WO2019208424A1 - Vehicle display device - Google Patents

Abstract

Provided is a compact vehicle image display device. The vehicle display device (10) has a display means (11) capable of emitting light and a light guide (40) into which the light emitted from the display means (11) enters and in which the entered light travels while being reflected by a first surface (41b) and a second surface (42b) arranged parallel to each other. The light guide (40) has the first surface (41b) and the second surface (42b) arranged along the vehicle width direction, and includes a deflecting unit (42a) that diffracts or reflects the internally passing light and causes the light to be emitted via the first surface (41b).

Description

Vehicle display device

The present invention relates to a vehicle display device that projects light onto a projection target disposed at the front of a vehicle body.

Some vehicles are equipped with a vehicle display device (head-up display device) that projects light onto a projection target such as a windshield and provides necessary information to a driver (viewer). For example, the vehicle display device is provided on a dashboard of the vehicle and projects light toward a windshield. As a conventional technique of such a vehicle display device, there is a technique disclosed in Patent Document 1.

A display device for a vehicle as disclosed in Patent Document 1 includes a display unit that can emit light, a collimating optical system that allows light emitted from the display unit to pass through in parallel light, and the collimating optical system. A light guide that is incident on the first surface and the second surface that are provided in parallel with each other, and the light emitted from the light guide is incident on the windshield. And a reflection mirror that reflects toward the screen.

The light guide is formed so as to emit incident light in an oblique direction from the first surface.

The reflection mirror is disposed in front of the light guide, and reflects light transmitted through the light guide toward the windshield.

The driver recognizes that an image is projected in front of the windshield by projecting the light emitted from the vehicle display device onto the windshield.

JP 2014-191143 A

For example, the vehicle display device is attached to the dashboard space of the vehicle. Here, other parts may be attached to the space where the vehicle display device is attached. Therefore, the space in which the vehicle display device can be attached is limited.

Refer to FIG. FIG. 7 shows a vehicle display device 100 according to Patent Document 1. In the vehicle display device 100 of Patent Document 1, the first and second surfaces 141b and 142b of the light guide 140 are disposed obliquely with respect to the vehicle width direction of the vehicle body. By arranging the light guide body 140 at an angle, the light emitted from the first surface 141b is vertically incident on the reflection mirror 113 provided in front.

In such a vehicle display device, since the light guide body is inclined, a space in which the vehicle display device can be mounted has to be secured widely in the front-rear direction of the vehicle body.

An object of the present invention is to provide a compact vehicle display device.

According to the first aspect of the present invention, in the vehicle display device that projects light onto the projection portion provided in the front portion of the vehicle body and causes the viewer to recognize the light projected onto the projection portion as a virtual image.
Display means capable of emitting light, collimating optical system for allowing the light emitted from the display means to pass in parallel light, and light that has passed through the collimating optical system are incident and the incident light is parallel to each other A light guide that reflects and travels by reflecting the first surface and the second surface provided; and an incident light correction member that corrects the light emitted from the first surface in a predetermined direction.
The light guide is arranged such that the first surface and the second surface are both along the vehicle width direction of the vehicle body, and diffracts or reflects light passing through the first light guide. A vehicular display device is provided that includes a deflecting unit that emits light from a surface.

As described in claim 2, preferably, the incident angle of the light that passes through the collimating optical system and is incident on the light guide is a critical angle that is the minimum angle at which the light incident on the light guide is totally reflected. In this case, the angle is larger than this critical angle.

As described in claim 3, preferably, the collimating optical system includes a collimating lens that transmits light so that light is incident on the first surface,
The collimating lens is a liquid crystal polymer lens or a lenticular lens in which a light incident surface and a light output surface are formed substantially parallel to each other.

Preferably, the incident light correction member is a liquid crystal polymer lens or a lenticular lens in which a light incident surface and a light output surface are formed substantially parallel to each other.

