JP5482304B2 - Display device - Google Patents

Description

  The present invention relates to a display device that can switch between indirect illumination display and direct illumination display.

  Patent document 1 is disclosing the display apparatus which displays the driving mode of a vehicle. In this apparatus, a first illumination state in which one symbol is illuminated with a common first color and a second illumination state in which one symbol is illuminated with a second color different from the common color are switched. White light is used as the first color. As the second color, orange or green is used. Further, in this apparatus, a plurality of symbols are arranged adjacent to each other. A light guide plate that guides light from the light source of the first color to the plurality of symbols is provided immediately below the plurality of symbols. The light guide plate extends under the plurality of symbols. A light source of the second color is placed immediately below each of the plurality of symbols.

JP 2004-233466 A

  The conventional technology including the light guide plate has a problem that the number of parts is large. In addition, the light guide plate has a problem of increasing the price of the display device.

  Furthermore, from another viewpoint, in the configuration of the related art, when one specific symbol is illuminated from the light source of the second color, the light may leak to other adjacent symbols through the light guide plate. Such light leakage has deteriorated the quality of illumination, also called illumination quality. In particular, in a dark environment such as at night, there is a problem that even a slight light leak is easily visible.

  Further, as disclosed in Patent Document 1, it has been proposed to improve the shape of the light guide plate in order to reduce light leakage via the light guide plate. However, there is a problem that the shape of the light guide plate is complicated.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a display device capable of realizing display by indirect illumination and display by direct illumination with a simple configuration.

  Another object of the present invention is to provide a display device that can reduce light leakage from one symbol to another with a simple configuration.

  Still another object of the present invention is to illuminate a plurality of symbols with the first light without using a light guide plate, and to illuminate one symbol with a second light different from the first light. However, it is providing the display apparatus which can reduce the leakage of the 2nd light to another symbol.

  The present invention employs the following technical means to achieve the above object.

The invention according to claim 1 is a display board (4) having a plurality of symbols (40) displayed by illumination from behind, and a light source device (6) having a plurality of light sources (60) for illuminating the symbols. ,
A partition member (5) disposed between the display plate and the light source device;
The plurality of symbols are a plurality of first mode symbols (43R, 42N, 42D, 42P) indicating a plurality of modes, and a first operation symbol indicating a method of operating the selection device for selecting one of the plurality of first modes ( 41F), a second mode symbol (42B) indicating a combination mode that can be selected only in a specific mode corresponding to one of the plurality of first mode symbols, and a second operation method of the selection device for selecting the combination mode. 2 operation symbols (41M)
The plurality of light sources are a first indirect light source (61NR, 61DF, 61PF) that indirectly illuminates a first operation symbol (41F) and a plurality of first mode symbols (43R, 42N, 42D, 42P), a second operation. symbol (41M) and a second indirect light source (61BM), a plurality of first direct light source for directly illuminating a plurality of first mode symbol indirectly illuminate the second mode symbol (42B) (63R, 62N, 62D 62P), and a second direct light source (62B) that directly illuminates the second mode symbol,
The partition member (5) has an opening at one end arranged behind the first operation symbol, and a first indirect vertical cylinder (50F) that defines a vertical through hole extending in a vertical direction from the light source device toward the display plate, A second indirect vertical cylinder (50M) having an opening at one end disposed behind the second operation symbol and defining a vertical through hole extending in the vertical direction from the light source device toward the display panel, and a plurality of first mode symbols A plurality of first direct vertical cylinders having an opening at one end arranged at the back and an opening at the other end surrounding the first direct light source and defining a vertical through hole extending in the vertical direction from the light source device toward the display plate ( 50R, 50N, 50D, 50P), having an opening at one end arranged behind the second mode symbol and an opening at the other end surrounding the second direct light source, and extending in the vertical direction from the light source device toward the display plate. The second direct vertical cylinder (50B) that defines the vertical through hole, the first in the vertical direction Contacting the light source (61NR, 61DF, 61PF) covers, through vertical through-hole and communicating the plurality of first in direct vertical cylinder through a plurality of first direct vertical cylinder communicating port formed at a position closer to the light source device, Furthermore, a first horizontal cylinder (51NR, 51DF, 51PF) that defines a recess communicating with a vertical through hole in the first indirect vertical cylinder through a communication port formed at a position close to the light source device of the first indirect vertical cylinder, And the second indirect light source (61BM) with respect to the vertical direction, communicated with the vertical through hole in the second direct vertical cylinder through a communication port formed at a position close to the light source device of the second direct vertical cylinder, and second possess indirect vertical tubular second transverse cylinder defining a longitudinal through-hole and the recess that communicates the second indirect vertical cylinder via the position the formed communication ports near the light source device of (51BM),
The plurality of first direct vertical cylinders (50R, 50N, 50D, 50P) and the first indirect vertical cylinder (50F) are disposed adjacent to each other, and the second direct vertical cylinder (50B) and the second indirect vertical cylinder ( 50M) are arranged adjacent to each other,
In addition, the first indirect light source, the second indirect light source, a plurality of first direct light sources, and a control device (23) that controls turning on or off of the second direct light source are provided, and the control device operates the power switch to the ON position. During this time, the first indirect light sources (61NR, 61DF, 61PF) are turned on, and only when a specific mode is selected, the plurality of first direct light sources (63R, 62N, 62D, 62P) correspond. One is lit, the second indirect light source (61BM) is lit only when a specific mode is selected, and the second direct light source is only when the specific mode is selected and the combination mode is selected. The technical means of the display device characterized by lighting (62B) is adopted.

  According to this invention, the first operation symbol, the first mode symbol, the first indirect light source, the first direct light source, the first indirect vertical cylinder, the first direct vertical cylinder, and the first horizontal cylinder constitute one unit. The The second operation symbol, the second mode symbol, the second indirect light source, the second direct light source, the second indirect vertical cylinder, the second direct vertical cylinder, and the second horizontal cylinder constitute one unit. In each unit, display by indirect illumination and display by direct illumination are realized without disposing a light-transmitting light guide plate between the display plate and the light source device. Further, in each unit, light leakage from the direct vertical cylinder to the indirect vertical cylinder is reduced. Furthermore, since the two units are configured independently, they can be in different display states. For example, the first operation symbol may be a symbol indicating an operation method for the R, N, and D modes, and the second operation symbol may be a symbol indicating an operation method for the B mode.

