JP6911894B2 - Vehicle display device - Google Patents

Description

The present invention relates to a vehicle display device mounted on a vehicle.

Patent Document 1 includes a transillumination type dial on which numbers and scales corresponding to rotation speed as vehicle information are printed, and a liquid crystal display panel for displaying various vehicle information, and these dials and a liquid crystal display panel are provided. Are arranged side by side in the same plane, and the light from the light source is reflected on the visual side and superimposed on the display contents of the dial and the liquid crystal display panel to display information. The structure for arranging the transparent display board having the above is shown.

Japanese Unexamined Patent Publication No. 2016-114423

However, in Patent Document 1, first, since the dial and the liquid crystal display panel are arranged in the same plane and side by side, there is no relative sense of depth between them. Secondly, since the distance between the reflective part of the transparent display plate and the liquid crystal display panel is uniquely determined by the position of the dial, the relative depth between the two in the combination of the transparent display plate and the liquid crystal display panel. Grants between are relatively limited.

In this way, since the depth is connected to the stereoscopic effect of the display, conventionally, the relative stereoscopic effect between the display of the dial and the reflective part and the display of the liquid crystal display panel is poor, and in particular, the liquid crystal display panel and the reflection are poor. There is a problem that it is not possible to effectively connect the various variable displays unique to the department to a three-dimensional effect.

The present invention has been made in view of the problems described above, and an object of the present invention is for a vehicle capable of improving the relative three-dimensional effect between the display of the dial and the reflective portion and the liquid crystal display panel. The purpose is to provide a display device.

Invention Nohi convex represented opened is a vehicle display device mounted on a vehicle,
A dial (20) that displays the index unit (22) corresponding to vehicle information on the visual side, and
An image display panel (40) that emits and displays an image on the visual side, and
A light transmissive display board (50) provided with reflective portions (54a, 54b) that reflect light from a light source (70) arranged on the visual side of the dial and the image display panel.
An image control unit (82) that controls an image and
A light source control unit (83) that controls turning on and off of the light source is provided.
The reflecting unit is a reflecting element that reflects the light from the light source to the visual side, and is arranged along the longitudinal direction (ED) of the light transmissive display plate to form a design (60a, 60b). Has a reflective element (56) of
The ends (62a, 62b, 63a, 63b) of the design extend toward the region of the light transmissive display plate facing the image display panel.
The image display panel displays extended images (IEA, IEB, IE1, IE2) provided linearly so as to further extend the end of the pattern as an image.
The design and the extended image are displayed in cooperation ,
The design can be switched between display and non-display as the light source turns on and off.
The image display panel, when the light source is off, shall be the hide at least part of the extension image.
Further, another one of the disclosed inventions is a vehicle display device mounted on a vehicle.
A dial (20) that displays the index unit (22) corresponding to vehicle information on the visual side, and
An image display panel (40) that emits and displays an image on a display surface (40a) facing the visual side, and
A light transmissive display board (50) provided with reflective portions (54a, 54b) that reflect light from a light source (70) arranged on the visual side of the dial and the image display panel.
An image control unit (82) that controls an image and
A light source control unit (83) for controlling a light source is provided.
The reflecting unit is a reflecting element that reflects the light from the light source to the visual side, and is arranged along the longitudinal direction (ED) of the light transmissive display plate to form a design (60a, 60b). Has a reflective element (56) of
The design has a shape that extends from a region of the light transmissive display plate where the display surfaces do not face, and positions the ends (62a, 62b, 63a, 63b) in the region of the light transmissive display plate where the display surfaces face each other. can be,
The image display panel displays, as an image, extended images (IEA, IEB, IE1, IE2) provided linearly so as to further extend the end portion extended to a position facing the display surface.
The design and the extended image are displayed in cooperation with each other.

It should be noted that the reference numerals in parentheses are limited to exemplifying the corresponding configurations in the embodiments described later, and are not intended to limit the contents of the invention in order to facilitate understanding of the contents of the description.

It is a front view which shows the display device for a vehicle of 1st Embodiment, and shows one display example in the case of display type A. It is an exploded perspective view which shows the display device for a vehicle of 1st Embodiment. It is sectional drawing which shows typically the display device for a vehicle of 1st Embodiment. It is sectional drawing which shows typically the light-transmissive display board of 1st Embodiment. It is an enlarged perspective view which shows typically the reflective element of 1st Embodiment. It is a front view which shows the display device for a vehicle of 1st Embodiment, and shows the case where the light source for a display board is turned off. It is a front view which shows the display device for a vehicle of 1st Embodiment, and shows one display example in the case of display type B. It is a front view which shows the display device for a vehicle of 1st Embodiment, and shows one display example in the case of display type C. It is a front view which shows the display device for a vehicle of 1st Embodiment, and shows one display example in the case of display type C. It is a front view which shows the display device for a vehicle of 1st Embodiment, and shows one display example in the case of display type D. It is a front view which shows the display device for a vehicle of 1st Embodiment, and shows one display example in the case of display type D. It is a front view which shows the display device for a vehicle of 1st Embodiment, and shows one display example in the case of display type E. It is a front view which shows the display device for a vehicle of 2nd Embodiment, and shows one display example. It is a front view which shows the display device for a vehicle of 2nd Embodiment, and shows one display example. It is a partially enlarged view for demonstrating the direction of the reflection surface of each reflection part of 2nd Embodiment. It is a front view which shows the display device for a vehicle of 3rd Embodiment. It is a schematic cross-sectional view of the light transmission display board for demonstrating the reflective element in the gradation region of 3rd Embodiment. It is a front view which shows the display device for a vehicle of 4th Embodiment, and shows one display example. It is a front view which shows the display device for a vehicle of 4th Embodiment, and shows one display example. It is a figure for demonstrating the control of the light emitting element of 4th Embodiment, and shows the case where the moving body image fades in. It is a figure for demonstrating the control of the light emitting element of 4th Embodiment, and shows the case where the moving body image is stopped in the center. It is a flowchart by the display device for a vehicle of 4th Embodiment. It is a front view of the display device for a vehicle of 5th Embodiment, and shows the mounted state in a vehicle. It is a flowchart by the display device for a vehicle of 5th Embodiment. It is an exploded perspective view which shows the display device for a vehicle of 6th Embodiment. It is sectional drawing which shows typically the display device for a vehicle of 6th Embodiment. It is a schematic diagram for demonstrating the difference between the case where a light transmissive display plate is a flat plate type, and the case where it is a curved plate shape. It is a front view for demonstrating the symbol of 6th Embodiment. It is a flowchart by the display device for a vehicle of 6th Embodiment. It is a front view which shows the display device for a vehicle of 6th Embodiment, and shows one display example. It is a front view which shows the display device for a vehicle of 6th Embodiment, and shows one display example. It is a figure corresponding to FIG. 4 in the modification 5.

Hereinafter, a plurality of embodiments of the present invention will be described with reference to the drawings. In addition, duplicate description may be omitted by assigning the same reference numerals to the corresponding components in each embodiment. When only a part of the configuration is described in each embodiment, the configuration of the other embodiment described above can be applied to the other parts of the configuration. Further, not only the combination of the configurations specified in the description of each embodiment, but also the configurations of a plurality of embodiments can be partially combined even if the combination is not specified. ..

(First Embodiment)
As shown in FIG. 1, the vehicle display device 100 according to the first embodiment of the present invention is mounted on a vehicle and installed on an instrument panel facing a seat on which an occupant who visually recognizes the device 100 sits. The vehicle display device 100 can display vehicle information toward the visual side where the occupant is located. The vehicle equipped with the vehicle display device 100 is, for example, a hybrid vehicle including both an engine and an electric motor as a driving means.

As shown in FIGS. 2 and 3, such a vehicle display device 100 includes a case unit 10, a dial 20, a pointer 30, an image display panel 40, an image control unit 82, a light transmissive display plate 50, and a display plate. The light source 70 and the light source control unit 83 are provided. The case portion 10 has a back case 12 and a wind plate 14 having a light-shielding property, and a light-transmitting plate 16 which is arranged on the most visible side in the device 100 and has a light-transmitting property. The light-transmitting plate 16 is formed in a plate shape by a light semi-transparent resin such as a colored acrylic resin. The transmittance of the light transmitting plate 16 is set to about 30% due to smoke-like coloring, but it may be set to an arbitrary value of 30% or more.