In the invention according to claim 1, the light guide is disposed such that the first surface and the second surface are both along the vehicle width direction of the vehicle body. Furthermore, the light guide includes a deflecting unit that diffracts or reflects light passing through the inside and emits the light from the first surface. First, by arranging the first and second surfaces along the vehicle width direction of the vehicle body, the light guide is arranged substantially parallel to the vehicle width direction. As a result, the vehicle display device can shorten the width in the front-rear direction, and becomes smaller. Further, the light guide includes a deflecting portion that diffracts or reflects light passing through the inside and emits light from the first surface, so that the light guide is disposed substantially parallel to the vehicle width direction. However, light can be emitted forward. That is, a compact vehicle display device can be provided.

In the invention which concerns on Claim 2, the incident angle of the light which passes through a collimating optical system and injects into the 1st surface and 2nd surface of a light guide is the light which injected into the 1st surface and 2nd surface If the minimum angle for total reflection is the critical angle, the angle is larger than this critical angle. By setting the incident angle of light on the first surface to an angle larger than the critical angle, the light incident on the first surface is first totally reflected by the first surface. A part of the light reflected by the first surface is diffracted by the deflecting unit, and the rest is incident on the second surface. Thereafter, the light incident on the second surface is incident on the second surface at an angle larger than the critical angle, and thus is totally reflected on the second surface. That is, by making the incident angles to the first surface and the second surface larger than the critical angle, it is possible to reflect light on the first and second surfaces without losing light energy. As a result, it is not necessary to provide a reflective film that reflects light on the first surface or the second surface. Thereby, an inexpensive vehicle display device can be provided.

In the invention according to claim 3, the collimating optical system has a collimating lens that transmits light so that the light is incident on the first surface. The collimating lens is a liquid crystal polymer lens or a lenticular lens in which a light incident surface and a light output surface are formed substantially parallel to each other. Since the light incident surface and the light output surface are substantially parallel to each other, the lens becomes thin. That is, a thinner lens is assembled to the vehicle display device. As a result, a more compact vehicle display device can be provided.

In the invention according to claim 4, the incident light correction member is a liquid crystal polymer lens or a lenticular lens in which a light incident surface and a light output surface are formed substantially parallel to each other. Since the light incident surface and the light output surface are substantially parallel to each other, the lens becomes thin. That is, a thinner lens is assembled to the vehicle display device. As a result, a more compact vehicle display device can be provided.

It is sectional drawing of the vehicle body front-back direction of the display apparatus for vehicles by Example 1 of this invention. FIG. 2 is a 2-2 cross-sectional view of the vehicle display device shown in FIG. 1. FIG. 3 is a 3-3 cross-sectional view of the vehicle display device shown in FIG. 2. It is a figure which shows the effect | action of the display apparatus for vehicles by Example 1. FIG. It is a figure which shows the example of a change of the collimating lens by Example 1, and a light guide. It is sectional drawing of the display apparatus for vehicles by Example 2. FIG. It is a figure explaining the problem at the time of mounting the conventional vehicle display apparatus in a vehicle.

Embodiments of the present invention will be described below with reference to the accompanying drawings. In the description, front and rear refer to front and rear based on the traveling direction of the vehicle, and left and right refer to right and left based on the passenger. In the figure, Fr indicates the front, Rr indicates the rear, Le indicates the left, Ri indicates the right, Up indicates the top, and Dn indicates the bottom.
<Example 1>

Refer to FIG. FIG. 1 shows a cross-sectional view in the vehicle longitudinal direction of a vehicle Ve on which the vehicle display device 10 is mounted. The vehicle display device 10 is attached to, for example, a dashboard space of the vehicle Ve, and projects light onto the vehicle windshield Ws (projected portion Ws). By projecting light onto the windshield Ws, the driver Mn (viewer Mn) recognizes that the image I (virtual image I) is projected in front of the windshield Ws. By displaying information such as vehicle speed and navigation information on the projected image I, the driver Mn can obtain information necessary for traveling through the windshield Ws.

Refer to FIG. FIG. 2 is a cross-sectional view of the vehicle display device 10 in the vehicle width direction (left-right direction) of the vehicle body. The vehicle display device 10 includes a case 20, display means 11 fixed inside the case 20, a collimating optical system 30 that allows light emitted from the display means 11 to pass through and is made into parallel light, and the collimator The light guide 40 in which the light that has passed through the optical system 30 enters, the incident light correction member 13 that corrects the light emitted from the light guide 40 in a predetermined direction, and the display unit 11 are controlled. And a control unit 14.

