KR20230046395A - Hologram image displaying apparatus for mobility - Google Patents

Abstract

The present invention discloses a holographic image implementation device for mobility, wherein when implementing lighting for mobility, lighting is advanced through the implementation of holographic images, multiple holographic images can be created, and distortion of holographic images is minimized. The holographic image implementation device includes: a light source which irradiates light; a light guide configured so that light irradiated from the light source is incident, and the incident light moves and radiates to the outside; a guide cover in which a plurality of pattern holes having a specific image are formed along the extending direction; and a plurality of half mirrors arranged on the same straight line in the vertical direction of the guide cover.

Description

Hologram image implementation device of mobility {HOLOGRAM IMAGE DISPLAYING APPARATUS FOR MOBILITY}

The present invention relates to a device for realizing a holographic image of mobility in which lighting is enhanced through the realization of a holographic image when realizing lighting for mobility.

In general, mobility is provided with a lighting device for the purpose of enabling a clear view of objects in the driving direction during night driving and for notifying other mobilities or other road users of the driving state of the mobility. A lamp, also called a headlight, is a lighting lamp that illuminates the path ahead of mobility.

These lamps are classified into headlamps, fog lights, turn indicators, brake lights, and reversing lights, and each direction of irradiating light to the road surface is set differently. I'll check out the high beams.

Recently, lamps have been highlighted as design elements other than the function of irradiating light to the road surface, and design elements are considered important along with lighting functions.

The matters described as the background art above are only for improving understanding of the background of the present invention, and should not be taken as an admission that they correspond to prior art already known to those skilled in the art.

KR 20-2000-0000644 U (2000.01.15)

The present invention has been proposed to solve these problems, and when implementing lighting for mobility, lighting is advanced through the implementation of holographic images, a plurality of holographic images can be generated, and holographic images of mobility in which distortion of holographic images is minimized. Its purpose is to provide an implementation device.

A holographic image implementation device for mobility according to the present invention for achieving the above object includes a light source for radiating light; a light guide configured so that the light irradiated from the light source is incident and the incoming light is emitted to the outside while moving; a guide cover formed to surround the light guide and having a plurality of pattern holes having a specific image along an extension direction; and a plurality of half mirrors disposed to extend along the guide cover, into which light emitted through the pattern hole is incident, and arranged on the same straight line in the vertical direction of the guide cover; by including, light emitted from the pattern hole of the guide cover. It is characterized in that an image according to a pattern hole is implemented in each half mirror as it is reflected and transmitted through each half mirror.

The half mirrors are formed to extend along the guide cover, and each half mirror is symmetrically disposed with respect to the guide cover.

The half mirror is characterized in that it is divided into a plurality and arranged along the guide cover to match the pattern holes of the guide cover, respectively.

It is characterized in that the image implementation device including a light source, a light guide, a guide cover, and a half mirror is composed of a plurality and disposed spaced apart in the forward and backward directions, and the half mirrors of each lighting module are disposed to cross each other in the forward and backward directions.

The plurality of half mirrors are inclined at the same inclination, so that a part of the light emitted through the pattern hole of the guide cover is reflected forward in the irradiation direction and the remaining light is transmitted.

A first light source, a first light guide, and a first guide cover are provided on the upper side of the half mirror. As the light emitted through the first pattern hole of the first guide cover moves downward, some light is reflected forward through the half mirror. The remaining light is transmitted, and a second light source, a second light guide, and a second guide cover are provided on the lower side of the half mirror, and the light emitted through the second pattern hole of the second guide cover is moved upward and partially passes through the half mirror. Light is reflected backward and the rest of the light is transmitted, and a reflection mirror is provided at the rear of the half mirror so that the light reflected back through the half mirror is re-reflected and transmitted through the half mirror.

The reflective mirror is characterized in that a portion matching each half mirror is formed to be curved in the forward direction, so that light reflected backward through the half mirror is reflected and moved with a focus on each front half mirror.

The reflective mirror is characterized in that each part matching each half mirror in the front is formed in the same shape as the first pattern hole and the second pattern hole.

The guide cover is provided to be movable in an extension direction, and an actuator is connected to the guide cover to move depending on whether the actuator is operated, so that when the guide cover is moved, the image formation position according to the pattern hole is changed.