The dial 20 is arranged on the back side of the light transmitting plate 16 and the light transmitting display plate 50. The back side is the side opposite to the visual side. The dial 20 is formed in a flat plate shape by partially applying light semitransparent or light-shielding printing on the surface of a base material made of a light-transparent synthetic resin on the visual side. Instead of printing, painting may be applied.

Such a dial 20 has an index unit 22 corresponding to vehicle information on the visual side. The index unit 22 forms the outline of an index such as characters or scales on the dial 20 by being surrounded by light-shielding printing and being subjected to translucent printing. The index unit 22 of the dial 20 may include characters, scales, or marks corresponding to vehicle information, and even if the name is "dial", the characters do not necessarily have to be included. ..

The index unit 22 is illuminated from the back side by the light emitting element 28 for index lighting mounted on the main circuit board 80 located on the back side of the dial 20.

Further, in the index unit 22 of the present embodiment, in accordance with the pointer 30 described later, the character and scale indicating the engine speed are shown in the left area of the dial 20, and the character and scale indicating the remaining fuel amount are shown in the upper right area, and the right side. In the lower area, letters and scales indicating the temperature of the engine cooling water are arranged.

A total of three pointers 30 are provided, one corresponding to the left area of the dial 20, one corresponding to the upper right area, and one corresponding to the lower right area. Each pointer 30 integrally has a connecting portion 32 and an indicating portion 34. The connecting portion 32 is arranged through a through hole formed in the dial 20 and is connected to the rotating shaft of the stepping motor 36 held by the main circuit board 80. The indicator 34 is arranged between the dial 20 and the light transmissive display plate 50, and has a needle shape. The instruction unit 34 of each pointer 30 is adapted to rotate according to the output of the stepping motor 36, and by instructing each index unit 22 arranged in a partial annular shape in the left and right regions of the dial 20. , Vehicle information is displayed.

In the present embodiment, the pointer 30 corresponding to the left region displays the engine speed as vehicle information. The pointer 30 corresponding to the upper right area displays the remaining fuel amount as vehicle information. The pointer 30 corresponding to the lower right region displays the water temperature of the engine cooling water as vehicle information.

The image display panel 40 is arranged between the main circuit board 80 and the dial 20 so as to face the back side of the dial 20. A gap is provided between the dial 20 and the image display panel 40. In the present embodiment, the image display panel 40 is arranged so as to correspond to the central region of the dial 20. Therefore, the image display panel 40 is arranged so as to be sandwiched between the displays by the left and right pointers 30.

The image display panel 40 of the present embodiment is a liquid crystal panel using a thin film transistor, and is an active matrix type liquid crystal panel formed of a plurality of liquid crystal pixels arranged in a two-dimensional direction. The image display panel 40 emits and displays an image by emitting display light from the rectangular display surface 40a facing the visual side to the visual side by illuminating the backlight 42 from the back side. There is.

The image control unit 82, which is particularly shown in FIG. 2, is mounted on, for example, the main circuit board 80 and has at least one processor, memory, and input / output interface. The processor can control the image of the image display panel 40 via the input / output interface, for example, by executing a computer program stored in the memory.

Here, in the central region of the dial 20 where the image display panel 40 faces, printing is not performed, so that the light-transmitting base material of the dial 20 is exposed. Therefore, the central region of the dial 20 is set as a transmission region 24 having light transmission so that the display light of the image of the image display panel 40 is transmitted. The transmission region 24 is arranged in a size slightly smaller than the display surface 40a. Such a transparent region 24 is surrounded by a light-shielding region 26 having a light-shielding property by black printing, so that the outline thereof is formed in a rectangular shape.

The light-transmitting display plate 50 is formed in a flat plate shape, for example, by a synthetic resin having light-transmitting property. The light transmissive display plate 50 is arranged on the visual side of the dial 20 and the pointer 30, and is provided substantially parallel to the dial 20. Therefore, the side-by-side direction ED of the light-transmitting display plate 50 is along the side-by-side direction of the display surface 20a and the side-by-side direction of the dial 20, and the plate thickness direction TD of the light-transmissive display board 50 is displayed. It is along the direction perpendicular to the surface 20a and the plate thickness direction of the dial 20. The plate thickness direction TD of the present embodiment substantially coincides with the surface of the light transmissive display plate 50 having the largest area in the vertical direction. The light transmissive display plate 50 has a substantially rectangular shape so as to cover the entire surface of the dial 20 from the visual side.

As shown in FIG. 2, the display board light source 70 has two light emitting units 72a and 72b that are separated from each other on the left and right sides. The light emitting portions 72a and 72b are arranged along the outer edge portion 52. More specifically, each of the light emitting portions 72a and 72b is formed by arranging a plurality of light emitting elements 73a and 73b that emit light from a light source along the outer edge portion 52 of the light transmissive display plate 50. Each of the light emitting elements 73a and 73b is a light emitting diode mounted on the circuit board 81 for a light source, and emits light when connected to a power source. In particular, in the present embodiment, the light emitting elements 73a and 73b are multicolor light emitting diodes. Therefore, the display board light source 70 of the present embodiment includes a color light source.

More specifically, each light emitting element 73a in the light emitting unit 72a faces the side surface of the outer edge portion 52 on the lower side of the outer edge portion 52 of the light transmissive display plate 50. Similarly, each light emitting element 73b in the light emitting unit 72b faces the side surface of the outer edge portion 52 on one lower side of the outer edge portion 52 of the light transmissive display plate 50. By emitting the light source light toward the side surfaces of the light emitting elements 73a and 73b facing each other, the light source light travels from the lower side to the upper side inside the light transmissive display plate 50. The light sources of the light emitting elements 73a and 73b incident on the inside of the light transmissive display plate 50 via the outer edge portion 52 illuminate the illumination range in which a part of the light emitting elements 73a and 73b is deviated from each other in the longitudinal direction ED. .. It is preferable that the light source 70 for the display board is arranged so as not to be seen by the occupants, but a part of the front view is shown by a solid line for explanation.

The light source control unit 83 is mounted on the main circuit board 80, for example, and has at least one processor, a memory, and an input / output interface. The processor can control the light source 70 for the display board via the input / output interface, for example, by executing a computer program stored in the memory. Specifically, the light source control unit 83 can switch the lighting and extinguishing of the light emitting elements 73a and 73b of the light source 70 for the display board. Further, the light source control unit 83 can change the emission color of each of the light emitting elements 73a and 73b to various colors. In particular, in the present embodiment, the light source control unit 83 switches between lighting and extinguishing and changes the emission color for each of the light emitting units 72a and 72b.

As shown in FIGS. 1 to 4, the light transmissive display plate 50 has reflecting portions 54a and 54b in a partial region. In particular, in the present embodiment, two reflecting portions 54a and 54b are arranged corresponding to the left and right light emitting portions 72a and 72b. The areas displayed by the reflecting portions 54a and 54b in FIGS. 1 and 2 are indicated by hatching of diagonal lines (the same applies to the corresponding figures below).

More specifically, as shown in FIGS. 4 and 5, each of the reflecting portions 54a and 54b has a plurality of reflecting elements 56 arranged along the longitudinal direction ED of the light transmissive display plate 50. Each reflecting element 56 is set to a fine size and is formed in a concave hole shape recessed from the back side of the light transmissive display plate 50 into the inside of the display plate 50. Each reflecting element 56 has a reflecting surface 57a and an inclined back surface 57b.

The reflecting surface 57a is arranged in the reflecting element 56 so as to face the light emitting portion 72a or 72b. The reflective surface 57a is formed in a curved surface. The reflecting surface 57a extends in an inclined direction inclined with respect to the plate thickness direction TD of the light transmissive display plate 50. The inclination direction is preferably set in the range of, for example, 39 to 45 degrees with respect to the plate thickness direction TD.