The invention according to claim 2 is a display board (4) having a plurality of symbols (40) displayed by illumination from behind, and a light source device (6) having a plurality of light sources (60) for illuminating the symbols. A partition member (5) disposed between the display board and the light source device,
The plurality of symbols are a plurality of first mode symbols (43R, 42N , 42D, 42P ) indicating a plurality of modes, and a combination mode that can be selected only in a specific mode corresponding to one of the plurality of first mode symbols. A two-mode symbol (42B) and an operation symbol (41M) indicating a method of operating the selection device for selecting the combination mode ;
The plurality of light sources include a first indirect light source ( 61NR, 61DF, 61PF ) that indirectly illuminates a plurality of first mode symbols (43R, 42N , 42D, 42P ), an operation symbol (41M), and a second mode symbol (42B). ) Indirectly illuminating the first mode light source, a plurality of first direct light sources (63R, 62N) directly illuminating the plurality of first mode symbols, and a second light source directly illuminating the second mode symbols. 2 direct light sources (62B)
The partition member (5) has an opening at one end disposed behind the operation symbol, an indirect vertical cylinder (50M) that defines a vertical through hole extending in the vertical direction from the light source device toward the display plate, and a first mode symbol A plurality of first direct vertical cylinders having an opening at one end disposed behind and an opening at the other end surrounding the first direct light source and defining a vertical through hole extending in the vertical direction from the light source device toward the display plate (50R, 50N , 50D, 50P ), having an opening at one end disposed behind the second mode symbol and an opening at the other end surrounding the second direct light source, and extending vertically from the light source device toward the display panel A second direct vertical cylinder (50B) that divides the extending vertical through hole, and covers the first indirect light sources ( 61NR, 61DF, 61PF ) in the vertical direction, and is formed at a position close to the light source device of the plurality of first direct vertical cylinders. Vertical through-holes in the plurality of first direct vertical cylinders through the communication port The first horizontal cylinder (51NR 1 , 51DF, 51PF ) that divides the recess communicating with the second indirect light source (61BM) in the vertical direction, and the communication formed in a position close to the light source device of the second direct vertical cylinder A recess that communicates with the vertical through hole in the second direct vertical cylinder through the opening and further communicates with the vertical through hole in the indirect vertical cylinder through a communication port formed at a position close to the light source device of the indirect vertical cylinder. have a second lateral tube partitioning (51BM),
The plurality of first direct vertical cylinders (50R, 50N, 50D, 50P) are arranged adjacent to each other, and the second direct vertical cylinder (50B) and the indirect vertical cylinder (50M) are arranged adjacent to each other,
In addition, the first indirect light source, the second indirect light source, a plurality of first direct light sources, and a control device (23) that controls turning on or off of the second direct light source are provided, and the control device operates the power switch to the ON position. During this time, the first indirect light sources (61NR, 61DF, 61PF) are turned on, and only when a specific mode is selected, the plurality of first direct light sources (63R, 62N, 62D, 62P) correspond. One is lit, the second indirect light source (61BM) is lit only when a specific mode is selected, and the second direct light source is only when the specific mode is selected and the combination mode is selected. The technical means of the display device characterized by lighting (62B) is adopted.

According to the present invention, a plurality of first mode symbols, a first indirect light source, a first direct light source, a plurality of first direct vertical cylinders, and a first horizontal cylinder constitute one unit. The operation symbol, the second mode symbol, the second indirect light source, the second direct light source, the second indirect vertical cylinder, the second direct vertical cylinder, and the second horizontal cylinder constitute one unit. In each unit, display by indirect illumination and display by direct illumination are realized without disposing a light-transmitting light guide plate between the display plate and the light source device. Further, in each unit, light leakage directly from the vertical cylinder to other vertical cylinders is reduced. Furthermore, since the two units are configured independently, they can be in different display states. For example, the first mode symbol may be a symbol indicating the R and N modes, and the operation symbol may be a symbol indicating the operation method for the B mode.
The invention according to claim 3 is characterized in that the second horizontal cylinder (51BM) is arranged on the side of the second direct vertical cylinder (50B) and the second indirect vertical cylinder (50M). According to the present invention, it is possible to increase the length of the light path from one vertical through hole through the recess to the other vertical through hole. For this reason, the light leakage of the direct light source is reduced.
The invention according to claim 4 is characterized in that the second horizontal cylinder (51BM) is disposed overlapping the second direct vertical cylinder (50B) and the second indirect vertical cylinder (50M). According to this invention, a horizontal cylinder can be arrange | positioned without projecting to the side of two vertical cylinders.
The invention according to claim 5 is characterized in that the second horizontal cylinder (51BM) is arranged on the side of the second direct vertical cylinder (50B) and the indirect vertical cylinder (50M). According to the present invention, it is possible to increase the length of the light path from one vertical through hole through the recess to the other vertical through hole. For this reason, the light leakage of the direct light source is reduced.
The invention according to claim 6 is characterized in that the second horizontal cylinder (51BM) is arranged overlapping the second direct vertical cylinder (50B) and the indirect vertical cylinder (50M). According to this invention, a horizontal cylinder can be arrange | positioned without projecting to the side of two vertical cylinders.
The light source device (6) includes a circuit board (64) on which light emitting diodes as a plurality of light sources (60) are mounted, and the partition member (5) is provided on the circuit board (64). The communication port is formed in a partition plate between the vertical cylinder and the horizontal cylinder, and the height (HD) of the emission surface of the light emitting diode from the surface of the circuit board and the surface of the circuit board The technical means that the communication port height (HW) is substantially equal is adopted. According to this invention, it is suppressed that the light of the light emitting diode as a direct light source reaches | attains a communicating port directly. As a result, leakage of light directly into the light source is reduced.
The invention according to claim 8 employs technical means that the light source luminance of the indirect light source is higher than the light source luminance of the direct light source. According to this invention, the light source luminance of the indirect light source is higher than the light source luminance of the direct light source. However, the indirect light source illuminates the symbol by indirect illumination. For this reason, it is avoided that the symbol is excessively brightly illuminated. On the other hand, the direct light source illuminates the symbol by direct illumination. For this reason, even if the light source luminance is low, the symbol is illuminated with the necessary brightness. Furthermore, since the brightness of the direct light source can be suppressed, leakage of light from the direct light source is reduced.
The invention according to claim 9 is characterized in that the specific mode is a D mode for advancing the vehicle, and the combination mode is a B mode for increasing a power regeneration amount during deceleration in the D mode. And

  Note that the reference numerals in parentheses described in the claims and the above-described means indicate the correspondence with the specific means described in the embodiments described later as one aspect, and are technical terms of the present invention. It does not limit the range.

It is a top view which shows the meter apparatus of 1st Embodiment to which this invention is applied. It is a top view which shows the shift indicator which is a display apparatus of 1st Embodiment. It is a disassembled perspective view which shows the shift indicator of 1st Embodiment. It is a perspective view which shows the front surface of the shift indicator of 1st Embodiment. It is a perspective view which shows the back surface of the shift indicator of 1st Embodiment. It is a perspective view which shows the front surface of the shift indicator of 1st Embodiment. It is sectional drawing which shows the VII-VII cross section of FIG. It is sectional drawing which shows the VIII-VIII cross section of FIG. It is a fragmentary sectional view which shows the IX-IX cross section of FIG. It is a perspective view which shows the light leakage path | route in 1st Embodiment. It is a fragmentary sectional view showing a shift indicator of a 2nd embodiment to which the present invention is applied.

  A plurality of modes for carrying out the present invention will be described below with reference to the drawings. In each embodiment, parts corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals, and redundant description may be omitted. When only a part of the configuration is described in each mode, the other modes described above can be applied to the other parts of the configuration. Not only combinations of parts that clearly show that combinations are possible in each embodiment, but also combinations of the embodiments even if they are not explicitly stated unless there is a problem with the combination. Is also possible.

(First embodiment)
FIG. 1 is a plan view showing a meter device according to a first embodiment to which the present invention is applied. The meter device 1 is a vehicle display device mounted on a vehicle. The vehicle is a hybrid vehicle that uses an internal combustion engine and an electric motor together as a driving power source.

  The vehicle is provided with a selection device 2 for selecting a part of the plurality of modes. As a part of the plurality of modes, a single mode or a combination of a plurality of modes is selected. The plurality of modes include a plurality of modes related to the operation state of the vehicle. The plurality of modes include an R mode for moving the vehicle backward, an N mode for shutting off the vehicle drive system and the power source, a D mode for moving the vehicle forward, and a power regeneration amount during deceleration in the D mode. A B mode for increasing and a P mode for stopping the vehicle are included. The selection device 2 includes a shift lever 21 operated by a driver. The shift lever 21 can select an R mode, an N mode, a D mode, and a B mode. The B mode is a combination mode that can be selected only in the D mode. The selection device 2 includes a parking brake device 22. The P mode is selected by operating the parking brake device 22. Further, the selection device 2 includes a control device 23. The control device 23 inputs a signal indicating an operation state of the shift lever 21 and the parking brake device 22 and outputs an output signal corresponding to the selected mode. This output signal controls lighting or extinguishing of a plurality of light sources described later.