The device for realizing a holographic image of mobility having the structure described above improves lighting through the implementation of a holographic image when implementing lighting for mobility, generates a plurality of holographic images, and minimizes distortion of the holographic image.

1 is a diagram showing a device for realizing a holographic image of mobility according to a first embodiment of the present invention.
Figure 2 is a diagram for explaining the image implementation of the device for realizing a holographic image of mobility according to the present invention.
Figure 3 is a diagram for explaining the movement of light in the device for realizing a holographic image of mobility according to the present invention.
4 is a diagram showing a device for realizing a holographic image of mobility according to a second embodiment of the present invention.
5 is a diagram showing a device for realizing a holographic image of mobility according to a third embodiment of the present invention.
FIG. 6 is a diagram for explaining an apparatus for realizing a holographic image of mobility according to a third embodiment shown in FIG. 5;
7 is a diagram showing a device for realizing a holographic image of mobility according to a fourth embodiment of the present invention.
8 is a view showing an embodiment of a reflection mirror;
9 is a view showing another embodiment of a reflective mirror;
10 is a view showing another embodiment of a reflection mirror.
11 is a diagram showing a device for realizing a holographic image of mobility according to a fifth embodiment of the present invention.

Hereinafter, a holographic image implementation device for mobility according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a diagram showing a device for implementing a holographic image of mobility according to a first embodiment of the present invention, FIG. 2 is a diagram for explaining image implementation of the device for implementing a holographic image of mobility according to the present invention, and FIG. It is a diagram for explaining the movement of light in the holographic image implementation device of mobility according to the invention.

4 is a diagram showing a device for realizing a holographic image of mobility according to a second embodiment of the present invention.

5 is a diagram showing a device for implementing a holographic image of mobility according to a third embodiment of the present invention, and FIG. 6 is a diagram for explaining a device for implementing a holographic image of mobility according to a third embodiment shown in FIG. 5 .

7 is a diagram showing a holographic image implementation device for mobility according to a fourth embodiment of the present invention, FIG. 8 is a diagram showing one embodiment of a reflective mirror, and FIG. 9 is a diagram showing another embodiment of a reflective mirror. , FIG. 10 is a view showing another embodiment of a reflective mirror.

11 is a diagram showing a device for realizing a holographic image of mobility according to a fifth embodiment of the present invention.

As shown in FIGS. 1 to 3, the apparatus for implementing a holographic image of mobility according to the present invention includes a light source 100 for radiating light; a light guide 200 configured such that the light irradiated from the light source 100 is incident and the incoming light is emitted to the outside while being moved; A guide cover 300 formed to surround the light guide 200 and having a plurality of pattern holes 310 having a specific image formed along an extension direction; And a plurality of half mirrors 400 disposed to extend along the guide cover 300, into which light emitted through the pattern hole 310 is incident, and disposed on the same straight line in the vertical direction of the guide cover 300. include

The light source 100 may be composed of LEDs, and irradiates light with the light guide 200 .

The light guide 200 is formed to extend in a straight line, and light irradiated from the light source 100 is incident through an end of the light guide 200 . Here, the light sources 100 are respectively installed at both ends of the light guide 200, so that the entire light guide 200 can be uniformly emitted by the light emitted from each light source 100.

The light source 100 and the light guide 200 are installed inside the guide cover 300 . That is, the guide cover 300 is formed to surround the light source 100 and the light guide 200, and a plurality of pattern holes 310 are formed along the extension direction, so that the light emitted from the light guide 200 is patterned. is emitted through the hole 310 . In particular, the pattern hole 310 of the guide cover 300 is formed in a specific image shape, and the image generated by the half mirror 400 is determined according to the shape of the pattern hole 310 . These pattern holes 310 may be formed in various shapes, and each pattern hole 310 may be formed differently.

The half mirror 400 is arranged so that the light emitted through the pattern hole 310 of the guide cover 300 is incident, and is composed of a plurality and arranged on the same straight line in the vertical direction of the guide cover 300. The half mirror 400 is configured to reflect some of the incident light and transmit the remaining part of the light.

Here, the plurality of half mirrors 400 are inclined at the same inclination, so that a part of the light emitted through the pattern hole 310 of the guide cover 300 is reflected forward in the irradiation direction and the remaining light is transmitted.