The inclined back surface 57b is provided so as to face the side opposite to the reflection surface 57a, and is arranged back to back with the reflection surface 57a. The inclined back surface 57b is formed in a plane shape that is inclined by, for example, 25 degrees with respect to the plate thickness direction TD. That is, the inclined back surface 57b is set to have an inclination angle smaller than the inclination of the reflecting surface 57a.

In the reflecting portions 54a and 54b, the reflecting elements 56 are arranged one by one so as to be separated from each other by the flat portion 58 formed flat along the side-by-side direction ED of the light transmissive display plate 50. ing. In particular, in the present embodiment, the densities of the reflecting elements 56 in the reflecting portions 54a and 54b are substantially the same at each location, and the shape of the reflecting element 56 is also substantially the same at each location.

When the light source light reaches such a reflection unit 54a from the light emitting unit 72a of the light source 70 for the display board, the light source light is reflected to the visual side by the reflecting surface 57a of each reflecting element 56 facing the light emitting unit 72a. Become. Similarly, when the light source light reaches the reflecting unit 54b from the light emitting unit 72b of the light source 70 for the display board, the light source light is reflected to the visual side by the reflecting surface 57a of each reflecting element 56 facing the light emitting unit 72b. Become. Therefore, as shown in FIGS. 1 and 2, when the light emitting unit 72a corresponding to the one reflecting unit 54a is turned on, the symbol 60a composed of the reflecting elements 56 arranged in the reflecting unit 54a is displayed shiningly. .. Similarly, when the light emitting unit 72b corresponding to the one reflecting unit 54b is turned on, the symbol 60b composed of the reflecting elements 56 arranged in the reflecting unit 54b is displayed shiningly.

The symbols 60a and 60b of the present embodiment are outer peripheral symbols 61a and 61b arranged symmetrically with each other corresponding to the left and right regions, respectively. The outer peripheral pattern 61a formed by the reflecting portion 54a is formed linearly so as to border the index portion 22 in the region corresponding to the outer peripheral portion of the index portion 22 on the left side of the light transmissive display plate 50. For example, it has an arc shape. Both ends 62a and 63a of the outer peripheral pattern 61a extend to a region of the light transmissive display plate 50 facing the image display panel 40. The outer peripheral pattern 61b formed by the reflecting portion 54b is formed linearly so as to border the index portion 22 in the region corresponding to the outer peripheral portion of the index portion 22 on the left side of the light transmissive display plate 50. For example, it has an arc shape. Both ends 62b and 63b of the outer peripheral pattern 61b extend to a region of the light transmissive display plate 50 facing the image display panel 40.

The outer peripheral symbols 61a and 61b can be displayed by not only switching between display and non-display as the corresponding light emitting units 72a and 72b are turned on and off, but also by individually changing the color by including a color light source. It has become. As shown in FIG. 6, when the corresponding light emitting portions 72a and 72b are not displayed, the outer peripheral symbols 61a and 61b are almost entirely visible from the visual side due to the setting of the size and density of the reflecting element 56. Not visible.

The lighting and extinguishing of the light emitting units 72a and 72b and the color change are controlled in cooperation with the image displayed by the image display panel 40. The image display type can be selected and set according to the preference of the occupant by, for example, a changeover switch provided on the vehicle, and is temporarily changed depending on the vehicle mode and the situation of peripheral monitoring by the vehicle peripheral monitoring device. There is also a display type.

The display type A shown in FIG. 1 is a display type that digitally displays the speed of the vehicle as vehicle information in the image by the character image ILT. When the eco mode is not selected in the vehicle, the light emitting portions 72a and 72b emit white light, so that the outer peripheral symbols 61a and 61b are also displayed in white. On the other hand, when the eco mode is selected, the light emitting units 72a and 72b are changed in color so as to emit green light, and the outer peripheral symbols 61a and 61b are also displayed in green. The eco-mode is a mode in which vehicle control is performed so as to suppress the engine speed to a low level, for example.

In the display type B shown in FIG. 7, the speed of the vehicle as vehicle information is digitally displayed by the character image ILT in the image, and the current value of the electric motor as other vehicle information is displayed on the scale image ISC by the pointer image IPO. It is a display type that displays analog by instructing. When the eco mode is not selected in the vehicle, the light emitting portions 72a and 72b emit white light, so that the outer peripheral symbols 61a and 61b are also displayed in white. On the other hand, when the eco mode is selected, the light emitting units 72a and 72b are changed in color so as to emit green light, and the outer peripheral symbols 61a and 61b are also displayed in green.

The display type C shown in FIGS. 8 and 9 is a display type in which the gear position is displayed on the left side of the display surface 40a and the speed of the vehicle is displayed on the right side by the character image ILT, and various information is displayed in the center of the display surface 40a. ..

In this display type C, when the idle stop mode is not selected in the vehicle, as shown in FIG. 8, the light emitting portions 72a and 72b emit white light, so that the outer peripheral symbols 61a and 61b also become white. Is displayed. At this time, the image display panel 40 further extends the lower ends 62a and 62b of the outer peripheral symbols 61a and 61b, and is provided linearly so as to connect the lower ends 62a and 62b to each other. Display image IE1. In addition, the image display panel 40 further extends the upper ends 63a and 63b of the outer peripheral symbols 61a and 61b, and the extended image IE2 is provided linearly so as to connect the upper ends 63a and 63b to each other. Is displayed.

On the other hand, as shown in FIG. 9, when the idle stop mode is selected in the vehicle, the light emitting unit 72a on the left side is turned off, so that the outer peripheral symbol 61a on the left side is hidden and the light emitting unit 72b on the right side is white. By turning on, the outer peripheral symbol 61b on the right side is displayed in white. Along with this, the extended image IE1 is hidden and the extended image IE2 remains displayed. The idle stop mode of the vehicle is a mode in which the vehicle is controlled so as to automatically and temporarily stop the engine when the vehicle is stopped at a traffic light, for example.

Further, as shown in FIGS. 10 and 11, when the auto cruise mode is set in the vehicle as the display type D, the gear position is displayed on the left side of the display surface 40a and the speed of the vehicle is displayed on the right side by the character image ILT. At the same time, the road condition such as whether or not a vehicle is present in front of the display surface 40a is displayed in the center of the display surface 40a. In this display, the image display panel 40 displays an extended image IEA provided linearly so as to further extend the lower end 62a of the ends 62a, 63a of the outer peripheral symbol 61a. Similarly, the image display panel 40 displays an extended image IEB provided linearly so as to further extend the lower end 62b of the ends 62b, 63b of the outer peripheral symbol 61b. Each of the extended images IEA and IEB sandwiches the vehicle image ICA in the display of the road condition on the left and right, and extends linearly from the corresponding ends 62a and 62b toward the center of the display surface 40a, so that the occupant can see. It can be recognized as an image representing the outside line of the road (for example, a white line).

These extended images IEA, IEB and outer peripheral symbols 61a, 61b are displayed in white as shown in FIG. 10 when the peripheral monitoring device does not detect an obstacle in the periphery. On the other hand, when the peripheral monitoring device detects an obstacle on the side outside the vehicle, as shown in FIG. 11, only the extension image and the outer peripheral design on the left and right sides where the obstacle is detected are colored amber (orange). Be changed. For example, in FIG. 11, since an obstacle is detected on the right side outside the vehicle, only the extension image IEB on the right side and the outer peripheral design 61b are changed in color to amber (orange). In FIG. 11, the color-changed portion is represented by dot hatching.

Further, as shown in FIG. 12, as the display type E, when the vehicle continues to travel on the highway for a long time, the gear position is displayed on the left side of the display surface 40a and the speed of the vehicle is displayed on the right side. At the same time, an image prompting a break is displayed in the center of the display surface 40a. At this time, the image display panel 40 further extends the lower ends 62a and 62b of the outer peripheral symbols 61a and 61b, and is provided linearly so as to connect the lower ends 62a and 62b to each other. Display image IE1. In addition, the image display panel 40 further extends the upper ends 63a and 63b of the outer peripheral symbols 61a and 61b, and the extended image IE2 is provided linearly so as to connect the upper ends 63a and 63b to each other. Is displayed. Therefore, the image prompting a break is visually recognized as if the entire circumference is surrounded by the extended images IE1 and IE2 and the outer peripheral symbols 61a and 61b. These extended images IE1 and IE2 and the outer peripheral symbols 61a and 61b are displayed in amber (orange) for alerting, respectively.