The case 20 is configured by covering the lower case 21 with the upper case 22. The case 20 has a box shape and is made of a synthetic resin that can block light from the outside.

The lower case 21 includes a lower case bottom surface portion 21a and a lower case wall portion 21b raised upward from a side edge of the lower case bottom surface portion 21a.

The upper case 22 has an upper case ceiling portion 22a and an upper case wall portion 22b that is lowered from a side edge of the upper case ceiling portion 22a.

The display means 11 includes a light source 11a capable of emitting light and a display panel 11b through which the light emitted from the light source 11a is transmitted.

The light source 11a has an LED lamp mounted on a substrate. The light source 11a is not limited to one using an LED lamp as long as it can irradiate the display panel 11b.

For the display panel 11b, for example, a transmissive display element such as a TFT (Thin Film Transistor) liquid crystal panel is employed.

The collimating optical system 30 includes a first mirror 31 that reflects the light emitted from the display unit 11, a second mirror 32 that receives the light reflected by the first mirror 31, and the second mirror. A collimating lens 33 that transmits the reflected light and converts the transmitted light into parallel light.

The first mirror 31 includes a first base 31a that is a flat inorganic glass, and a first reflecting portion in which a metal capable of reflecting light is formed in a thin film on the surface of the first base 31a. And 31b.

The first reflecting portion 31b is formed in a thin film shape from a metal such as aluminum.

The second mirror 32 is a second reflecting portion in which a second base material 32a made of flat inorganic glass and a metal capable of reflecting light are formed in a thin film shape on the surface of the second base material 32a. 32b.

The second reflecting portion 32b is formed in a thin film shape from a metal such as aluminum, for example.

The collimating lens 33 has a light incident surface and a light output surface formed substantially parallel to each other. As the collimating lens 33, for example, a liquid crystal polymer lens can be employed. The liquid crystal polymer lens transmits incident light and converts it into parallel light. Further, the collimating lens 33 may be any lens that can change the transmitted light into parallel light, and a lenticular lens can be adopted in addition to the liquid crystal polymer lens. The lenticular lens is, for example, inorganic glass.

Each of the first and second mirrors 31 and 32 and the collimating lens 33 is arranged such that light that has passed through the collimating optical system 30 and entered the light guide 40 is totally reflected inside the light guide 40. . That is, when the critical angle is the minimum angle at which the light incident on the light guide 40 is totally reflected, each of the first and second mirrors 31 and 32 and the collimating lens 33 has a boundary inside the light guide 40. Light is arranged so that the incident angle with respect to the surface is greater than the critical angle.

Refer to FIG. FIG. 3 is a cross-sectional view of the vehicle display device 10 in the vehicle body vertical direction. The light guide 40 is disposed along the vehicle width direction of the vehicle, and emits light toward the windshield Ws (see FIG. 1) located above.

Refer to FIG. The light guide 40 is configured so that the light guide body 41 in which the light that has passed through the collimator lens 33 enters and a part of the light that enters the light guide body 41 are emitted to the outside of the light guide 40. And a light guide diffractive portion 42 that diffracts and reflects the remaining light toward the light guide main body 41.

The light guide body 41 has an incident surface 41a for allowing the light transmitted through the collimator lens 33 to enter the light guide 40, and the light incident from the incident surface 41a is reflected toward the light guide diffraction unit 42. 1 surface 41b and an opposing surface portion 41c which is a surface formed to oppose the first surface 41b. The light guide body 41 is, for example, inorganic glass.

The incident surface portion 41 a is formed at one end portion on the side where the collimating lens 33 is disposed, and makes light transmitted through the collimating lens 33 enter the light guide 40. The incident surface portion 41a is a surface formed obliquely with respect to the first surface 41b and the opposed surface portion 41c when the end portion of the light guide 40 has an acute angle so that light can easily enter the inside.