  The meter device 1 includes a shift indicator 3 as a display device. The shift indicator 3 displays the selected mode in response to the output signal from the selection device 2.

  FIG. 2 is a plan view showing the shift indicator 3 which is the display device of the first embodiment. A plurality of symbols 40 are arranged on the display board 4 of the shift indicator 3. The display board 4 has a transparent resin plate such as acrylic or polycarbonate, and a printed layer printed on the front surface and / or back surface thereof. A plurality of symbols 40 are represented by the print layer. The printing layer has an ink portion formed of black light-shielding ink and a non-printing portion or a light transmitting portion. The non-printing part or the translucent part has a symbol shape. In the non-printing part or the light transmitting part of the display board 4, fine uneven parts are formed for scattering light and realizing uniform brightness. A fine uneven part is also called a grained surface.

  Therefore, each of the plurality of symbols 40 is illuminated from behind the display panel 4 to transmit the illumination light. As a result, the symbol 40 becomes brighter and is in a display state. Further, the display states of some of the symbols 40 are a first display state that only indicates the presence of the symbol and a second display that indicates that the mode indicated by the symbol is selected by switching the illumination mode. Switched to the state.

  The illumination mode can be switched by switching the characteristics of the illumination light. Specifically, light having the first characteristic and light having the second characteristic are switched and supplied. The light having the second characteristic is different from the light having the first characteristic so that a person can identify the light. As light having the first characteristic, light of the first color as the background color is supplied. The first color is white. The first color can be called a common color supplied to a plurality of symbols or a background color because it is used as a background. The purpose of illumination with white light is to make it possible to visually recognize the presence of a plurality of symbols 40. As light having the second characteristic, light of a second color is provided for indicating the selected mode in a distinguishable manner from other modes. The second color is different from the first color. The second color is orange or green. The second color light is supplied in addition to the first color light toward only the symbol corresponding to the selected mode. The second color is a color that makes one symbol stand out on the shift indicator 3. The second color can also be called a display color or a specific color.

  The plurality of symbols 40 include operation symbols 41F and 41M indicating the operation method or operation direction of the shift lever 2, and character symbols 43R, 42N, 42D, 42B, and 42P indicating a plurality of modes. The operation symbol 41F is also called a first operation symbol. The operation symbol 41F includes a circle symbol indicating the home position of the shift lever 2 and three arrow symbols indicating the operation directions to the R mode, N mode, and D mode. The operation symbol 41M includes one arrow symbol indicating the operation direction to the B mode. The operation symbol 41M is also called a second operation symbol. Since the character symbol can be replaced with a mark, it can also be called a mode symbol. The symbol 42P indicating the P mode is composed of characters and a frame. Here, the character symbols 43R, 42N, 42D, and 42P are also called first mode symbols. The character symbol 42B is also called a second mode symbol.

  While the vehicle power switch is being operated to the ON position, the operation symbol 41F and the plurality of character symbols 43R, 42N, 42D, and 42P are displayed by being illuminated with white light. The operation symbol 41F is a first monochromatic symbol that is illuminated only with white light while the power switch of the vehicle is being operated to the ON position. Therefore, the plurality of symbols 41F, 43R, 42N, 42D, and 42P form a first symbol group that is illuminated with the first color light while the vehicle power switch is operated to the ON position. .

  The operation symbol 41M and the character symbol 42B are illuminated with white light only in the D mode in which the character symbol 42D is displayed. Therefore, the operation symbol 41M and the character symbol 42B form a second symbol group that can block illumination with white light independently of the first symbol group. The operation symbol 41M is a second single color symbol illuminated only with white light.

  Furthermore, any of the character symbols 43R, 42N, 42D, and 42P corresponding to the selected mode is selectively illuminated with the second color and displayed. Further, when the B mode is selected in the D mode, the character symbol 42B is simultaneously illuminated with the second color light in addition to the character symbol 42D. The character symbol 43R is supplied with orange light. The other character symbols 42N, 42D, 42B, and 42P are supplied with green light. Therefore, the character symbols 43R, 42N, 42D, 42P, and 42B can also be referred to as discoloration symbols whose colors change between the first color and the second color.

  FIG. 3 is an exploded perspective view showing the shift indicator 3. The shift indicator 3 includes a display plate 4, a partition member 5, and a light source device 6. Only the partition member 5 is disposed between the display plate 4 and the light source device 6. The upper end of the partition member 5 is disposed in close contact with the back surface of the display panel 4. The partition member 5 is a member that divides a plurality of passages through which illumination light passes. The partition member 5 is also a member that partitions a plurality of ranges to be illuminated from each other. A light source device 6 is disposed immediately below the partition member 5. Between the display board 4 and the partition member 5, the translucent light guide plate which can guide light along the horizontal direction parallel to the display board 4, ie, an XY plane, is not provided. There is no large gap between the display plate 4 and the partition member 5 that allows the passage of light in the lateral direction parallel to the display plate 4. The lower end surface of the partition member 5 is in contact with the circuit board 64 of the light source device 6. A gap of about 0.5 mm may be provided between the lower end surface of the partition member 5 and the light source device 6.

  The light source device 6 includes a plurality of light sources 60 including an indirect light source 61 that indirectly illuminates a single color symbol and a color change symbol, and direct light sources 62 and 63 that directly illuminate the color change symbol. The plurality of light sources 60 are provided by a plurality of light emitting diodes (hereinafter referred to as LEDs) 60. The plurality of LEDs 60 include a plurality of indirect LEDs 61NR, 61DF, 61BM, 61PF and a plurality of direct LEDs 62N, 62D, 62B, 62P, 63R. The indirect LEDs 61NR, 61DF, 61BM, and 61PF supply the first color light for indirect illumination. The first color provides a first display state. The first color is white. Direct LEDs 62N, 62D, 62B, 62P, 63R provide a second color of light for direct illumination. The second color provides a second display state. The second color is a color different from the first color. The direct LEDs 62N, 62D, 62B, 62P, and 63R include a green LED 62N, 62D, 62B, and 62P, and an orange LED 63R. The indirect LEDs 61NR, 61DF, and 61PF are also called first indirect light sources. The indirect LED 61BM is also called a second indirect light source. The direct LEDs 63R, 62N, 62D, and 62P are also called first direct light sources. The direct LED 62B is also called a second direct light source.

  The plurality of LEDs 60 are mounted on the circuit board 64. A white print layer 65 is formed on the circuit board 64 by screen printing. The print layer 65 is effective for reflecting light. The print layer 65 is formed substantially corresponding to the range covered with the partition member 5 or the arrangement range of the plurality of LEDs 60. The print layer 65 is formed corresponding to at least a light path to be described later.

  The plurality of indirect LEDs 61NR, 61DF, 61BM, and 61PF are dispersedly arranged outside the arrangement range of the plurality of direct LEDs 62N, 62D, 62B, 62P, and 63R. The indirect LED 61 is arranged so as to be adjacent to and adjacent to the two symbols. For example, indirect LED 61NR is arrange | positioned apart from these symbols 43R and 42N to the side so that it may adjoin both character symbol 43R and character symbol 42N. Indirect LED 61DF is arrange | positioned apart from these symbols 42D and 41F to the side so that it may adjoin both the character symbols 42D and the operation symbols 41F. Indirect LED 61BM is arrange | positioned apart from these symbols 42B and 41M to the side so that it may adjoin both the character symbols 42B and the operation symbols 41M. Indirect LED 61PF is arrange | positioned apart from these symbols 42P and 41F laterally so that it may adjoin both the character symbols 42P and the operation symbols 41F.

  Each of the plurality of direct LEDs 62N, 62D, 62B, 62P, and 63R is associated with one of the plurality of symbols 42N, 42D, 42B, 42P, and 43R. The direct LEDs 62, 63 are arranged under the corresponding symbols. The direct LEDs 62 and 63 are arranged so that their light irradiation directions are directly directed to the corresponding symbols.