In this way, since the half mirror 400 is inclined, an image is implemented as the light emitted through the pattern hole 310 of the guide cover 300 is reflected from the inclined surface, and some light is transmitted. In addition, since the plurality of half mirrors 400 are inclined with the same inclination, when light is incident on each half mirror 400, it moves in the same irradiation direction, thereby reducing image distortion.

Due to this, the light irradiated from the light source 100 is emitted through the light guide 200, and the light emitted from the light guide 200 is emitted from the pattern hole 310 of the guide cover 300 to form a half mirror (400). ) is entered into In this way, among the light incident on the half mirror 400, the reflected light forms an image according to the shape of the pattern hole 310 on the half mirror 400 and is implemented as a hologram image M, and the transmitted light is transmitted to the next half mirror. While being reflected at 400, a hologram image M according to the shape of the pattern hole 310 is implemented. As such, in the plurality of half mirrors 400, as the light emitted from the pattern hole 310 of the guide cover 300 is reflected to generate an image, a plurality of hologram images M are generated in each half mirror 400. is implemented

The present invention can be applied to the various embodiments described above.

The half mirrors 400 according to the first embodiment of the present invention are formed to extend along the guide cover 300, and each half mirror 400 is disposed symmetrically with respect to the guide cover 300.

As shown in FIG. 1, the plurality of half mirrors 400 have a shape that extends in a straight line along the guide cover 300, so that the half mirror 400 is easy to form and install, and the overall structure is simplified. .

In addition, when the light irradiated from the light source 100 is emitted from the light guide 200 and enters the half mirror 400 through the pattern hole 310 of the guide cover 300, the pattern hole in the half mirror 400 An image according to the shape of 310 is created. In addition, as the half mirror 400 is formed to extend in a straight line, a background effect of an image generated through the half mirror 400 is generated.

Meanwhile, the half mirror 400 according to the second embodiment of the present invention is divided into a plurality of pieces and arranged along the guide cover 300 to match the pattern holes 310 of the guide cover 300, respectively.

As shown in FIG. 4, the plurality of half mirrors 400 are divided into a plurality of pieces in the extension direction of the guide cover 300, and each half mirror 400 is formed through each pattern hole 310 of the guide cover 300. By being arranged to match, the light emitted through each pattern hole 310 is incident on the half mirror 400, and the image is implemented.

In this way, by dividing the half mirror 400 into a plurality of pieces, the weight of the half mirror 400 is reduced and hologram image formation according to each pattern hole 310 is accurately implemented.

Meanwhile, as a third embodiment of the present invention, as shown in FIGS. 5 and 6, an image implementation device including a light source 100, a light guide 200, a guide cover 300, and a half mirror 400 ( A) consists of a plurality of pieces and is spaced apart in the front-back direction. Here, the half mirrors 400 included in each image implementation device A are divided into a plurality of pieces in the extension direction of the guide cover 300 and are spaced apart at regular intervals.

In addition, each image implementation device (A) is disposed spaced apart in the forward and backward directions, and the half mirror 400 of the image implementation device A1 disposed in the front and the half mirror 400 of the image implementation device A2 disposed in the rear By being arranged to cross each other, as the images implemented in the half mirrors 400 of each image implementation device A are spaced apart in the forward and backward directions, a three-dimensional effect is given to the hologram image.

That is, as light is reflected and transmitted through each half mirror 400 of the image implementation device A1 disposed in the front, an image is generated, and also in each half mirror 400 of the image implementation device A2 disposed in the rear. As the light is reflected and transmitted, an image is generated, so that between the images generated in the half mirror 400 of the image implementation device A1 disposed in the front, in the half mirror 400 of the image implementation device A2 disposed in the rear. As the image is created, a three-dimensional effect is given to the hologram image.

Here, the image implementation device A disposed in the front and rear respectively forms a different shape of the pattern hole 310 formed in each guide cover 300, so that various patterns of hologram images can be implemented.