The first surface 41b is arranged along the vehicle width direction of the vehicle body. The first surface 41b is a boundary surface on which light that has passed through the incident surface portion 41a first reaches. The light that has passed through the collimating optical system 30 and transmitted through the incident surface portion 41a is incident on the first surface 41b at an angle larger than the critical angle. That is, the light passing through the collimating optical system 30 and the incident surface portion 41a is first totally reflected by the first surface 41b.

The opposing surface portion 41c is formed in parallel to the first surface 41b. The light reflected by the first surface 41 b passes through the opposing surface portion 41 c and enters the light guide diffraction portion 42.

The light guide diffracting section 42 is formed integrally with the facing surface section 41c and diffracts a part of incident light, and a second surface 42b that reflects the remaining light incident on the deflecting section 42a. ,have.

The deflecting portion 42a is provided below the facing surface portion 41c, and is incident on the light reflected by the first surface 41b located above the facing surface portion 41c. The deflecting unit 42a diffracts the light in a direction perpendicular to the first surface 41b so that the light incident on the deflecting unit 42a is emitted from the first surface 41b. The deflecting unit 42a is made of, for example, a holographic optical element, and a thin film capable of diffracting light in a predetermined wavelength band is stacked. The deflecting unit 42a diffracts the light incident on the deflecting unit 42a according to the wavelength band and transmits the remaining light.

The deflecting unit 42a is not limited to a holographic optical element as long as it can diffract the incident part of light so that it can pass through the first surface 41b. In addition to the holographic optical element, for example, a black diffraction grating, a liquid crystal polymer diffraction grating, and a blazed diffractive optical element can be employed for the deflecting unit 42a.

The second surface 42b is a surface formed at the lower part of the deflecting portion 42a, and totally reflects the light incident on the second surface 42b toward the first surface 41b. That is, the light incident on the second surface 42b is incident so that the incident angle is larger than the critical angle. The second surface 42b is formed to be parallel to the first surface 41b.

The first and second surfaces 41b and 42b are provided parallel to each other along the vehicle width direction of the vehicle body, and reflect the light incident from the incident surface portion 41a to the other end of the light guide 40. .

The incident light correction member 13 is formed such that light is transmitted therethrough and the light incident surface and the light exit surface are substantially parallel to each other. The incident light correction member 13 is made of, for example, a liquid crystal polymer lens. The incident light correction member 13 is disposed above the first surface 41b and transmits light emitted from the first surface 41b of the light guide 40 toward the upper windshield Ws. Further, the incident light correction member 13 refracts the light transmitted through the incident light correction member 13 so that the light projected onto the windshield Ws and reflected by the windshield Ws becomes parallel light. The incident light correction member 13 only needs to be able to refract light so that the light reflected by the windshield Ws becomes parallel light. In addition to the liquid crystal polymer lens, a lenticular lens can also be adopted. The lenticular lens is, for example, inorganic glass.

Control unit 14 controls blinking of light source 11a. Further, the control unit 14 can project an arbitrary image I (see FIG. 1) in front of the windshield Ws by controlling the voltage of the display panel 11b.

Next, the operation of the vehicle display device 10 according to the first embodiment will be described.

Refer to FIG. For example, the vehicle display device 10 is attached to a dashboard space of the vehicle Ve and emits light toward the windshield Ws. When the light emitted from the vehicle display device 10 is projected onto the windshield Ws, the driver Mn recognizes the projected light as an image I.

Refer to FIG. FIG. 4 shows the optical path of the light emitted from the vehicle display device 10 and the display means 11 and reaching the windshield Ws. The light emitted from the display means 11 passes through the collimating optical system 30 and becomes parallel light, and enters the light guide 40 from the incident surface portion 41a. Thereafter, the light incident on the light guide 40 reaches the first surface 41b and is totally reflected by the first surface 41b. At this time, when the incident angle of light on the first surface 41b is θ and the critical angle that is the minimum angle at which light is totally reflected is γ, the light is reflected on the first surface so that θ> γ. 41b.