  The light source device 6 is configured so that the circuit board 64 can be diverted to a left-hand drive vehicle. The circuit board 64 is provided with lands for installing LEDs so as to be symmetrical. In the drawing, LED 62V indicates the position of the direct LED 62N for the left-hand drive vehicle. In this embodiment, no LED is provided at the position of the LED 62V.

  FIG. 4 is a perspective view showing the front surface of the shift indicator 3 of the first embodiment. This figure shows a state where the display panel 4 is seen through. In this figure, a plurality of symbols 40 are shown in order to show the correspondence between the plurality of symbols 40 and the partition member 5.

  FIG. 5 is a perspective view showing the back surface of the shift indicator 3 of the first embodiment. This figure shows a state in which the circuit board 64 is seen through. In this figure, a plurality of LEDs 60 are shown in order to show the correspondence between the plurality of LEDs 60 and the partition member 5.

  FIG. 6 is a perspective view showing the front surface of the shift indicator 3 of the first embodiment. 7 is a cross-sectional view showing a VII-VII cross section of FIG. FIG. 8 is a cross-sectional view showing a VIII-VIII cross section of FIG. 6. FIG. 9 is a partial cross-sectional view showing the IX-IX cross section of FIG. 6.

  4 and 5, the partition member 5 is formed by molding a white resin. The partition member 5 is formed in a substantially box shape. The partition member 5 defines a passage for guiding light from one LED 60 directly or indirectly to one or more associated symbols 40. These passages are filled with air. The partition member 5 includes a plurality of vertical partitions 50 and a plurality of horizontal partitions 51, and can be viewed as an aggregate thereof. The vertical partition 50 can also be referred to as a vertical cylinder 50. The vertical cylinder 50 has a vertical through hole defined therein. The horizontal partition 51 can also be referred to as a cover member 51 or a horizontal cylinder 51 in which an end surface on the light source device 6 side and a side surface in contact with the adjacent vertical cylinder 50 are opened. The horizontal cylinder 51 defines a recess. The vertical through hole and the recess provide a passage.

  The partition member 5 can also be viewed as a member including a rectangular tube-shaped outer cylinder and a plurality of partition plates that divide the inside into a plurality of passages. Moreover, the partition member 5 can also be seen as a member that forms a plurality of vertical through holes penetrating the front and back surfaces in the vertical direction and a plurality of concave portions extending in the vertical direction from the back surface.

  The vertical cylinder 50 defines a vertical through hole extending along the vertical direction (Z-axis direction) from the light source device 6 toward the display plate 4. Two adjacent vertical cylinders 50 are configured to share a wall between them. The vertical cylinder 50 is formed by a vertical partition plate extending along the vertical direction Z.

  The plurality of vertical cylinders 50 are formed and arranged so that one vertical cylinder 50 corresponds to one symbol 40. The vertical cylinder 50 has one end opening disposed behind the corresponding symbol 40. The one-end opening has a size that can include only the corresponding symbol 40.

  The plurality of vertical cylinders 50 include direct vertical cylinders 50R, 50N, 50D, 50P, and 50B and indirect vertical cylinders 50F and 50M. The square cylindrical direct vertical cylinder 50R is located immediately below the character symbol 43R. The square cylinder-like direct vertical cylinder 50N is located immediately below the character symbol 42N. The square cylindrical direct vertical cylinder 50D is located immediately below the character symbol 42D. The square cylinder-like direct vertical cylinder 50P is located immediately below the character symbol 42P. The square cylindrical direct vertical cylinder 50B is located immediately below the character symbol 42B. The vertical cylinders 50R, 50N, 50D, 50P, and 50B are arranged below the color change symbols 43R, 42N, 42D, 42P, and 42B. The direct vertical cylinders 50R, 50N, 50D, and 50P are also called first direct vertical cylinders. The direct vertical cylinder 50B is also called a second direct vertical cylinder. The indirect vertical cylinder 50F having a T-shaped cross section is located immediately below the operation symbol 41F. The square cylindrical indirect vertical cylinder 50M is located immediately below the operation symbol 41M. The indirect vertical cylinders 50F and 50M are disposed below the monochrome symbols 41F and 41M. The indirect vertical cylinder 50F is also called a first indirect vertical cylinder. The indirect vertical cylinder 50M is also called a second indirect vertical cylinder.

  The direct vertical cylinders 50R, 50N, 50D, 50P, and 50B have other end openings that surround only one of the direct LEDs 62N, 62D, 62B, 62P, and 63R. The other end opening has a size that can include only the corresponding direct LEDs 62N, 62D, 62B, 62P, 63R. Each of the direct vertical cylinders 50R, 50N, 50D, 50P, and 50B has a cylindrical shape that extends straight along the vertical direction (Z-axis direction) of the shift indicator 3. The vertical through holes defined by the respective vertical cylinders 50R, 50N, 50D, 50P, and 50B extend straight in the vertical direction between the one end opening and the other end opening. As a result, the corresponding symbol 40 and the corresponding second color LED are positioned so as to face each other directly at both ends of the plurality of direct vertical cylinders 50R, 50N, 50D, 50P, 50B.

  Each of the direct vertical cylinders 50R, 50N, 50D, 50P, and 50B defines a direct illumination path. The direct illumination path allows one of the LEDs 62N, 62D, 62B, 62P, and 63R to directly illuminate one of the character symbols 42N, 42D, 42B, 42P, and 43R.

  Each of the indirect vertical cylinders 50F and 50M has a lower end opening, but there is no LED in the range of the lower end opening. The indirect vertical cylinder 50F has an intermediate plate 54F in the middle in the vertical direction. The intermediate plate 54F partitions the inside of the indirect vertical cylinder 50F into an upper space and a lower space. A vertical communication port 55F is provided in the intermediate plate 54F. The vertical communication port 55F is substantially T-shaped corresponding to the approximate shape of the operation symbol 41F. Further, the indirect vertical cylinder 50F is formed with a slope 56F for reflecting light to reach the operation symbol 41F. The inclined surface 56F is inclined so as to guide the indirect illumination light supplied through the vertical communication port 55F toward the operation symbol 41F. The indirect vertical cylinder 50M has an intermediate plate 54M in the middle in the vertical direction. The intermediate plate 54M partitions the indirect vertical cylinder 50M into an upper space and a lower space. A vertical communication port 55M is provided in the intermediate plate 54M. The vertical communication port 55M is provided at a portion farthest from the horizontal cylinder 51BM corresponding to the indirect vertical cylinder 50M. The shape, size, and position of the vertical communication port 55M are set so as to adjust the amount and distribution of the first color light that reaches the operation symbol 41M. The shape, size, and position of the vertical communication port 55F are set so as to adjust the amount and distribution of the light of the first color that reaches the operation symbol 41F. The vertical communication ports 55M and 55F are adjusted so that the operation symbol 41M and the operation symbol 41F have substantially the same brightness.

  Each of the indirect vertical cylinders 50M and 50F defines a part of the indirect illumination passage. The indirect illumination passage allows one of the indirect LEDs 61NR, 61DF, 61BM, and 61PF to indirectly illuminate one of the operation symbols 41M and 41F.