In this way, the vehicle display device 100 displays the image of the image display panel 40 and the symbols 60a and 60b configured by the reflecting element 56 in cooperation with each other.

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

Since the vehicle display device 100 has the configuration as in the first embodiment, the image display panel 40 is not arranged side by side in the same plane with respect to the dial 20, but is the back surface of the dial 20. Since it is arranged on the side, the sense of depth of the image display panel 40 with respect to the dial 20 and the light transmissive display board 50 is increased as compared with the side-by-side state. Then, the image of the image display panel 40 can reach the direction of the light transmissive display plate 50 through the transmission region 24 of the dial 20. By increasing the sense of depth of the image display panel 40 in this way, in the combination of the display by the reflecting portions 54a and 54b of the dial 20 and the light transmissive display board 50 and the display of the image display panel 40, these are relative to each other. It can be expected to have a special effect of improving the three-dimensional effect.

Further, according to the first embodiment, a plurality of reflecting elements 56 are arranged in the side-by-side direction ED of the light transmissive display plate 50 to form the symbols 60a and 60b. Since these symbols 60a and 60b are displayed as if they protrude from the image display panel 40 to the visual side, the stereoscopic effect becomes more special.

Further, according to the first embodiment, the image display panel 40 is linearly provided as an image so as to further extend the ends of the linear outer peripheral symbols 61a, 61b. Display IE2. By making the extended images IEA, IEB, IE1, and IE2 appear to be continuous with the outer peripheral symbols 61a and 61b, the index unit 22, the reflection units 54a, 54b, and the image display panel 40 are connected to each other while giving a three-dimensional effect. A sense of unity can be obtained in between.

Further, according to the first embodiment, since the light source 70 includes a color light source in which the colors of the symbols 60a and 60b can be changed, it is possible to produce various appearances according to the situation while giving a three-dimensional effect.

(Second Embodiment)
As shown in FIGS. 13 to 15, the second embodiment of the present invention is a modification of the first embodiment. The second embodiment will be described focusing on the points different from those of the first embodiment.

In the second embodiment, as shown in FIGS. 13 and 14, as the index unit 222, the left area of the dial 220 has characters and scales indicating the engine speed, and the right area has characters and scales indicating the speed of the vehicle. Have been placed. Correspondingly, a total of two pointers 30 are provided, one corresponding to the left region of the dial 220 and one corresponding to the right region.

Similar to the first embodiment, the image display panel 40 faces the back side of the dial 220 and is arranged so as to correspond to the central region of the dial 220. The central region of the dial 220 is set as a transmission region 24 so that the display light of the image of the image display panel 40 is transmitted.

The light transmissive display plate 250 of the second embodiment has two reflecting portions 254a and 254b so as to form different symbols 260a and 260b. The reflecting portion 254a is provided at a position of the light transmissive display plate 250 facing the upper region of the image display panel 40. The reflecting portion 254b is provided at a position of the light transmissive display plate 250 facing the lower region of the image display panel 40.

The display board light source 270 of the second embodiment has two light emitting units 272a and 272b. The light emitting unit 272a corresponds to the reflecting unit 254a. In the light emitting portion 272a, each light emitting element 273a faces the side surface of the outer edge portion 252 on the upper side of the outer edge portion 252 of the light transmissive display plate 250. Each light emitting element 273a emits light source light toward the side surface, so that the light source light travels from the upper side to the lower side inside the light transmissive display plate 250.

The reflecting surfaces 257a of each reflecting element 256a in the reflecting portion 254a face upwards in the same direction as each other. That is, the light emitting portion 272a is arranged at a position of the outer edge portion 252 facing the reflecting surface 257a of the corresponding reflecting portion 254a. When the light source light reaches the reflecting unit 254a from the light emitting unit 272a, the light source light is reflected to the visual side by the reflecting surface 257a of each reflecting element 256a facing the light emitting unit 272a. Therefore, when the light emitting unit 272a is turned on, the symbol 260a is displayed shining by each of the reflecting elements 256a arranged in the reflecting unit 254a.

The light emitting unit 272b corresponds to the reflecting unit 254b. In the light emitting portion 272b, each light emitting element 273b faces the side surface of the outer edge portion 252 on the left side of the outer edge portion 252 of the light transmissive display plate 250. Each light emitting element emits light source light toward the side surface, so that the light source light travels from the left side to the right side inside the light transmissive display plate 250.

The reflecting surface 257b of each reflecting element 256b in the reflecting portion 254b faces the left side in the same direction as each other. That is, the light emitting portion 272b is arranged at a position of the outer edge portion 252 facing the reflecting surface 257b of the corresponding reflecting portion 254b. In this way, the reflecting surface 257a of the reflecting portion 254a and the reflecting surface 257b of the reflecting portion 254b are oriented 90 degrees different from each other as shown in FIG.

When the light source light reaches the reflecting unit 254b from the light emitting unit 272b, the light source light is reflected to the visual side by the reflecting surface 257b of each reflecting element 256b facing the light emitting unit 272b. Therefore, when the light emitting unit 272b is lit, the symbol 260b is displayed shining by each of the reflecting elements 256b arranged in the reflecting unit 254b.

In such an arrangement of the light emitting portions 272a and 272b and the reflecting portions 254a and 254b, the light from the light emitting portion 272a can reach the reflecting portion 254b, but the reflecting surface 257b of the reflecting portion 254b is the reflecting surface 257a of the reflecting portion 254a. Are facing different directions, not facing the light emitting unit 272a. Therefore, even if the light emitting unit 272a is turned on, it is suppressed that the symbol 260b by the reflecting unit 254b is illuminated and displayed.

Here, the symbol 260a configured by the reflecting portion 254a includes the contour symbol 261a in which the appearance contour is expressed among the display objects. In particular, the display object of the present embodiment is a vehicle, and the outline pattern 261a expresses the appearance contour of the vehicle.

The symbol 260b composed of the reflecting portion 254b represents a vehicle, which is a vehicle bird's-eye view symbol 261b that is a bird's-eye view of the vehicle from the rear and above.

FIG. 13 shows a state in which the light emitting unit 272a is turned on and the light emitting unit 272b is turned off. In this state, the contour symbol 261a is displayed, but the vehicle bird's-eye view symbol 261b is not displayed. Correspondingly, the image display panel 40 superimposes the internal image IIS on which the internal state of the display object is expressed on the contour pattern 261a and displays it. In particular, in the present embodiment, since the display object is a vehicle, the internal image IIS expresses the internal state of the vehicle. For example, the internal image IIS displays the engine and the storage battery at a position matched to the contour pattern 261a, and the moving image in which energy flows between the engine, the electric motor, and the storage battery is used to control the hybrid system of the vehicle at present. Show if it is.

FIG. 14 shows a state in which the light emitting unit 272a is turned off and the light emitting unit 272b is turned on. In this state, the contour symbol 261a is hidden, but the vehicle bird's-eye view symbol 261b is displayed. Correspondingly, the image display panel 40 displays a navigation image INV expressing the surrounding roads and townscapes. The navigation image INV can navigate the occupant to the destination by displaying, for example, an arrow that turns to the right.

According to the second embodiment described above, the reflecting surfaces 257a and 257b face each other in the same direction in the same reflecting portion 254a or 254b, and face different directions among the different reflecting portions 254a and 254b. Corresponding to each of the reflecting units 254a and 254b, the light emitting units 272a and 272b emit light toward the opposing reflecting surfaces 257a and 257b, respectively. By doing so, by turning on or off the light emitting units 272a and 272b individually, it is possible to display a plurality of different symbols 260a and 260b on the same light transmissive display board 250.