The light totally reflected by the first surface 41b goes to the second surface 42b. The light traveling toward the second surface 42b eventually enters the deflecting unit 42a. The deflecting unit 42a diffracts a part of the incident light in a direction perpendicular to the first surface 41b. For this reason, a part of the light incident on the deflecting unit 42a is incident on the first surface 41b perpendicularly and is transmitted through the first surface 41b. On the other hand, the remaining light is totally reflected by the second surface 42b formed below the deflecting portion 42a. At this time, the remaining light incident on the deflecting unit 42a is light so that δ> γ, where δ is the angle of incidence on the second surface 42b and γ is the minimum angle at which the light is totally reflected. Is incident on the second surface 42b.

The light that has passed through the first surface 41b passes through the incident light correction member 13 provided above the first surface 41b and is projected onto the upper windshield Ws. On the other hand, the light totally reflected by the second surface 42b reaches the first surface 41b, and is totally reflected by the first surface 41b toward the second surface 42b.

Thereafter, the light directed toward the second surface 42b eventually enters the deflecting unit 42a, is deflected so that part of the light is perpendicular to the first surface 41b, and the remaining light is the second surface 42b. And is totally reflected by the second surface 42b.

That is, the light that has entered the light guide 40 from the incident surface portion 41 a is reflected by the first and second surfaces 41 b and 42 b and travels inside the light guide 40. While traveling inside the light guide 40, light is diffracted in the vertical direction by the deflecting portion 42a and transmitted through the first surface 41b. The light transmitted through the first surface 41b passes through the incident light correction member 13 disposed above and reaches the windshield Ws disposed further upward.

Next, effects of the vehicle display device 10 according to the first embodiment will be described.

Refer to FIG. The light guide 40 is arranged such that the first surface 41b and the second surface 42b are both along the vehicle width direction of the vehicle body. Further, the light guide 40 includes a deflecting unit 42a that diffracts light passing through the inside and emits the light from the first surface 41b. First, the first and second surfaces 41b and 42b are arranged along the vehicle width direction of the vehicle body, so that the light guide 40 is arranged substantially parallel to the vehicle width direction. As a result, the display device 10 for a vehicle can shorten the width in the front-rear direction and becomes smaller. Further, since the light guide 40 includes a deflecting portion 42a that diffracts light passing through the inside and emits light from the first surface 41b, the light guide 40 is substantially parallel to the vehicle width direction. Even if it arrange | positions, light can be radiate | emitted toward the front. That is, the compact vehicle display device 10 can be provided.

Further, the vehicular display device 10 is incident in the front-rear direction of the light guide 40 by disposing the transmissive incident light correction member 13 above the first surface 41b with the first surface 41b facing upward. It is not necessary to arrange the light correction member. As a result, the width of the vehicle display device 10 can be made shorter in the front-rear direction of the vehicle body. That is, the vehicle display device 10 can be made more compact.

The incident angle of light passing through the collimating optical system 30 and entering the first surface 41b and the second surface 42b of the light guide 40 is such that the light incident on the first surface 41b and the second surface 42b is totally reflected. If the minimum angle is the critical angle, the angle is larger than this critical angle. By making the incident angle of the light on the first surface 41b larger than the critical angle, the light incident on the first surface 41b is first totally reflected by the first surface 41b. A part of the light reflected by the first surface 41b is diffracted by the deflecting unit 42a, and the rest is incident on the second surface 42b. Thereafter, the light incident on the second surface 42b is incident on the second surface 42b at an angle larger than the critical angle, and thus is totally reflected by the second surface 42b. That is, by making the incident angle to the first surface 41b and the second surface 42b larger than the critical angle, the light is reflected by the first and second surfaces 41b and 42b without losing light energy. Can be made. As a result, it is not necessary to provide a reflective film that reflects light on the first surface 41b or the second surface 42b. Thereby, the cheap display apparatus 10 for vehicles can be provided.

The collimating optical system 30 includes a collimating lens 33 that transmits light so that the light is incident on the first surface 41b. The collimating lens 33 is a liquid crystal polymer lens or lenticular lens in which a light incident surface and a light output surface are formed substantially parallel to each other. Since the light incident surface and the light output surface are substantially parallel to each other, the lens becomes thin. That is, a thinner lens is assembled to the vehicle display device 10. As a result, a more compact vehicle display device 10 can be provided.