  Each of the plurality of horizontal cylinders 51 defines a flat concave portion extending along a horizontal direction (direction along the XY plane) parallel to the display plate 4 and the light source device 6. The plurality of horizontal cylinders 51 are provided dispersed on three sides of the partition member 5 formed in a rectangular parallelepiped shape. The horizontal cylinder 51 extends from the lower part of the partition member 5 along the light source device 6. The horizontal cylinder 51 has an opening surrounding the indirect LED 61 on the lower side facing the light source device 6. The horizontal cylinder 51 covers the corresponding indirect LED 61 in the vertical direction, that is, in the light emission direction. Thereby, the light from the indirect LED 61 is always reflected by the inner surface of the horizontal tube 51. Further, the concave portion defined by the horizontal cylinder 51 communicates with a vertical through hole defined by the vertical cylinder 50 via a communication port formed at a position close to the light source device 6 of the vertical cylinder 50. The communication port is opened at a position closer to the light source device 6 than the display plate 4. In other words, the communication port is opened so as not to directly face the LEDs 62 and 63 with respect to the emission direction of the LEDs 62 and 63 directly. The position of the communication port and the height in the vertical direction of the communication port are set so as to reduce or desirably prevent direct light from directly entering the recesses in the horizontal cylinder 51 from the LEDs 62 and 63. Yes. The light source communication port is formed at the end of the vertical cylinder 50 on the light source device 6 side. The communication port can be formed by a notch portion or a through hole provided at the edge of the partition plate located between the vertical cylinder 50 and the horizontal cylinder 51. The communication port is opened in a direction (direction along the XY plane) orthogonal to the vertical direction. The horizontal cylinders 51NR, 51DF, and 51PF are also called first horizontal cylinders. The horizontal cylinder 51BM is also called a second horizontal cylinder.

  5 and 7, the horizontal cylinder 51PF is located on the side of the vertical cylinder 50P and the vertical cylinder 50F. The horizontal cylinder 51PF has a lower opening end having a size including the indirect LED 61PF on the lower side thereof. The horizontal cylinder 51PF has a horizontal communication port 52P that communicates directly with the lower space in the vertical cylinder 50P and a horizontal communication port 53F1 that communicates with the lower space in the indirect vertical cylinder 50F on the lateral side. Therefore, the horizontal cylinder 51PF provides a branch passage that supplies light from the indirect LED 61PF by directly branching it into the vertical cylinder 50P and the indirect vertical cylinder 50F. The horizontal communication port 52P has a portion 52P1 that opens at the boundary between the direct vertical tube 50P and the horizontal tube 51PF, and a portion 52P2 that opens at the boundary between the direct vertical tube 50P and the indirect vertical tube 50F. The portion 52P2 is disposed below the intermediate plate 54F. For this reason, when viewed from the display board 4 along the vertical direction (Z-axis direction), the portion 52P2 is covered with the intermediate board 54F. In other words, the intermediate plate 54F forms an extended recess by extending a recess for indirect illumination defined by the horizontal cylinder 51PF into the indirect vertical cylinder 50F. The shape, size, and height (Z-axis direction) of the horizontal communication port 52P are set so as to adjust the light amount of the indirect LED 61PF that is directly introduced into the vertical cylinder 50P. Therefore, the horizontal communication port 52P is also a horizontal cylinder stop for adjusting the amount of light. The horizontal communication port 53F1 extends over the entire boundary between the horizontal cylinder 51PF and the indirect vertical cylinder 50F. Therefore, the horizontal communication port 53F1 is not intended to adjust the amount of light. However, the amount of light to the operation symbol 41F is adjusted by a vertical communication port 55F as a vertical cylinder aperture.

  5 and 7, the horizontal cylinder 51NR is located on the side of the vertical cylinder 50R and the vertical cylinder 50N. The horizontal cylinder 51NR has a lower opening end having a size including the indirect LED 61NR on the lower side thereof. The horizontal cylinder 51NR has a horizontal communication port 52R that communicates directly with the lower space in the vertical cylinder 50R and a horizontal communication port 52N that communicates directly with the lower space in the vertical cylinder 50N. Therefore, the horizontal cylinder 51NR provides a branch passage that supplies light from the indirect LED 61NR by directly branching it into the vertical cylinder 50N and the direct vertical cylinder 50R. The horizontal communication port 52R is formed directly at the boundary between the vertical cylinder 50R and the horizontal cylinder 51NR. The shape, size, and height (Z-axis direction) of the horizontal communication port 52R are set so as to adjust the light amount of the indirect LED 61NR that is directly introduced into the vertical cylinder 50R. Therefore, the horizontal communication port 52R is also a horizontal cylinder stop for adjusting the amount of light. The horizontal communication port 52N is formed directly at the boundary between the vertical cylinder 50N and the horizontal cylinder 51NR. The shape, size, and height (Z-axis direction) of the horizontal communication port 52N are set so as to adjust the light quantity of the indirect LED 61NR that is directly introduced into the vertical cylinder 50N. Therefore, the horizontal communication port 52N is also a horizontal cylinder stop for adjusting the amount of light.

  5 and 8, the horizontal cylinder 51DF is located on the side of the vertical cylinder 50D and the vertical cylinder 50F. The horizontal cylinder 51DF has a lower opening end of a size that includes the indirect LED 61DF on the lower side thereof. The horizontal cylinder 51DF has a horizontal communication port 52D that communicates directly with the lower space in the vertical cylinder 50D and a horizontal communication port 53F2 that communicates with the lower space in the indirect vertical cylinder 50F on the lateral side. Therefore, the horizontal cylinder 51DF provides a branch passage that supplies the light from the indirect LED 61DF to the direct vertical cylinder 50D and the indirect vertical cylinder 50F. The horizontal communication port 52D is formed directly at the boundary between the vertical cylinder 50D and the horizontal cylinder 51DF. The shape, size, and height (Z-axis direction) of the horizontal communication port 52D are set so as to adjust the light amount of the indirect LED 61DF that is directly introduced into the vertical cylinder 50D. Therefore, the horizontal communication port 52D is also a horizontal cylinder stop for adjusting the amount of light. The horizontal communication port 53F2 extends over the entire boundary between the horizontal cylinder 51DF and the indirect vertical cylinder 50F. Therefore, the horizontal communication port 53F2 is not intended to adjust the amount of light. However, the amount of light to the operation symbol 41F is adjusted by a vertical communication port 55F as a vertical cylinder aperture.

  5 and 9, the horizontal cylinder 51BM is located on the side of the vertical cylinder 50M and the vertical cylinder 50B. The horizontal cylinder 51DF and the horizontal cylinder 51BM are formed of a series of plate materials. The horizontal cylinder 51BM has a lower opening end having a size including the indirect LED 61BM at the lower end thereof. The indirect LED 61BM is turned off independently of the other indirect LEDs 61NR, 61DF, 61PF. Therefore, the vertical partition plates around the horizontal cylinder 51BM are formed so as to contact the circuit board 64 so that light from the other horizontal cylinders 51PF, 51NR, and 51DF does not enter the horizontal cylinder 51BM. For the same reason, the vertical partition plates around the direct vertical cylinder 50 </ b> B and the indirect vertical cylinder 50 </ b> M are formed so as to contact the circuit board 64. The horizontal cylinder 51BM has a horizontal communication port 52B that communicates directly with the lower space in the vertical cylinder 50B and a horizontal communication port 53M that communicates with the lower space in the indirect vertical cylinder 50M. Therefore, the horizontal cylinder 51BM provides a branch passage that supplies light from the indirect LED 61BM by directly dividing the light into the vertical cylinder 50B and the indirect vertical cylinder 50M. The horizontal communication port 52B is formed directly at the boundary between the vertical cylinder 50B and the horizontal cylinder 51BM. The shape, size, and height (Z-axis direction) of the horizontal communication port 52B are set so as to adjust the light amount of the indirect LED 61BM that is directly introduced into the vertical cylinder 50B. Therefore, the horizontal communication port 52B is also a horizontal cylinder stop for adjusting the amount of light. The horizontal communication port 53M extends over the entire boundary between the horizontal cylinder 51BM and the indirect vertical cylinder 50M. Therefore, the horizontal communication port 53M is not intended to adjust the light amount. However, the amount of light to the operation symbol 41M is adjusted by the vertical communication port 55M as a vertical cylinder aperture.