Further, according to the second embodiment, the image display panel 40 superimposes the internal image IIS in which the internal state of the display object is expressed as an image on the contour symbol 261a in which the appearance contour is expressed in the display object. Let me display it. According to such a superposed display, the contour pattern 261a is displayed as if it protrudes to the visual side, so that the occupant of the vehicle can accurately recognize the display object by the appearance contour. Then, since the internal state is separately displayed on the rear side, the occupant of the vehicle can avoid being confused with the external contour and can accurately recognize the internal state. In this way, it is possible to realize a display with high visibility utilizing a three-dimensional effect.

(Third Embodiment)
As shown in FIGS. 16 and 17, the third embodiment of the present invention is a modification of the first embodiment. The third embodiment will be described focusing on the points different from those of the first embodiment.

As shown in FIG. 16, the display board light source 370 of the third embodiment has two light emitting units 372a and 372b which are separated from each other, as in the first embodiment. However, in the third embodiment, in the light emitting portions 372a and 372b, the light emitting elements 373a and 373b face the side surface of the outer edge portion 352 on the upper side of the outer edge portion 352 of the light transmissive display plate 350. There is. Each of the light emitting elements 373a and 373b emits the light source light toward the side surface, so that the light source light travels from the upper side to the lower side inside the light transmissive display plate 50.

Two reflecting portions 354a and 354b are arranged corresponding to the left and right light emitting portions 372a and 372b, respectively. Each of the reflecting portions 354a and 354b has a gradation region GRD. As an example is schematically shown in FIG. 17, in the gradation region GRD, at least one of the recessed dimension of the reflecting element 56 and the density of the reflecting element 56 gradually changes depending on the location. Since the amount of light source light reflected from the light emitting units 372a and 372b to the visual side differs depending on the location, the display brightness of the symbols 60a and 60b by each reflecting element 56 changes in a gradation shape in the gradation region GRD. It becomes. In FIG. 16, the gradation is schematically expressed by changing the thickness of the diagonal hatching.

According to the third embodiment described above, the reflecting portions 354a and 354b have a gradation region GRD in which the display brightness of the symbols 60a and 60b is changed in a gradation shape by gradually changing the shape or density of the reflecting element 56. Therefore, the three-dimensional effect can be emphasized.

(Fourth Embodiment)
As shown in FIGS. 18 to 22, the fourth embodiment of the present invention is a modification of the first embodiment. The fourth embodiment will be described focusing on the points different from those of the first embodiment.

The display board light source 470 of the fourth embodiment has one light emitting unit 472, as shown in 20 and 21 in particular. In the light emitting unit 472, each light emitting element 473 faces the side surface of the outer edge portion 452 on the lower side of the outer edge portion 452 of the light transmissive display plate 450.

On the other hand, the light source control unit 483 of the fourth embodiment individually switches between lighting and extinguishing for each light emitting element 473 of the light emitting unit 472.

The reflection unit 454 of the fourth embodiment is provided including a portion of the light transmissive display plate 450 that faces the image display panel 40. In particular, the reflection portion 454 of the present embodiment is provided including a portion of the image display panel 40 facing the lower side. More specifically, the reflecting portion 454 is provided at a portion of the dial 20 facing the lower side.

In the fourth embodiment, the symbol 460 configured by each reflecting element 56 of the reflecting portion 454 is a ground symbol 461 expressing the ground. Specifically, the ground symbol 461 has a plurality of horizontal lines extending parallel to the left and right, and vertical lines extending vertically and narrowing the distance from each other toward the top. Then, the perspective of the ground is expressed by forming the ground pattern 461 in a grid pattern with the horizontal lines and the vertical lines.

With respect to such a ground symbol 461, the light emitting elements 473 are arranged along the outer edge portion 452, so that the ground symbols 461 are directed toward a portion of the ground symbol 461 that is deviated from each other in the direction in which the light emitting elements 473 are arranged. It is designed to emit light. As a result, it is possible to display only a part of the ground symbol 461 corresponding to the lit light emitting element 473.

The image display panel 40 of the fourth embodiment can display a moving body image IMV in which a moving body is represented. In particular, in the present embodiment, since the vehicle is adopted as the moving body, the moving body image IMV is a vehicle image representing the vehicle.

The process executed by the vehicle display device 400 (mainly the image control unit 482 and the light source control unit 483) of the fourth embodiment will be described with reference to the flowchart of FIG. At the start of the flowchart of FIG. 22, it is assumed that the image of the image display panel 40 is in the non-display state and the vehicle start switch 402 is in the off state. The start switch 402 is slightly different depending on the vehicle, but corresponds to, for example, an ignition switch for starting an engine and a power switch for an electric vehicle.

First, in step S410, it is determined whether or not the vehicle start switch 402 has been changed from the off state to the on state. If an affirmative determination is made in step S410, the process proceeds to step S420. If a negative determination is made in step S410, the determination in step S410 is performed again after a predetermined time or according to a predetermined opportunity.

In step S420, as shown in FIGS. 18 and 20, the moving body image IMV fades in from the right side to the center of the display surface 40a in the image control unit 482. In conjunction with the fade-in, the light source control unit 483 sequentially switches the light emitting element 473 to be lit from the light emitting element 473 on the left side to the adjacent light emitting element 473 on the right side. That is, the light emitting element 473 that lights up shifts in the direction opposite to the moving direction of the moving body image. In this way, it is possible to produce an effect as if the vehicle as a moving body is running. After the process of step S420, the process proceeds to step S430.

In step S430, particularly as shown in FIGS. 19 and 21, when the moving body image IMV moves to the center of the display surface 40a, the moving body image is displayed while being stopped at the center. Similar to step S420, the light source control unit 483 sequentially switches the light emitting element 473 to be lit from the light emitting element 473 on the left side to the adjacent light emitting element 473 on the right side. For example, the light source control unit 483 shifts the light emitting elements 473 that are turned on in order so that the three light emitting elements 473 that are continuously arranged are turned on between the light emitting elements 473 that are turned off. In this way, even if the moving body image IMV is stopped without moving, it is possible to produce an effect as if the vehicle as a moving body is running. A series of processes is completed in step S430.

According to the fourth embodiment described above, among the plurality of light emitting elements 473 that emit light toward a portion displaced from each other, the light emitting element 473 that lights up is switched. By such switching, the symbol 460 is partially displayed, the symbol 460 can be moved, and the three-dimensional effect can be emphasized.

Further, according to the fourth embodiment, the light emitting element 473 that lights up is sequentially switched to the adjacent light emitting element in accordance with the moving body image IMV displayed by the image display panel 40. By doing so, since the displayed part of the ground symbol 461 appears to move, the moving body image IMV can be made to appear as if it is moving. Therefore, the cooperation between the ground pattern 461 by the reflection unit 454 and the moving body image IMV by the image display panel 40 can create a sense of unity as well as a three-dimensional effect.

(Fifth Embodiment)
As shown in FIGS. 23 and 24, the fifth embodiment of the present invention is a modification of the first embodiment. The fifth embodiment will be described focusing on the points different from those of the first embodiment.

The vehicle equipped with the vehicle display device 500 of the fifth embodiment includes a moving obstacle detection unit 503 that detects a moving obstacle. The moving obstacle detection unit 503 includes at least one peripheral monitoring sensor such as a millimeter wave radar, sonar, and lidar (LIDER: Light Detection and Ranging / Laser Imaging Detection and Ranging), and moves obstacles such as pedestrians around the vehicle. Objects can be detected.

The display board light source 570 of the fifth embodiment has one light emitting unit 572. In the light emitting unit 572, each light emitting element 573 is arranged on the upper side of the outer edge portion 552 of the light transmissive display plate 550 and faces the side surface of the outer edge portion 552.

On the other hand, the light source control unit 582 of the fifth embodiment individually switches between lighting and extinguishing for each light emitting element 573 of the light emitting unit 572. Further, the light source control unit 582 of the fifth embodiment can communicate with the moving obstacle detection unit 503 via, for example, the ECU of the vehicle.

In the fifth embodiment, the symbol 60 composed of the reflecting elements 56 of the reflecting unit 554 becomes a moving obstacle motion symbol 561 in which a plurality of moving obstacles are arranged side by side according to the direction in which the light emitting elements 573 are arranged. There is. Specifically, the moving obstacle motion symbol 561 of the present embodiment is a symbol representing a state in which a pedestrian as a moving obstacle crosses a pedestrian crossing side by side for each motion.

