefore, the occurrence of uneven light emission in the zone portion 17 due to the direct light DL is avoided. In addition, the light shielding wall 62 provided upright from the inner peripheral side reflecting wall 61 can function as a rib for reinforcing the inner peripheral side reflecting wall 61. Therefore, the light shielding wall 62 can contribute to the improvement of the rigidity of the inner peripheral side reflection wall 61, and hence the case main body 53 and the housing 50.

  Further, the top surface 62 a of the light shielding wall 62 in the present embodiment directs a part of the illumination light IL incident on the top surface 62 a to the outer peripheral side reflection wall 64 due to the planar shape along the plate surface direction of the circuit board 40. Can be reflected. As a result, the amount of light passing through the zone portion 17 can be increased. As described above, the light shielding wall 62 can contribute to the improvement of the brightness of the zone portion 17.

  Furthermore, according to the present embodiment, the formation of the concave groove 63 enlarges the first reflection wall surface 61a. According to the above, since the amount of light reflected by the inner peripheral side reflection wall 61 and transmitted through the zone portion 17 increases, the zone portion 17 can emit light more brightly. In addition, according to the formation of the concave groove 63, the entire inner peripheral reflection wall 61 is formed in a plate shape. As a result, it is possible to prevent the occurrence of dents in the inner peripheral side reflective wall 61 due to the sink of the resin material when resin molding the inner peripheral side reflective wall 61.

  In addition, as in the present embodiment, in the configuration in which the outer peripheral reflection wall 64 is erected from the outer peripheral wall 65, the outer peripheral reflection wall 64 can function as a rib that reinforces the outer peripheral wall 65. Therefore, the outer peripheral side reflection wall 64 can contribute to the improvement of the rigidity of the case main body 53. In addition, the outer peripheral side reflection wall 64 efficiently reflects the light reflected by the inner peripheral side reflection wall 61 toward the zone portion 17 in the front direction FD by the posture inclined with respect to the outer peripheral wall 65. Can.

  Further, the top surface 64 d of the outer peripheral side reflecting wall 64 in the present embodiment is in contact with the circuit board 40. Therefore, the leakage of light from between the outer peripheral side reflection wall 64 and the circuit board 40 can be prevented. According to the above, since the decrease in the amount of light passing through the zone portion 17 is suppressed, the zone portion 17 can emit light more brightly.

  Furthermore, in the case where the zone portion 17 has a shape extending in a band shape as in the present embodiment, by providing a connecting wall 66 connecting the inner peripheral side reflecting wall 61 and the outer peripheral side reflecting wall 64, these reflecting walls 61, The reflective wall 64 can have a more rigid and continuous structure. In addition, according to the function of reflecting the illumination light IL by the reflective side surface 66a, the amount of light passing through the zone portion 17 can be further increased. Therefore, the rigidity improvement of the case main body 53 and the housing 50 is realized while the light emission luminance of the zone portion 17 is increased.

  In the present embodiment, the zone unit 17 corresponds to a "light emitting unit", the zone light source 42 corresponds to a "light source", the case 50 corresponds to a "case body", and the combination meter 100 is a "display device". It corresponds to

(Other embodiments)
As mentioned above, although one Embodiment by this invention was described, this invention is not limited and interpreted to the said embodiment, It applies to various embodiment and the combination in the range which does not deviate from the summary of this invention. be able to.

  In the above embodiment, the recessed groove 63 is formed between the inner peripheral side reflection wall 61 and the light shielding wall 62 which are respectively formed in a plate shape, but the shape of the recessed groove can be appropriately changed. For example, as in the first modification shown in FIG. 5, a concave groove 263 extending in the circumferential direction may be formed at the center of the top surface 262 a of the light shielding wall 262. Even with the concave groove 263 having such a shape, the effect of suppressing the generation of sink marks on the inner peripheral side reflection wall 261 can be exhibited.

  The inner peripheral side light shielding wall in the above embodiment is formed with a substantially constant wall thickness. Therefore, the first reflection wall surface 61a and the display reflection wall surface 61d are formed substantially in parallel. However, the first reflecting wall surface and the display reflecting wall surface can be formed in different inclined postures in order to efficiently reflect the emitted light of each light source. In such a configuration, the inner light shielding wall may be shaped to gradually change the wall thickness.

  Although the zone part 17 which shows a red zone was illustrated as a light emission part provided in edge 11a of display field 11 in the above-mentioned embodiment, a light emission part is not limited to a zone part as mentioned above. For example, the light emitting unit may be a plurality of indicators formed in a bar-shaped area provided at the upper edge of the display area. The indicator is, for example, a light emission display of a warning such as a brake and a remaining amount of fuel. Furthermore, the light emitting unit may be an image formed on a liquid crystal display panel as a display plate. The illumination structure can also transmit and illuminate the image formed at the edge of the liquid crystal display panel.