  As illustrated in FIG. 5, the horizontal communication ports 52R, 52N, 52D, 52B, and 52P are directly open on the sides of the LEDs 63R, 62N, 62D, 62B, and 62P. The LEDs 63 </ b> R, 62 </ b> N, 62 </ b> D, 62 </ b> B, and 62 </ b> P have light emission surfaces on their upper surfaces so as to be directed to the display panel 4. Therefore, it is avoided that the light directly emitted from the LEDs 63R, 62N, 62D, 62B, and 62P is directly incident on the lateral communication ports 52R, 52N, 52D, 52B, and 52P. As a result, leakage of the second color light is suppressed.

  As shown in FIG. 7, the height HW of the horizontal communication ports 52R, 52N, 52D, 52B, and 52P and the height HD of the direct LEDs 63R, 62N, 62D, 62B, and 62P are set to be approximately equal. . The height HW of the horizontal communication ports 52R, 52N, 52D, 52B, and 52P in the vertical direction is such that direct light enters the concave portions in the horizontal cylinders 51NR, 51DF, 51BM, and 51PF from 63R, 62N, 62D, 62B, and 62P. Is set to reduce or preferably prevent. The height HW is a height from the surface of the circuit board 64 to the upper edge of the communication port. The height HD is the height of the LED emission surface from the surface of the circuit board 64. This configuration also contributes to avoiding light directly emitted from the LEDs 63R, 62N, 62D, 62B, and 62P from directly entering the lateral communication ports 52R, 52N, 52D, 52B, and 52P. The relationship between the height HW and the height HD can be set such that HW≈HD and HW> HD. The height HW can be set lower than the upper limit height slightly higher than the height HD. Thereby, leakage of the light of the second color is suppressed.

  In this embodiment, the partition member 5 includes at least one direct vertical cylinder 50 and at least one horizontal cylinder 51 connected to the direct vertical cylinder 50. Thereby, the symbol located directly on the vertical cylinder 50 is selectively displayed by indirect illumination and direct illumination. The partition member 5 includes at least two vertical cylinders 50 and at least one horizontal cylinder 51 connected to the two vertical cylinders 50. Thereby, indirect illumination is provided to the two vertical cylinders 50 by one horizontal cylinder 51. The partition member 5 includes a plurality of units with at least two vertical cylinders 50 and at least one horizontal cylinder 51 connected to the two vertical cylinders 50 as a set of units. Thereby, a large number of symbols can be displayed. One unit can include at least two direct vertical cylinders 50R and 50N. One unit can include at least one of the direct vertical cylinders 50D, 50P, and 50B and at least one of the indirect vertical cylinders 50F and 50M.

  In this embodiment, one direct vertical tube provides a direct illumination path that allows light of the second color to reach the symbol directly from the light source. Further, the direct vertical and horizontal cylinders provide an indirect illumination path that allows the first color light to indirectly reach the symbol after being reflected and scattered from the indirect light source. Thus, the direct illumination path provides a portion of the indirect illumination path. The indirect illumination passage is connected to the lower part of the direct illumination passage. As a result, the first color light is supplied from the lower part of the direct illumination path. Furthermore, the recessed part in one horizontal cylinder is connected to the vertical through-hole in several vertical cylinders including at least one direct vertical cylinder. Accordingly, one horizontal cylinder supplies the first color light to the plurality of vertical cylinders. That is, the indirect illumination passage is formed as a branch passage so that the light of the first color can branch and reach a plurality of symbols. The plurality of vertical cylinders supplied with the light of the first color from one horizontal cylinder can include a plurality of direct vertical cylinders. The plurality of vertical cylinders supplied with light of the first color from one horizontal cylinder can include a direct vertical cylinder and an indirect vertical cylinder.

Returning to FIG. 2 and FIG. 3, when the plurality of symbols 40 are illuminated in white, the luminance on the symbols 40 is about ²⁰ cd / m ² . On the other hand, when the character symbols 43R, 42N, 42D, and 42P are illuminated in orange or green, the luminance on the character symbols is about 200 cd / m ² . Thereby, the character symbol corresponding to the selected mode is displayed brighter and more colored than white as the background display. In order to provide such a low-luminance background display and a high-luminance selection display, the light source luminance of the plurality of LEDs 60 is selected. Here, the light of the white indirect LEDs 61NR, 61DF, 61PF, and 61BM reaches the plurality of symbols 40 after being irregularly reflected in the plurality of horizontal tubes 51. On the other hand, the light of the orange or green direct LEDs 63R, 62N, 62D, 62B, 62P reaches the symbol 40 directly. In consideration of such a light path difference, the indirect LEDs 61NR, 61DF, 61PF, and 61BM use high-intensity LEDs that have higher light source luminance than the direct LEDs 63R, 62N, 62D, 62B, and 62P. Thereby, even if the light for background display is provided by irregular reflection between the partition member 5 and the circuit board 64, the necessary luminance on the display board 4 can be realized. It is also avoided that the symbols are illuminated too brightly. Furthermore, the brightness of the LEDs 63R, 62N, 62D, 62B, and 62P can be directly suppressed. For this reason, leakage of orange or green light is suppressed. Further, the luminance of each of the plurality of LEDs 60 is adjusted by adjusting the supplied current so that the necessary luminance can be obtained on the display panel 4.

  The control device 23 lights the indirect LEDs 61NR, 61DF, and 61PF while the power switch of the vehicle is being operated to the ON position. Thereby, the presence of a selectable mode is displayed, and the operation direction of the shift lever 21 is displayed. When a specific mode is selected by the shift lever 21 or the parking brake device 22, the control device 23 lights the direct LEDs 63R, 62N, 62D, 62B, and 62P corresponding to the selected mode. The control device 23 lights up the orange LED 63R only when the R mode is selected. The control device 23 lights the green LED 62N only when the N mode is selected. The control device 23 lights up the green LED 62D only when the D mode is selected. The control device 23 lights the green LED 62P only when the P mode is selected. The control device 23 turns on the indirect LED 61BM only when the D mode is selected. Further, the control device 23 lights the green LED 62B only when the D mode is selected and the B mode is selected.

  FIG. 10 is a perspective view showing a light leakage path of the second color in the first embodiment. The plurality of vertical through holes defined by the plurality of vertical cylinders 50 are separated from each other at the upper end portion close to the display panel 4 and are independent. The partition member 5 provides a partition that blocks light leakage between the plurality of vertical cylinders 50 at the upper end portion close to the display panel 4. The vertical through-holes defined by the two adjacent vertical cylinders 50 are communicated only at the lower part of the vertical cylinders 50, that is, only at the end opposite to the display panel 4. For this reason, the light of the direct LEDs 63R, 62N, 62D, 62B, and 62P arranged in the direct vertical cylinders 50R, 50N, 50D, 50B, and 50P reaches the other vertical cylinders 50 after being reflected several times. Further, the vertical through holes defined by the two adjacent vertical cylinders 50 are communicated with each other through a recess in the common horizontal cylinder 51 or an extension recess extended by the intermediate plates 54F and 54M. Therefore, the light of the direct LEDs 63R, 62N, 62D, 62B, and 62P directly arranged in the vertical cylinders 50R, 50N, 50D, 50B, and 50P is reflected in the recesses or the extension recesses and then reaches the other vertical cylinders 50. To do. Furthermore, since the horizontal cylinder 51 is formed so as to protrude to the side of the vertical cylinder 50, the leaked light passing through the recess in the horizontal cylinder 51 is given a long path. With these configurations, the leakage light from the vertical cylinders 50R, 50N, 50D, 50B, and 50P directly reaches the other vertical cylinder 50 after being weakened. Thereby, leakage of the light of the second color is suppressed.