With respect to such a moving obstacle motion symbol 561, each light emitting element 573 is arranged along the outer edge portion 552, so that a part of the symbol 561 that is deviated from each other in the direction in which the light emitting element 573 is arranged. It is designed to emit light toward. As a result, it is possible to display only one motion corresponding to the light emitting element 573 that lights up among the moving obstacle motion symbols 561.

The process executed by the vehicle display device 500 (mainly the light source control unit 582) of the fifth embodiment will be described with reference to the flowchart of FIG. 24.

First, in step S510, the light source control unit 582 determines whether or not the pedestrian 504 moving left and right in front of the vehicle is detected by the input signal from the moving obstacle detection unit 503. If an affirmative determination is made in step S510, the process proceeds to step S520. If a negative determination is made in step S510, the determination in step S510 is performed again after a predetermined time or according to a predetermined opportunity.

In step S520, the light source control unit 582 sequentially switches the lit light emitting element 573 to the adjacent light emitting element 573 according to the moving direction of the pedestrian 504. In this way, the motions of the pedestrians displayed in the moving obstacle motion symbol 561 are sequentially switched, and it is possible to produce an effect in which the pedestrian walks like a flip book.

Here, the light source control unit 582 may switch each light emitting element 573 so that the brightness gradually changes, instead of switching between lighting and extinguishing instantaneously. Then, the motion adjacent to the motion having the highest display brightness is expressed like an afterimage, and the appearance is improved.

Further, when the pedestrian 504 stops in the middle of the pedestrian crossing, the light source control unit 582 may suspend the switching of the light emitting element 573 that lights up in conjunction with the temporary stop. After the process of step S520, the process proceeds to step S530.

In step S530, the light source control unit 582 determines whether the detected pedestrian 504 has moved from the front outside the vehicle to another location. If an affirmative determination is made in step S530, the process proceeds to step S540. If a negative determination is made in step S530, the display of the moving obstacle motion symbol 561 is continued, and the determination in step S510 is performed again after a predetermined time or according to a predetermined opportunity.

In step S540, the light source control unit 582 turns off all the light emitting elements 583 and ends the display of the moving obstacle motion symbol 561. A series of processes is completed in step S540.

According to the fifth embodiment described above, among the plurality of light emitting elements 573 that emit light toward a portion displaced from each other, the light emitting element 573 that lights up is switched. By such switching, the symbol 561 is partially displayed, the symbol 561 can be moved, and the three-dimensional effect can be emphasized.

Further, according to the fifth embodiment, when the moving obstacle detection unit 503 detects a pedestrian 504 as a moving obstacle, the light emitting element 573 that lights up in accordance with the pedestrian 504 moves to the adjacent light emitting element 573. It switches in sequence. In this way, the expressions of the pedestrian 504 represented by the movement obstacle motion symbol 561 are displayed in order, and the existence of the pedestrian 504 can be accurately displayed to the occupants of the vehicle.

(Sixth Embodiment)
As shown in FIGS. 25 to 31, the sixth embodiment of the present invention is a modification of the first embodiment. The fifth embodiment will be described focusing on the points different from those of the first embodiment.

In the vehicle display device 600 of the sixth embodiment, as shown in FIGS. 25 and 26, the light transmissive display plate 650 is formed in a curved plate shape by, for example, a light transmissive synthetic resin. Specifically, the surface 651 on the visual side of the light transmissive display plate 650 is formed in a curved surface shape in which the central portion is recessed toward the back surface side. In particular, the surface 651 on the visual side of the present embodiment has a cylindrical surface shape curved in the left-right direction of the vehicle.

External light such as sunlight or light from a light source in a vehicle may be incident on such a light transmitting display board 650 from the visual side, and these external lights are reflected by the light transmitting display board 650. There are times. Here, with reference to FIG. 27, the difference in the light reflection direction between the case where the light transmissive display plate has a flat plate shape and the case where the light transmissive display plate has a curved plate shape will be described. FIG. 27 shows a cross section of the vehicle display device 600 in the left-right direction. In FIG. 27, the area indicated by the ellipse is called the Illips ELP. The eye lip ELP is an eye range that statistically represents the distribution of the eye positions of the driver as a occupant as an ellipse (see JIS D0021: 1998 for details).

In the case of a flat plate-shaped light transmissive display plate (see the broken line in FIG. 27), consider the case where a predetermined external light Ai is incident on the outer peripheral portion in the right side region of the light transmissive display plate. The incident angle of the external light Ai with respect to the flat light transmissive display plate is α, and the locus of the reflected light Ar circumscribes the irips ELP of the right eye. Since the reflected light Cr of the external light Ci incident at an incident angle γ slightly larger than the incident angle α of the external light Ai passes on the left side of the reflected light Ar, it passes through the irips ELP. That is, the external light incident on the right side region at an incident angle larger than the incident angle α is likely to be visually recognized by the driver as an occupant.

On the other hand, in the case of the curved plate-shaped light transmissive display plate 650 (see the solid line in FIG. 27), when the outer peripheral portion in the right region of the light transmissive display plate 650 and the external light Bi having the same trajectory as the external light Ai are incident. think of. In this case, due to the curvature of the surface 651 on the visual side, the surface 651 on the visual side is inclined so as to face the central portion side slightly in the right region. The incident angle of is β, and the incident angle β is a considerably large value as compared with the incident angles α and γ. Therefore, the locus of the reflected light Br passes further to the left side of the left eye's eye lip ELP. Further, even if the incident light of the external light having the same trajectory as the external light Ci is incident, the reflected light passes further to the left side of the reflected light Br, so that it may be visually recognized by the driver as a occupant. , It is lower than the case of a flat plate-shaped light transmissive display board.

Further, the light transmissive display plate 650 of the sixth embodiment is provided with a through hole corresponding to the pointer 630. Since the connecting portion 632 of the pointer 630 penetrates the through hole of the light transmissive display plate 650, the indicator portion 634 of the pointer 630 is on the visual side of the light transmissive display plate 650 as shown in FIGS. Is located in.

The dial 620 of the sixth embodiment is formed in a curved plate shape having substantially the same curved shape as the light transmissive display plate 650. The dial 620 and the light transmissive display plate 650 are arranged close to each other with few gaps.

The dial 620 is formed with an index unit 622 similar to that of the first embodiment. As shown in FIG. 25, in the present embodiment, a scale and characters are arranged in the left region of the dial 620 as an index 622a indicating a situation corresponding to the current value of the electric motor of the vehicle. A scale and characters are arranged in the area to the right of the dial 620 as an index 622b for displaying the voltage value of the power supply battery of the electric motor of the vehicle.

The symbol 660 of the sixth embodiment has another index unit 659 provided in the region facing the index unit 622 in the left and right regions. The separate index unit 659 is similar to the index unit 622 in that it displays information by being instructed by the instruction unit 634 of the guideline 630, but displays information different from the information displayed by the index unit 622. It has become.

As shown in FIGS. 25 and 28, another index unit 659 of the present embodiment has an index symbol 661a in a region facing the index 622a and an index symbol 661b in a region facing the index 622b. The index symbol 661a has a scale and characters indicating the speed of the vehicle. The index symbol 661b has a scale and characters indicating the engine speed of the vehicle.

The light source control unit 683 of the sixth embodiment can control the index illumination light source 627 together with the display board light source 670. The index illumination light source 627 is configured by providing a plurality of index illumination light emitting elements 628 similar to those in the first embodiment. Specifically, the light source control unit 683 switches the lighting and extinguishing of each light emitting element 673 of the display board light source 670 and the lighting and extinguishing of each light emitting element 628 of the index lighting light source 627.

Similar to the first embodiment, the symbol 660 is in the display state when each light emitting element 673 is lit, and can be visually recognized from the visual side. However, when each light emitting element 673 is turned off, the symbol 660 is in a non-display state and is hardly visible from the visual side.