Meanwhile, according to the fourth embodiment of the present invention, a first light source 100a, a first light guide 200a, and a first guide cover 300a are provided above the half mirror 400, and the first guide cover 300a As the light emitted through the first pattern hole 310a of ) moves downward, some light is reflected forward through the half mirror 400 and the remaining light is transmitted, and the second light source is on the lower side of the half mirror 400. (100b), a second light guide (200b), and a second guide cover (300b) are provided, and the light emitted through the second pattern hole (310b) of the second guide cover (300b) moves upward while the half mirror (400) ) Through which some light is reflected backward and the remaining light is transmitted, and a reflection mirror 500 is provided at the rear of the half mirror 400, and the light reflected backward through the half mirror 400 is re-reflected to form a half mirror ( 400) is transmitted through.

That is, as shown in FIGS. 7 and 8, a plurality of light sources 100, light guides 200, and guide covers 300 are arranged on the upper and lower sides of the half mirror 400, and the half mirror 400 A first light source 100a, a first light guide 200a, and a first guide cover 300a are provided on the upper side of the half mirror 400 centering on , and a second light source 100b on the lower side of the half mirror 400. ), a second light guide 200b, and a second guide cover 300b are provided.

Accordingly, the light irradiated from the first light source 100a is emitted from the first light guide 200a, and as the first pattern hole 310a is formed at the bottom of the first guide cover 300a, the first pattern hole A part of the light emitted from 310a is reflected by the half mirror 400 and moves forward in the irradiation direction, and a part of the light is transmitted and moved to the next half mirror 400.

In addition, the light irradiated from the second light source 100b is emitted from the second light guide 200b, and as the second pattern hole 310b is formed at the top of the second guide cover 300b, the second pattern hole ( A part of the light emitted from 310b) is reflected by the half mirror 400 and moves backward, which is opposite to the irradiation direction, and a part of the light emitted is transmitted to the next half mirror 400.

At this time, when the light irradiated from the second light source 100b is reflected by the half mirror 400 and moves backward, it is reflected again by the reflective mirror 500 provided at the rear of the half mirror 400 and moves forward, thereby moving the half mirror 400 forward. (400). For this reason, an image according to the second pattern hole 310b is formed even by the light irradiated from the second light source 100b.

Through this, in the fourth embodiment, the brightness and sharpness of images generated by all the half mirrors 400 are secured. That is, each of the half mirrors 400 arranged from the upper side to the lower side is generated in the uppermost half mirror 400 as the light irradiated from the first light source 100a is reflected on the uppermost half mirror 400 that is incident first. The brightness of the image is the brightest. As the light irradiated from the second light source 100b is reflected on the lowermost half mirror 400 and then re-reflected through the reflective mirror 500 and transmitted forward, the lowermost half mirror 400 The brightness of the generated image is secured.

On the other hand, in the above-described reflective mirror 500, a portion matching each half mirror 400 is formed to be curved, so that the light reflected backward through the half mirror 400 is reflected on each half mirror 400 on the front side. It can be reflected and moved with a focus on .

That is, as shown in FIG. 9, the reflective mirror 500 is formed to be curved in a parabolic shape to form a focal point, and as the focal point is formed to be located at the half mirror 400, the light reflected by the reflective mirror 500 In the half mirror 400, the image is accurately incident on the position where it is to be generated. Accordingly, as the light irradiated from the second light source 100b is reflected by the reflective mirror 500 and re-incident to the position where the image is created in the half mirror 400, the brightness by the light of the second light source 100b and sharpness are secured.

In addition, each part of the reflection mirror 500 that matches each half mirror 400 in the forward direction may be formed in the same shape as the first pattern hole 310a and the second pattern hole 310b.

That is, as shown in FIG. 10, the reflection mirror 500 is formed in the same shape as the first pattern hole 310a or the second pattern hole 310b for each half mirror 400, thereby reflecting the reflection. As the light reflected by the mirror 500 is implemented as the same image as the image generated by the half mirror 400, the brightness and sharpness of the image generated by the half mirror 400 are secured.

The reflection mirror 500 is divided to match each half mirror 400, or a portion matching each half mirror 400 protrudes from one reflection mirror 500 to form a first pattern hole 310a or It may be formed to match the second pattern hole 310b.

On the other hand, according to the fifth embodiment of the present invention, as shown in Figure 11, the guide cover 300 is provided to be movable in the extension direction, the actuator 600 is connected to the guide cover 300, the actuator ( 600) may be configured to be moved depending on whether the operation is performed or not.