  The character symbol 43R and the character symbol 42N are illuminated in white. When the R mode is selected, the LED 63R is lit directly. The light directly from the LED 63R directly illuminates the character symbol 43R. Thereby, the character symbol 43R is illuminated in orange. At this time, the amount of orange light leaking directly from the vertical cylinder 50R to the vertical cylinder 50N via the horizontal cylinder 51NR is small depending on the position, size, and height of the horizontal communication port 52R and the horizontal communication port 52N. Limited. In addition, the leaked orange light is attenuated and weakened by being reflected in the horizontal cylinder 51NR. Further, the white light of the indirect LED 61NR drowns out the orange light. For this reason, leakage of orange light to the character symbol 42N is reduced. When the N mode is selected, the LED 62N is lit directly. The light of the direct LED 62N directly illuminates the character symbol 42N. Thereby, the character symbol 42N is illuminated in green. At this time, the amount of green light that leaks directly from the vertical cylinder 50N to the vertical cylinder 50R via the horizontal cylinder 51NR is limited by the position, size, and height of the horizontal communication port 52N and the horizontal communication port 52R. Is done. Moreover, the leaked green light is attenuated and weakened by being reflected in the horizontal cylinder 51NR. Furthermore, the white light of the indirect LED 61NR extinguishes the green light. For this reason, leakage of orange light to the character symbol 43R is reduced.

  The character symbol 42P and the operation symbol 41F are illuminated in white. When the P mode is selected, the LED 62P is lit directly. The light of the direct LED 62P directly illuminates the character symbol 42P. Thereby, the character symbol 42P is illuminated in green. At this time, the amount of green light leaking from the direct vertical cylinder 50P to the indirect vertical cylinder 50F is limited to be small depending on the position, size, and height of the horizontal communication port 52P. Moreover, the leaked green light is attenuated and weakened by being reflected in the indirect vertical cylinder 50F below the intermediate plate 54F. Furthermore, the white light of the indirect LED 61PF drowns out the green light. For this reason, the leakage of green light to the operation symbol 41F is reduced.

  The character symbol 42D and the operation symbol 41F are illuminated in white. When the D mode is selected, the LED 62D is lit directly. The light of the direct LED 62D directly illuminates the character symbol 42D. Thereby, the character symbol 42D is illuminated in green. At this time, the amount of green light leaking directly from the vertical cylinder 50D to the indirect vertical cylinder 50F via the horizontal cylinder 51DF is limited to a small amount depending on the position, size, and height of the horizontal communication port 52D and the horizontal communication port 53F2. Is done. Moreover, the leaked green light is attenuated and attenuated by reflection in the horizontal cylinder 51DF. Further, the white light of the indirect LED 61DF drowns out the green light. For this reason, the leakage of green light to the operation symbol 41F is reduced.

  The character symbol 42B and the operation symbol 41M are illuminated in white. When the B mode is selected, the LED 62B is lit directly. The light of the direct LED 62B directly illuminates the character symbol 42B. Thereby, the character symbol 42B is illuminated in green. At this time, the amount of green light leaking directly from the vertical cylinder 50B to the indirect vertical cylinder 50M via the horizontal cylinder 51BM is limited to a small amount depending on the position, size, and height of the horizontal communication port 52B and the horizontal communication port 53M. Is done. In addition, the leaked green light is attenuated and attenuated by reflection in the horizontal cylinder 51BM. Moreover, the leaked green light is attenuated and weakened by being reflected in the indirect vertical cylinder 50M below the intermediate plate 54M. Further, the white light of the indirect LED 61BM drowns out the green light. For this reason, the leakage of green light to the operation symbol 41M is reduced.

  Accordingly, leakage of light from the direct LEDs 63R, 62N, 62D, 62B, and 62P from one direct vertical cylinder 50 to another vertical cylinder 50 is suppressed. Specifically, light leakage of the direct LEDs 63R, 62N, 62D, 62B, and 62P from one of the two adjacent vertical cylinders 50 to the other is suppressed. More specifically, light leakage of the LEDs 63R, 62N, 62D, 62B, and 62P directly from one of the two vertical cylinders 50 sharing one horizontal cylinder 51 to the other is suppressed.

  According to this embodiment, a plurality of symbols can be illuminated with the first light without using a light guide plate. Moreover, even if one symbol is illuminated with a second light different from the first light, leakage of the second light to other symbols can be reduced. As a result, light leakage from one symbol to another can be reduced with a simple configuration.

(Second Embodiment)
FIG. 11 is a partial cross-sectional view showing the shift indicator 3 of the second embodiment to which the present invention is applied. FIG. 11 shows a longitudinal section (X-axis direction) in the range of the character symbol 43R and the character symbol 42N in FIG. The partition member 205 includes a horizontal cylinder 251NR between the direct vertical cylinder 50R and the direct vertical cylinder 50N. The horizontal cylinder 251NR is disposed so as to overlap the direct vertical cylinder 50R and the direct vertical cylinder 50N. The horizontal cylinder 251NR is integrally formed with the partition plate 250NR at the lower end of the partition plate 250NR that partitions the direct vertical cylinder 50R and the direct vertical cylinder 50N. The horizontal cylinder 251NR is arranged so as to overlap with the character symbol 43R and the character symbol 42N. A horizontal communication port 252R is provided between the horizontal cylinder 251NR and the direct vertical cylinder 50R. A horizontal communication port 252N is provided between the horizontal cylinder 251NR and the direct vertical cylinder 50N. Further, an indirect LED 261NR is disposed under the horizontal cylinder 251NR. The indirect LED 261NR is disposed between the direct LED 63R and the direct LED 62N. According to this embodiment, the horizontal cylinder 251NR is arranged without protruding to the side of the partition member 205. The direct vertical cylinder 50R and the direct vertical cylinder 50N may be used as an indirect vertical cylinder by removing the direct LED 63R or the direct LED 62N. The configuration of the second embodiment can be applied to the other two adjacent vertical cylinders 50.

  Also in this embodiment, a plurality of symbols can be illuminated with the first light without using a light guide plate. Moreover, even if one symbol is illuminated with a second light different from the first light, leakage of the second light to other symbols can be reduced. As a result, light leakage from one symbol to another can be reduced with a simple configuration.

(Other embodiments)
The preferred embodiments of the present invention have been described above, but the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.

  The structure of the said embodiment is an illustration to the last, Comprising: The scope of the present invention is not limited to the range of these description. The scope of the present invention is indicated by the description of the scope of claims, and further includes meanings equivalent to the description of the scope of claims and all modifications within the scope.

  For example, in the said embodiment, although LED was used as a light source, light sources, such as a light bulb, can be used. Also, instead of or in addition to white, orange, and green, other colors of light can be used. The first color can be a light color such as light yellow or light blue. The second color can be a sharp color such as yellow or blue. Further, the display state of one symbol may be switched by changing the characteristics such as the intensity and blinking of the direct illumination light and the indirect illumination light. Moreover, the display board 4 is good also considering the symbol part as light-shielding property instead of the structure which makes a symbol part translucent. Further, light for indirect illumination may be supplied from one horizontal tube to a plurality of three or more vertical tubes. Further, a plurality of direct LEDs may be arranged in one vertical cylinder. Further, a plurality of indirect LEDs may be arranged in one horizontal cylinder.