  The circuit board 40 in the above-described embodiment has the outer edge 40 a positioned in the projection range PA of the zone portion 17 by being disposed with a gap of about several millimeters between the circuit board 40 and the outer peripheral wall 65. However, as long as the gap provided between the circuit board and the outer peripheral wall is expanded, the entire circuit board may be disposed outside the projection range.

  The connecting wall 66 in the above embodiment is configured to connect the two reflecting walls 61 and 64 in cooperation with the light shielding wall 62. However, the form of the connection wall can be changed as appropriate. The connection wall may extend along the radial direction RD so as to directly connect the first reflection wall surface and the second reflection wall surface as long as the mass productivity of the case body is not impaired. Furthermore, the connecting wall can be omitted.

  The shape of the light shielding wall blocking the direct light DL in the above embodiment can be appropriately changed according to the positional relationship between the zone portion and the zone light source. In addition, the light shielding wall can be omitted as long as the direct light DL reaching the light emitting portion is slight and light emission unevenness of the light emitting portion does not occur.

  As mentioned above, although the example in which the red zone of a tachometer is reliably light-emitting and displayed by applying this invention to the combination meter for vehicles was demonstrated, the application scope of this invention is not limited to such a form. For example, the present invention can also be applied to a light emitting design formed on a pointer display unit different from a tachometer, and a display device that emits light and displays the indicator and the liquid crystal display unit as described above. Furthermore, the present invention is applicable not only to display devices mounted on vehicles, but also to general display devices used for various consumer devices, various transport devices, and the like.

11 display area 11a edge portion 17 zone portion (light emitting portion) 30 display board 40 circuit board 42 zone light source (light source) 50 case (case body) 61, 261 inner peripheral side reflecting wall edge 61c edge Part, 62, 262 light shielding wall, 62a, 262a top surface, 63, 263 concave groove, 64 outer peripheral side reflection wall, 64 d top surface, 65 outer peripheral wall, 66 connection wall, 100 combination meter (display device), BD rear direction, FD front direction, ED extension direction, DL direct light, PA projection range, PS projection space

Claims (8)

A display device in which a light emitting unit (17) for emitting light by transmitting light is formed at an edge (11a) of a display area (11) for displaying information,
A display plate (30) forming the light emitting unit;
A circuit board (40) disposed along the display plate in the back direction (BD) of the display plate;
Among the circuit boards, it is outside the projection range (PA) obtained by projecting the light emitting part in the back direction, and is located closer to the center of the circuit board than the projection range and emits light for emitting the light emitting part A light source (42)
An inner reflection wall (61, 261) positioned between the light source and the display plate for reflecting light emitted from the light source toward the outer periphery, and an inner circumference located in the back direction of the light emitting portion And a case body (50) for accommodating the circuit board, comprising: an outer peripheral reflection wall (64) for reflecting light reflected by the side reflection wall toward the light emitting portion in the front direction (FD); ,
The outer peripheral side reflecting wall is formed to avoid a space (PS) obtained by projecting the inner peripheral side reflecting wall toward the rear,
The case body is
A light shielding wall (62, 262) which is erected from the edge portion (61c) on the outer peripheral side of the inner peripheral side reflection wall toward the back surface and shields direct light (DL) directed from the light source to the light emitting portion;
Display device comprising Rukoto to have a, a connecting wall (66) which extends in a plate shape on the light shielding wall from the outer peripheral side reflective wall. The circuit board facing the top surface (62a, 262a) among the light-shielding wall, a display device according to claim 1, characterized in that it is formed in a planar shape along the plate surface direction of the circuit board . The display device according to claim 1 or 2 , wherein a recessed groove (63, 263) recessed in the front direction is formed between the inner peripheral side reflection wall and the light shielding wall. The case body further includes an outer peripheral wall (65) surrounding an outer peripheral side of the circuit board,
The display device according to any one of claims 1 to 3 , wherein the outer peripheral reflection wall is erected from the outer peripheral wall in a posture inclined with respect to the outer peripheral wall. The display device according to claim 4 , wherein the outer peripheral side reflection wall supports the circuit board by a top surface (64d) positioned at a front end in a standing direction. The display device according to any one of claims 1 to 5, wherein the connection wall connects the inner peripheral reflection wall and the outer peripheral reflection wall together with the light shielding wall. The light emitting portion has a shape extending in a band shape,
A plurality of the light sources are arranged on the circuit board along an extension direction (ED) of the light emitting unit,
The connecting wall is positioned offset with respect to the circumferential direction each said light source at an outer peripheral side of each of the light sources, according to claim 1, wherein the joint Guko and said light-shielding wall and the outer peripheral side reflective wall The display apparatus as described in any one. The display device according to any one of claims 1 to 7, wherein the connection wall reflects the light emitted from the light source toward the outer peripheral reflection wall.

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