Further, the index unit 622 of the dial 620 is in a display state when each light emitting element 628 is lit, and can be visually recognized from the visual side. However, when each light emitting element 628 is turned off, the index unit 622 is in a non-display state, and it becomes difficult for the index unit 622 to be visually recognized.

Then, the light source control unit 683 is adapted to turn on one of the light emitting element 673 of the display board light source 670 and the light emitting element 628 of the index lighting light source 627 and turn off the other. As a result, only one of the separate index unit 659 of the light transmissive display plate 650 and the index unit 622 of the dial 620 is in the display state. The pointer 630 rotates according to the display state of the separate index unit 659 and the index unit 622. That is, the light source control unit 683 switches the referent indicated by the instruction unit 634 of the pointer 630 between the index unit 622 and another index unit 659.

The process executed by the vehicle display device 600 (mainly the light source control unit 683) of the sixth embodiment will be described with reference to the flowchart of FIG. 29. This flowchart is executed at a predetermined opportunity or at predetermined time intervals.

First, in step S610, the light source control unit 683 determines whether or not to display another index unit 659. The conditions for this determination can be set as appropriate. For example, the determination can be made by referring to the on / off state of the operation switch operated by the occupant. Further, for example, at the time of determination, it is possible to determine whether the vehicle is mainly driven by the engine or the electric motor. If an affirmative determination is made in step S610, the process proceeds to step S620. If a negative determination is made in step S610, the process proceeds to step S630.

In step S620, the light source control unit 683 turns on each light emitting element 673 of the display board light source 670 and turns off each light emitting element 628 of the index lighting light source 627. As a result, as shown in FIG. 30, the index symbols 661a and 661b of the separate index unit 659 are in the display state, and the index unit 622 is in the non-display state. Therefore, the referent indicated by the referent unit 634 is set in the separate index unit 659. The images of the index unit 662 and the image display panel 40 are partially superimposed and displayed. A series of processes is completed according to step S620.

In step S630, the light source control unit 683 turns off each light emitting element 673 of the display board light source 670 and turns on each light emitting element 628 of the index lighting light source 627. As a result, as shown in FIG. 31, the index symbols 661a and 661b of the separate index unit 659 are in the non-display state, and the index unit 622 is in the display state. Therefore, the referent indicated by the referent unit 634 is set in the index unit 622. A series of processes is completed according to step S630.

As shown in FIG. 30, a red zone index 629 corresponding to the index symbol 661b is formed on the dial 620. The red zone index 629 is controlled independently of the index unit 622. Specifically, when the index unit 622 is in the non-display state, the red zone index 629 is in the display state due to the illumination from the back side (see FIG. 30), and when the index unit 622 is in the display state, the illumination from the back side. Is stopped and becomes a hidden state (see FIG. 31).

According to the sixth embodiment described above, the light transmissive display plate 650 is formed in the shape of a curved plate. In this way, a part of the light transmissive display board 650 protrudes to the visual side with respect to the other area, so that a three-dimensional effect can be generated in the light transmissive display board 650.

Further, according to the sixth embodiment, the surface 651 on the visual side of the light transmissive display plate 650 is formed in a curved surface shape in which the central portion is recessed toward the back surface side. In this way, a three-dimensional effect is generated between the central portion and the outer peripheral portion of the light transmissive display plate 650. At the same time, it is possible to suppress the reflected light when the external light is reflected on the surface 651 from being visually recognized by the occupant, so that the visibility of each display is enhanced, and the relative three-dimensional effect due to the combination of these displays is achieved. Can be emphasized.

Further, according to the sixth embodiment, the display state of the symbol 660 is changed depending on the lighting state of the light source 670 for the display board, and the referent indicated by the referent unit 634 is switched between the index unit 622 and another index unit 659. .. In such switching, the range of display expression can be expanded by switching the referents according to the same guideline 630.

(Other embodiments)
Although a plurality of embodiments of the present invention have been described above, the present invention is not construed as being limited to those embodiments, and may be applied to various embodiments and combinations without departing from the gist of the present invention. Can be applied.

Specifically, as the first modification, the image display panel 40 is not limited to the liquid crystal panel, and a panel using an organic EL display may be adopted.

As a modification 2, the region of the dial 20 facing the image display panel 40 is a semitransparent region having light semitransparency if the light transmissive region is set so that the image of the image display panel is transmitted. It may be.

As a modification 3, the reflection surface 57a may be formed in a flat shape.

As a modification 4, the image control unit 82 and the light source control unit 83 may share a processor or the like.

As a modification 5, as shown in FIG. 32, the light transmissive display plate 50 has a flat outer edge reflecting surface 52b and an outer edge reflecting surface 52b, which are provided so as to be inclined to the rear side toward the outside in the outer edge portion 52. It may have an outer edge light guide portion 52a extending from 52b to the rear side. In the example of FIG. 25, a plurality of light emitting elements 73a and 73b of the light source 70 are arranged so as to face the front end surface on the back side of the outer edge light guide portion 52a. The light source light emitted from the plurality of light emitting elements 73a and 73b from different positions is guided to the outer edge reflecting surface 52b by the outer edge light guide unit 52a, and further reflected to the inside of the light transmissive display plate 50 by the outer edge reflecting surface 52b. Will be done. In this way, the light sources of the light emitting elements 73a and 73b incident on the inside of the light transmissive display plate 50 via the outer edge portion 52 illuminate the illumination range in which a part of the light emitting elements 73a and 73b is deviated from each other in the longitudinal direction ED. It has become like.