The incident light correcting member 13 is a liquid crystal polymer lens or a lenticular lens in which a light incident surface and a light output surface are formed substantially parallel to each other. Since the light incident surface and the light output surface are substantially parallel to each other, the lens becomes thin. That is, a thinner lens is assembled to the vehicle display device 10. As a result, a more compact vehicle display device 10 can be provided.

Next, a modified example of the vehicle display device 10 according to the first embodiment will be described.

Refer to FIG. FIG. 5 shows a light guide 40A mounted on a vehicle display device 10A according to a modification. The light guide 40A integrally includes a collimating lens portion 33A that serves to change the transmitted light into parallel light. That is, the collimating lens 33 shown in FIG.

Even when the light guide body 40A configured as described above is used, the predetermined effect of the present invention can be obtained. Furthermore, the number of parts can be reduced by using the light guide 40A in which the collimating lens portion 33A is integrally formed.

<Example 2>
Next, a second embodiment of the present invention will be described with reference to the drawings.

Refer to FIG. FIG. 6 is a cross-sectional view of the second embodiment of the vehicle display device 10B, corresponding to FIG. In the vehicle display device 10B according to the second embodiment, the position where the deflection unit 42a according to the first embodiment is arranged is changed. Other basic structures are common to the vehicle display device 10 according to the first embodiment. About the part which is common in Example 1, a code | symbol is diverted and detailed description is abbreviate | omitted.

The light guide 40B is a light guide body 41B that makes the light that has passed through the collimator lens 33 incident, and a deflection that reflects the light that has entered the light guide body 41B so as to be emitted from the light guide body 41B. Part 42Ba.

The light guide body 41B includes an incident surface 41Ba that allows the light transmitted through the collimator lens 33 to enter the light guide 40B, a first surface 41Bb that reflects the light incident from the incident surface 41Ba, and the first surface 41Bb. And the second surface 41Bc on which the light reflected by the surface 41Bb is incident.

The first surface 41Bb and the second surface 41Bc totally reflect the incident light.

The first surface 41Bb is a boundary surface where light that has passed through the incident surface portion 41Ba reaches first, and totally reflects the incident light toward the second surface 41Bc. The first surface 41Bb receives the light reflected by the second surface 41Bc and totally reflects the incident light toward the second surface 41Bc.

The second surface 41Bc is provided to face the first surface 41Bb. The second surface 41Bc receives a part of the light reflected by the first surface 41Bb and totally reflects the incident light toward the first surface 41Bb.

The deflecting unit 42Ba is provided between the first surface 41Bb and the second surface 41Bc, reflects a part of the incident light in a direction substantially perpendicular to the first surface 41Bb, and the remaining part of the second surface 41Bc. Permeate to the side. In other words, the light reflected by the deflecting unit 42Ba is transmitted through the first surface 41Bb and partly emitted from the first surface 41Bb in the vertical direction. In other words, the deflecting unit 42Ba has a characteristic capable of emitting light in the vertical direction to the light guide 40B.

The deflection unit 42Ba is, for example, a half mirror, and a plurality of the deflection units 42Ba are arranged inside the light guide body 41B. The half mirror is disposed so as to be inclined so that the light reflected by the first surface 41Bb is perpendicularly incident on the first surface 41Bb. The half mirror here refers to a mirror capable of reflecting a part of light. That is, the half mirror does not necessarily have a light reflectance and transmittance of 1: 1. For example, the reflectance and transmittance may be 1: 9, or 2: 8. good. Moreover, the reflectance and the transmittance | permeability of each half mirror arrange | positioned inside the light guide main-body part 41B may differ.

The light guide 40B can be arranged in the vehicle width direction of the vehicle body because the light can be emitted vertically also in the light guide 40B in which the deflection unit 42Ba is arranged in the light guide body 41B. In other words, the first and second surfaces 41Bb and 41Bc can be arranged along the vehicle width direction of the vehicle body. Therefore, also in the vehicle display device 10B according to the second embodiment, the present invention can obtain a predetermined effect.