That is, the guide cover 300 is slidably moved in the extension direction and the position thereof is variable, and the actuator 600 is connected to the guide cover 300 to control the position of the guide cover 300 . The actuator 600 may be operated under the control of a controller, and the moving direction or moving speed or moving position of the guide cover 300 may be determined according to various lighting functions. In addition, the actuator 600 may be composed of a piezo actuator 600, and various driving methods such as a gear connection method may be applied.

Due to this, as the guide cover 300 changes its position while sliding during the operation of the actuator 600, the position of the light emitted through the pattern hole 310 of the guide cover 300 changes, so that the half mirror ( 400), the formation position of the generated image is changed. In this way, various lighting patterns can be implemented through the position change of the image generated on the half mirror 400 .

The device for realizing a holographic image of mobility having the structure described above improves lighting through the implementation of a holographic image when implementing lighting for mobility, generates a plurality of holographic images, and minimizes distortion of the holographic image.

Although the present invention has been shown and described in relation to specific embodiments, it is known in the art that the present invention can be variously improved and changed without departing from the technical spirit of the present invention provided by the claims below. It will be self-evident to those skilled in the art.

100: light source (100) 100a: first light source
100b: second light source 200: light guide 200
200a: first light guide 200b: second light guide
300: guide cover 300a: first guide cover
300b: second guide cover 310: pattern hole
310a: first pattern hole 310b: second pattern hole
400: half mirror 500: reflective mirror
600: actuator
Image implementation device placed in the front
Image (M)

Claims (9)

a light source that irradiates light;
a light guide configured so that the light irradiated from the light source is incident and the incoming light is emitted to the outside while moving;
a guide cover formed to surround the light guide and having a plurality of pattern holes having a specific image along an extension direction; and
A plurality of half mirrors disposed extending along the guide cover, into which light emitted through the pattern hole is incident, and disposed on the same straight line in the vertical direction of the guide cover;
A holographic image implementation device for mobility, characterized in that the image according to the pattern hole is implemented in each half mirror as the light emitted from the pattern hole of the guide cover is reflected and transmitted through each half mirror. The method of claim 1,
The half mirror is formed to extend along the guide cover, and each half mirror is disposed symmetrically with respect to the guide cover. The method of claim 1,
A holographic image implementation device for mobility, characterized in that the half mirror is divided into a plurality and arranged along the guide cover to match each pattern hole of the guide cover. The method of claim 3,
A plurality of image implementation devices including a light source, a light guide, a guide cover, and a half mirror are arranged spaced apart in the forward and backward directions,
A holographic image implementation device for mobility, characterized in that the half mirrors of each lighting module are arranged to cross in the front and rear directions. The method of claim 1,
A plurality of half mirrors are inclined at the same inclination, so that a part of the light emitted through the pattern hole of the guide cover is reflected forward in the direction of irradiation and the remaining light is transmitted. The method of claim 1,
A first light source, a first light guide, and a first guide cover are provided on the upper side of the half mirror. As the light emitted through the first pattern hole of the first guide cover moves downward, some light is reflected forward through the half mirror. the rest of the light is transmitted
A second light source, a second light guide, and a second guide cover are provided on the lower side of the half mirror. As the light emitted through the second pattern hole of the second guide cover moves upward, some light is reflected backward through the half mirror. the rest of the light is transmitted
A holographic image implementation device for mobility, characterized in that a reflection mirror is provided at the rear of the half mirror, and light reflected backward through the half mirror is re-reflected and transmitted through the half mirror. The method of claim 6,
The reflective mirror is a holographic image of mobility, characterized in that the part that matches each half mirror is formed to be curved in the forward direction, so that the light reflected backward through the half mirror is reflected and moved with a focus on each half mirror in the front. implementation device. The method of claim 6,
The holographic image implementation device of mobility, characterized in that each part of the reflection mirror forwardly matched with each half mirror is formed in the same shape as the first pattern hole and the second pattern hole. The method of claim 1,
The guide cover is provided to be movable in the extension direction,
An actuator is connected to the guide cover and moved according to whether the actuator is operating, so that when the guide cover is moved, the formation position of the image according to the pattern hole is changed.

Images