As a modification 6, the light source control unit 483, 582, 683 and the like are not limited to those using a program, and may be realized by a simpler circuit.
The technical features of the above-described embodiments are summarized as follows.
(Technical feature 1)
A vehicle display device mounted on a vehicle.
A dial (20,220,620) having an index unit (22,222,622) corresponding to vehicle information on the visual side, and
An image display panel (40), which is arranged facing the back side of the dial opposite to the visual side and displays an image by emitting light, and
Reflectors (54a, 54b, 254a, 254b, 354a, 354b, 454) that reflect light from light sources (70, 270, 370, 470, 570, 670) arranged on the visual side of the dial. With a light transmissive display board (50, 250, 350, 450, 550, 650) provided with 554),
The area of the dial on which the image display panel faces is set to be light transmissive so that the image of the image display panel can pass through that area.
In technical feature 1, by providing such a configuration, the image display panels are not arranged side by side in the same plane with respect to the dial, but are arranged on the back side of the dial. In addition, the sense of depth of the image display panel with respect to the dial and the light transmissive display board is increased as compared with the side-by-side state. Then, the image of the image display panel can reach the direction of the light transmissive display board through the light transmissive region of the dial. In this way, by increasing the sense of depth of the image display panel, the relative stereoscopic effect of the display by the reflecting portion of the dial and the light transmissive display board and the display of the image display panel is improved. You can expect a special effect.
(Technical feature 2)
In technical feature 1,
The reflecting unit is a reflecting element that reflects the light from the light source to the visual side, and is arranged along the longitudinal direction (ED) of the light transmissive display plate and has a design (60, 60a, 60b, 260a, 260b, It has a plurality of reflecting elements (56, 256a, 256b) constituting 460,660).
(Technical feature 3)
In technical feature 2,
The design includes an outer peripheral design (61a, 61b) formed linearly so as to border the index portion in a region of the light transmissive display plate corresponding to the outer peripheral portion of the index portion.
The ends (62a, 62b, 63a, 63b) of the outer peripheral pattern are extended to the region of the light transmissive display plate facing the image display panel.
The image display panel displays extended images (IEA, IEB, IE1, IE2) provided linearly so as to further extend the end portion of the outer peripheral pattern as an image.
(Technical feature 4)
In technical feature 2 or 3,
The light source includes a color light source in which the color of the symbol can be changed.
(Technical feature 5)
In any one of technical features 2 to 4,
A plurality of reflecting portions are provided so as to form different patterns on the same light transmissive display plate.
In the same reflecting part, each reflecting element has a reflecting surface (257a, 257b) facing each other in the same direction, and between different reflecting parts, the reflecting surface of each reflecting element faces in a different direction.
The light source has a plurality of light emitting portions (272a, 272b) arranged along the outer edge portion (252) of the light transmissive display plate.
Each light emitting portion corresponds to each reflecting portion individually, is arranged at a position of the outer edge portion facing the reflecting surface of the corresponding reflecting portion, and emits light toward the opposing reflecting surface.
(Technical feature 6)
In any one of technical features 2 to 5,
The symbol includes a contour symbol (261a) in which the appearance contour is expressed among the display objects.
The image display panel displays an internal image (IIS) representing the internal state of the display object as an image by superimposing it on the contour pattern.
(Technical feature 7)
In any one of technical features 2 to 6,
The reflecting unit has a gradation region (GRD) in which the display brightness of the symbol is changed in a gradation manner by gradually changing the shape or density of the reflecting element.
(Technical feature 8)
In technical feature 2,
Further equipped with a light source control unit (483, 582) for controlling the light source,
The light source has a plurality of light emitting elements (473,573) that can be individually switched on or off.
Each light emitting element emits light toward a part of the design that is offset from each other.
The light source control unit switches the light emitting element to be lit among the light emitting elements.
(Technical feature 9)
In technical feature 8,
The image display panel displays a moving body image (IMV) in which a moving body is represented as an image.
The design is a ground design (461) that expresses the ground.
The light source control unit sequentially switches the light emitting element to be lit to the adjacent light emitting element according to the moving body image.
(Technical feature 10)
In technical feature 8,
The vehicle is provided with a moving obstacle detection unit (503) for detecting a moving obstacle.
The symbol is a moving obstacle motion symbol (561) in which a plurality of moving obstacles are arranged side by side.
When the moving obstacle detection unit detects a moving obstacle, the light source control unit sequentially switches the light emitting element to be lit to the adjacent light emitting element according to the moving obstacle.
(Technical feature 11)
In any one of technical features 1 to 10,
The light transmissive display plate is formed in the shape of a curved plate.
(Technical feature 12)
In technical feature 11,
The surface (651) of the light transmissive display plate on the visual side is formed in a curved shape in which the central portion is recessed toward the back side.
(Technical feature 13)
In any one of technical features 1 to 12,
A pointer (630) is further provided, which is arranged on the visual side of the light transmissive display plate and has an instruction unit (634) which rotates to display information according to the instruction position.
(Technical feature 14)
In technical feature 2,
A pointer with a rotating indicator and
Further equipped with a light source control unit (683) for controlling the light source,
The symbol has a separate index unit (659) that displays information different from the information displayed by the index unit in the area facing the index unit.
The light source control unit changes the display state of the symbol depending on the lighting state of the light source, and switches the referent indicated by the instruction unit between the index unit and another index unit.
(Technical feature 15)
A vehicle display device mounted on a vehicle.
A dial (20) that displays the index unit (22) corresponding to vehicle information on the visual side, and
An image display panel (40) that emits and displays an image on the visual side, and
A light transmissive display plate (50) provided with reflective portions (54a, 54b) that reflect light from a light source (70) arranged on the visual side of the dial and the image display panel.
The reflecting unit is a reflecting element that reflects the light from the light source to the visual side, and is arranged along the longitudinal direction (ED) of the light transmissive display plate to form a design (60a, 60b). Has a reflective element (56) of
The design includes an outer peripheral design (61a, 61b) formed linearly so as to border the index portion in a region of the light transmissive display plate corresponding to the outer peripheral portion of the index portion.
The ends (62a, 62b, 63a, 63b) of the outer peripheral pattern are extended to the region of the light transmissive display plate facing the image display panel.
The image display panel displays extended images (IEA, IEB, IE1, IE2) provided linearly so as to further extend the end portion of the outer peripheral pattern as an image.
According to such a technical feature 15, the image display panel displays, as an image, an extended image provided linearly so as to further extend the end portion of the outer peripheral pattern. By making such an extended image appear to be continuous with the outer peripheral pattern, a sense of unity can be obtained between the index portion, the reflective portion, and the image display panel while creating a three-dimensional effect.
(Technical feature 16)
A vehicle display device mounted on a vehicle.
An image display panel (40) that emits and displays an image on the visual side, and
A light transmissive display plate (250) having a reflecting unit (254a) that reflects light from a light source (270) arranged on the visual side of the image display panel is provided.
The reflecting unit is a reflecting element that reflects the light from the light source to the visual side, and is a plurality of reflecting elements arranged along the longitudinal direction (ED) of the light transmissive display plate to form a design (260a). It has an element (256a) and
The symbol includes a contour symbol (261a) in which the appearance contour is expressed among the display objects.
The image display panel displays an internal image (IIS) representing the internal state of the display object as an image by superimposing it on the contour pattern.
According to such a technical feature 16, the image display panel superimposes an internal image expressing the internal state of the display object on the contour pattern expressing the appearance contour of the display object as an image. indicate. According to such a superposed display, the contour pattern is displayed as if it protrudes to the visual side, so that the occupant of the vehicle can accurately recognize the display object by the external contour. Then, since the internal state is separately displayed on the rear side, the occupant of the vehicle can avoid being confused with the external contour and can accurately recognize the internal state. In this way, it is possible to realize a display with high visibility utilizing a three-dimensional effect.

100,200,300,400,500,600 Vehicle display device, 20,220,620 dial, 40 image display panel, 50,250,350,450,550,650 light transmissive display board, 54a, 54b, 254a, 254b, 354a, 354b, 454,554 Reflector, 56,256a, 256b Reflector, 60,60a, 60b, 260a, 260b, 460,660 Design, 61a, 61b Outer design, 62a, 62b, 63a, 63b End, 70,270,370,470,570,670 Light source, 261a contour pattern, ED installation direction, IEA, IEB, IE1, IE2 extended image, IIS internal image

Claims (4)

A vehicle display device mounted on a vehicle.
A dial (20) that displays the index unit (22) corresponding to vehicle information on the visual side, and
An image display panel (40) that emits and displays an image on the visual side, and
A light transmissive display plate (50) provided with reflective portions (54a, 54b) that reflect light from a light source (70) arranged on the visual side of the dial and the image display panel.
An image control unit (82) that controls the image and
A light source control unit (83) for controlling turning on and off of the light source is provided.
The reflecting portion is a reflecting element that reflects the light from the light source to the visual side, and is arranged along the longitudinal direction (ED) of the light transmissive display plate to form a design (60a, 60b). Has a plurality of reflective elements (56)
The ends (62a, 62b, 63a, 63b) of the design extend toward the region of the light transmissive display plate facing which the image display panel faces.
The image display panel displays, as the image, extended images (IEA, IEB, IE1, IE2) provided linearly so as to further extend the end portion of the symbol.
The symbol and the extended image are displayed in cooperation with each other .
The symbol is switched between display and non-display as the light source is turned on and off.
The image display panel, when the light source is off, hide the vehicle display device you at least part of the extension image. A vehicle display device mounted on a vehicle.
A dial (20) that displays the index unit (22) corresponding to vehicle information on the visual side, and
Display surface facing the view side to the image display panel for displaying light emission images in (40a) (40),
A light transmissive display plate (50) provided with reflective portions (54a, 54b) that reflect light from a light source (70) arranged on the visual side of the dial and the image display panel.
An image control unit (82) that controls the image and
A light source control unit (83) for controlling the light source is provided.
The reflecting portion is a reflecting element that reflects the light from the light source to the visual side, and is arranged along the longitudinal direction (ED) of the light transmissive display plate to form a design (60a, 60b). Has a plurality of reflective elements (56)
FIG handle, the display surface of the light transmitting display plate is drawn from a region not opposed, ends in a region where the display surface faces of the light transmitting display plate (62a, 62b, 63a, 63 b ) Is the shape to position
The image display panel, as the image, the so display surface and a front SL end that extends to a position opposite to further extend, extended image provided linear (IEA, IEB, IE1, IE2 ) Show death,
A vehicle display device in which the symbol and the extended image are displayed in cooperation with each other. The vehicle display device according to claim 2 , wherein the light source control unit controls lighting and extinguishing of the light source according to the display of the image. The vehicle display device according to claim 2 or 3 , wherein the light source control unit controls the emission color of the light source according to the display of the image.

Images