The vehicle Ve on which the vehicle display devices 10, 10A and 10B according to the present invention are mounted may be a two-wheeled vehicle or a three-wheeled vehicle other than a four-wheeled vehicle.

Also, the first and second mirrors 31 and 32 shown in the embodiment are not essential components. That is, you may abolish these as needed. Conversely, the number of mirrors can be increased as necessary. By increasing the number of mirrors, it is possible to increase the degree of freedom of the optical path until light enters the light guides 40, 40A, and 40B.

Furthermore, the first and second base materials 31a and 32a are described with an example of a flat inorganic glass in the embodiments. However, the first and second base materials 31a and 32a are not limited to a flat inorganic glass as long as a metal film capable of reflecting light can be deposited. That is, the first and second base materials 31a and 32a may be, for example, an acrylic resin or a cycloolefin polymer resin.

Further, the first and second reflecting portions 31b and 32b are described with an example of a metal film such as aluminum deposited on the first and second base materials 31a and 32a in the embodiment. However, the first and second reflecting portions 31b and 32b may be multilayer films that can reflect only light in a predetermined wavelength band (visible light). That is, the first mirror 31 and the second mirror 32 having the first and second reflecting portions 31b and 32b may be cold mirrors.

Furthermore, the light guides 40, 40A, and 40B are described with examples that are inorganic glass in the embodiments. However, the light guides 40, 40 </ b> A, and 40 </ b> B are not limited to inorganic glass as long as the light can be incident on the inside. That is, the light guides 40, 40A, and 40B may be, for example, an acrylic resin or a cycloolefin polymer resin that is a transparent resin.

Further, the projection target part Ws is described as the windshield Ws in the embodiment. However, the projected part Ws is not limited to the windshield Ws as long as it can project the light emitted from the vehicle display devices 10, 10 </ b> A, and 10 </ b> B. That is, the present invention can also be applied to the vehicle display devices 10, 10 </ b> A, and 10 </ b> B that use a so-called combiner as the projection target portion Ws.

That is, the present invention is not limited to the examples as long as the operations and effects of the present invention are exhibited.

The vehicle display devices 10, 10A, and 10B of the present invention are suitable for being mounted on the vehicle Ve.

DESCRIPTION OF SYMBOLS 10, 10A, 10B ... Display apparatus for vehicles 11 ... Display means 13 ... Incident light correction member 20 ... Case 30 ... Collimating optical system 33, 33A ... Collimating lens (collimating lens part)
40, 40A, 40B ... light guides 40b, 40Bb ... first surface 41Bc, 42b ... second surface 42a, 42Ba ... deflection part I ... virtual image (image)
Mn ... Viewer (driver)
Ve ... Vehicle Ws ... Projected part (windshield)

Claims (4)

1. In a vehicle display device that projects light onto a projection unit provided at a front portion of a vehicle body and causes a viewer to recognize the light projected on the projection unit as a virtual image,
   Display means capable of emitting light, collimating optical system for allowing the light emitted from the display means to pass in parallel light, and light that has passed through the collimating optical system are incident and the incident light is parallel to each other A light guide that reflects and travels by reflecting the first surface and the second surface provided; and an incident light correction member that corrects the light emitted from the first surface in a predetermined direction.
   The light guide is arranged such that the first surface and the second surface are both along the vehicle width direction of the vehicle body, and diffracts or reflects light passing through the first light guide. A vehicular display device comprising a deflecting portion for emitting light from a surface.
2. The incident angle of the light that passes through the collimating optical system and is incident on the first surface and the second surface of the light guide is totally reflected by the light incident on the first surface and the second surface. 2. The display device for a vehicle according to claim 1, wherein when the minimum angle is a critical angle, the angle is larger than the critical angle.
3. The collimating optical system has a collimating lens that transmits light so that the light is incident on the first surface;
   3. The vehicle display device according to claim 1, wherein the collimating lens is a liquid crystal polymer lens or a lenticular lens in which a light incident surface and a light emitting surface are formed substantially parallel to each other. .
4. 4. The incident light correction member is a liquid crystal polymer lens or a lenticular lens in which a light incident surface and a light output surface are formed substantially parallel to each other. Vehicle display device.

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