DESCRIPTION OF SYMBOLS 1 Meter apparatus 2 Selection apparatus 3 Shift indicator 4 Display board 5 Partition member 6 Light source device

Claims (9)

A display board (4) having a plurality of symbols (40) displayed by illumination from behind;
A light source device (6) having a plurality of light sources (60) for illuminating the symbol;
A partition member (5) disposed between the display plate and the light source device;
The plurality of symbols are:
A plurality of first mode symbols (43R, 42N, 42D, 42P) indicating a plurality of modes;
A first operation symbol (41F) indicating an operation method of the selection device for selecting one of the plurality of first modes;
A second mode symbol (42B) indicating a combination mode selectable only in a specific mode corresponding to one of the plurality of first mode symbols; and
A second operation symbol (41M) indicating an operation method of the selection device for selecting the combination mode ,
The plurality of light sources are
A first indirect light source (61NR, 61DF, 61PF) that indirectly illuminates the first operation symbol (41F) and the plurality of first mode symbols (43R, 42N, 42D, 42P),
A second indirect light source (61BM) that indirectly illuminates the second operation symbol (41M) and the second mode symbol (42B);
It said plurality of first direct light source for directly illuminating a plurality of first mode symbol comprises (63R, 62N, 62D, 62P ), and a second direct light source for illuminating the second mode symbol directly to (62B),
The partition member (5)
A first indirect vertical cylinder (50F) having an opening at one end disposed behind the first operation symbol and defining a vertical through hole extending in a vertical direction from the light source device toward the display plate;
A second indirect vertical cylinder (50M) having an opening at one end disposed behind the second operation symbol and defining a vertical through hole extending in a vertical direction from the light source device toward the display plate;
A vertical through hole having an opening at one end disposed behind the plurality of first mode symbols and an opening at the other end surrounding the first direct light source and extending in a vertical direction from the light source device toward the display plate A plurality of first direct vertical cylinders (50R, 50N, 50D, 50P),
A vertical through hole having an opening at one end disposed behind the second mode symbol and an opening at the other end surrounding the second direct light source and extending in a vertical direction from the light source device toward the display plate is defined. The second direct vertical cylinder (50B),
Wherein with respect to the longitudinal direction a first indirect light source (61NR, 61DF, 61PF) covers, the light source device first directly through the communicating port formed at a position closer to the plurality of the plurality of first direct vertical tube A concave portion communicating with the vertical through hole in the vertical cylinder and further communicating with the vertical through hole in the first indirect vertical cylinder via a communication port formed at a position near the light source device of the first indirect vertical cylinder. A first horizontal cylinder (51NR, 51DF, 51PF) to be partitioned, and a communication port that covers the second indirect light source (61BM) in the vertical direction and is formed at a position close to the light source device of the second direct vertical cylinder The second indirect vertical cylinder communicates with a vertical through hole in the second direct vertical cylinder, and further passes through the second indirect vertical cylinder through a communication port formed at a position close to the light source device. Second horizontal cylinder (51BM) that defines a recess communicating with the through hole ) Have a,
The plurality of first direct vertical cylinders (50R, 50N, 50D, 50P) and the first indirect vertical cylinder (50F) are disposed adjacent to each other,
The second direct vertical cylinder (50B) and the second indirect vertical cylinder (50M) are disposed adjacent to each other,
And a controller (23) for controlling turning on or off of the first indirect light source, the second indirect light source, the plurality of first direct light sources, and the second direct light source,
The controller is
While the power switch is operated to the ON position, the first indirect light source (61NR, 61DF, 61PF) is turned on,
Only when the specific mode is selected, the corresponding one of the plurality of first direct light sources (63R, 62N, 62D, 62P) is turned on,
Only when the specific mode is selected, turn on the second indirect light source (61BM),
Furthermore, the second direct light source (62B) is turned on only when the specific mode is selected and the combination mode is selected . A display board (4) having a plurality of symbols (40) displayed by illumination from behind;
A light source device (6) having a plurality of light sources (60) for illuminating the symbol;
A partition member (5) disposed between the display plate and the light source device;
The plurality of symbols are:
A plurality of first mode symbols (43R, 42N , 42D, 42P ) indicating a plurality of modes,
A second mode symbol (42B) indicating a combination mode selectable only in a specific mode corresponding to one of the plurality of first mode symbols; and
An operation symbol (41M) indicating an operation method of the selection device for selecting the combination mode ,
The plurality of light sources are
A first indirect light source ( 61NR 1 , 61DF, 61PF ) that indirectly illuminates the plurality of first mode symbols (43R, 42N , 42D, 42P ),
A second indirect light source (61BM) that indirectly illuminates the operation symbol (41M) and the second mode symbol (42B);
A plurality of first direct light sources (63R, 62N , 62D , 62P ) for directly illuminating the plurality of first mode symbols, and a second direct light source (62B) for directly illuminating the second mode symbols;
The partition member (5)
An indirect vertical cylinder (50M) having an opening at one end disposed behind the operation symbol and defining a vertical through hole extending in a vertical direction from the light source device toward the display plate;
A vertical through hole having an opening at one end disposed behind the first mode symbol and an opening at the other end surrounding the first direct light source and extending in a vertical direction from the light source device toward the display plate is defined. A plurality of first direct cylinders (50R, 50N , 50D, 50P ),
A vertical through hole having an opening at one end disposed behind the second mode symbol and an opening at the other end surrounding the second direct light source and extending in a vertical direction from the light source device toward the display plate is defined. The second direct vertical cylinder (50B),
The plurality of first direct light sources ( 61NR 1 , 61DF, 61PF ) with respect to the vertical direction are covered through the communication ports formed at positions close to the light source device of the plurality of first direct vertical tubes. A first horizontal cylinder (51NR , 51DF, 51PF ) defining a recess communicating with a vertical through hole in the vertical cylinder, and the second indirect light source (61BM) with respect to the vertical direction; It communicates with a vertical through hole in the second direct vertical cylinder through a communication port formed at a position close to the light source device, and further through a communication port formed at a position near the light source device in the indirect vertical cylinder. wherein possess second transverse cylinder defining a recess communicating with the longitudinal through hole of the indirect vertical cylinder the (51BM) Te,
The plurality of first direct vertical cylinders (50R, 50N, 50D, 50P) are arranged adjacent to each other,
The second direct vertical cylinder (50B) and the indirect vertical cylinder (50M) are disposed adjacent to each other,
And a controller (23) for controlling turning on or off of the first indirect light source, the second indirect light source, the plurality of first direct light sources, and the second direct light source,
The controller is
While the power switch is operated to the ON position, the first indirect light source (61NR, 61DF, 61PF) is turned on,
Only when the specific mode is selected, the corresponding one of the plurality of first direct light sources (63R, 62N, 62D, 62P) is turned on,
Only when the specific mode is selected, turn on the second indirect light source (61BM),
Furthermore, the second direct light source (62B) is turned on only when the specific mode is selected and the combination mode is selected .   The display according to claim 1, wherein the second horizontal cylinder (51BM) is arranged on a side of the second direct vertical cylinder (50B) and the second indirect vertical cylinder (50M). apparatus.   The display according to claim 1, wherein the second horizontal cylinder (51BM) is disposed so as to overlap the second direct vertical cylinder (50B) and the second indirect vertical cylinder (50M). apparatus.   The display device according to claim 2, wherein the second horizontal cylinder (51BM) is disposed on a side of the second direct vertical cylinder (50B) and the indirect vertical cylinder (50M).   The display device according to claim 2, wherein the second horizontal cylinder (51BM) is disposed so as to overlap the second direct vertical cylinder (50B) and the indirect vertical cylinder (50M).   The light source device (6) includes a circuit board (64) on which light emitting diodes as the plurality of light sources (60) are mounted.
  The partition member (5) is disposed on the circuit board (64),
  The communication port is formed in a partition plate between the vertical cylinder and the horizontal cylinder,
  2. The height (HD) of the emission surface of the light emitting diode from the surface of the circuit board is substantially equal to the height (HW) of the communication port from the surface of the circuit board. The display device according to any one of 6 to 6.   The display device according to claim 1, wherein a light source luminance of the indirect light source is higher than a light source luminance of the direct light source.   The specific mode is a D mode for moving the vehicle forward,
  The display device according to claim 1, wherein the combination mode is a B mode for increasing a power regeneration amount during deceleration in the D mode.

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