CN213513728U

CN213513728U - Car light lighting system and car light

Info

Publication number: CN213513728U
Application number: CN202022227983.6U
Authority: CN
Inventors: 谢晨; 邱柏渝
Original assignee: Shanghai Zhitong Daohe Industry Co ltd
Current assignee: Zhejiang Bihu Technology Co.,Ltd.
Priority date: 2020-10-09
Filing date: 2020-10-09
Publication date: 2021-06-22
Anticipated expiration: 2030-10-09

Abstract

The utility model discloses a car light lighting system and car light, its system includes: the device comprises an illumination light path, a DMD chip and a projection light path, wherein the illumination light path comprises a laser light source module, a first illumination lens group, a wavelength conversion component and a second illumination lens group which are sequentially arranged; laser emitted by the laser source module forms light spots in sequence through the first illumination lens group to be incident to the wavelength conversion component, white light beams formed through conversion of the wavelength conversion component are incident to the second illumination lens group, are reflected to the sixth illumination lens in the third illumination lens group through the first reflector in the third illumination lens group, are reflected to the DMD chip through the second reflector in the third illumination lens group, and are reflected to the projection light path through the DMD chip to perform illumination projection. The utility model discloses a car light lighting system can throw the pattern of needs subaerial, and because all light through the illumination light path all hit the DMD chip partly on, reduce the waste of light energy, improve whole lighting system's conversion efficiency.

Description

Car light lighting system and car light

Technical Field

The utility model relates to a vehicle lighting field especially relates to a car light lighting system and car light.

Background

Projection apparatuses are used in a wide variety of applications, such as projectors in offices, projection apparatuses in movie theaters, and the like, for projecting light onto a screen and projecting a desired pattern on the screen.

The head lamp of the automobile is the maximum guarantee that the automobile can safely run at night, and besides the anti-dazzling function, the head lamp also has the function of projecting images on the ground, so that the human-vehicle interaction function is realized. However, in the prior art, the patterns projected on the ground are determined according to the blocking sheets for installing various patterns on the headlamp, and the blocking sheets are switched manually or automatically, so that the patterns capable of being projected on the ground are very limited and are not intelligent enough, and meanwhile, the conversion efficiency of the lighting system in the prior art is low.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a car light lighting system and car light, this car light lighting system not only can throw the pattern that needs subaerial, still improves whole lighting system's conversion efficiency.

The utility model provides a technical scheme as follows:

a vehicular lamp illumination system comprising:

the light emitted by the illumination light path enters a part of the DMD chip and is reflected to the projection light path, and the projection light path projects the light reflected by the DMD chip;

the illumination light path comprises a laser light source module, a first illumination lens group, a wavelength conversion component and a second illumination lens group which are sequentially arranged;

laser emitted by the laser source module sequentially passes through the first illumination lens group to form light spots to be incident to the wavelength conversion component, white light beams formed by conversion of the wavelength conversion component are incident to the second illumination lens group, are reflected to the sixth illumination lens in the third illumination lens group through the first reflector in the third illumination lens group, are reflected to the DMD chip through the second reflector in the third illumination lens group, and are reflected to the projection light path through the DMD chip to perform illumination projection.

Preferably, the first illumination lens group comprises a first illumination lens, a fly eye lens, a second illumination lens and a third illumination lens which are arranged in sequence;

the first lighting lens is arranged opposite to the laser light source module, and is used for receiving laser emitted by the laser light source module and transmitting the laser to the fly eye lens;

the fly eye lens is used for receiving and homogenizing the laser emitted by the first illuminating lens and transmitting the laser to the second illuminating lens;

the third illuminating lens is arranged opposite to the wavelength conversion material, and the second illuminating lens and the third illuminating lens collimate and transmit the homogenized laser to the wavelength conversion material.

Preferably, the second illumination lens group comprises a fourth illumination lens and a fifth illumination lens;

the third illumination lens group comprises a first reflector, a sixth illumination lens and a second reflector;

the fourth illumination lens and the third illumination lens are the same in shape and are symmetrical to each other.

Preferably, the laser light source module, the first illumination lens group and the second illumination lens group are coaxial and form a preset first angle with a horizontal plane;

the included angle interval between the first reflector and the horizontal plane is a preset second angle interval, and the included angle interval between the second reflector and the horizontal plane is a preset third angle interval;

the central axis of the sixth illumination lens deviates from the preset first angle towards the direction away from the DMD chip, and the first reflector and the second reflector extend upwards towards the opposite direction.

Preferably, the focal length f102 of the first illumination lens is between 40mm and 70 mm;

the thickness d103 of the fly-eye lens is more than 3 mm;

the focal length f104 of the second illumination lens is between-40 mm and-15 mm, and the absolute values of the curvature radiuses of the front surface and the rear surface of the second illumination lens are equal;

the focal length f105 of the third lighting lens is between 15mm and 40 mm;

the focal length f106 of the sixth lighting lens is between 40mm and 50 mm.

Preferably, the focal number of the projection light path ranges from 27.5mm to 29.5 mm.

Preferably, the projection optical path includes a first projection lens, a second projection lens, a third projection lens, a fourth projection lens, a diaphragm, a fifth projection lens, and a sixth projection lens, which are arranged in sequence, where the focal power of the first projection lens is positive, the focal power of the second projection lens is positive, the focal power of the third projection lens is positive, the focal power of the fourth projection lens is negative, the focal power of the fifth projection lens is negative, and the focal power of the sixth projection lens is positive;

the first projection lens, the second projection lens, the third projection lens, the fourth projection lens, the diaphragm, the fifth projection lens and the sixth projection lens are coaxial and parallel to the horizontal plane, and laser reflected by the DMD chip sequentially passes through the first projection lens, the second projection lens, the third projection lens, the fourth projection lens, the diaphragm, the fifth projection lens and the sixth projection lens and is projected out.

Preferably, the focal length f301 of the first projection lens is between 60mm and 100 mm;

the focal length f302 of the second projection lens is between 60mm and 100 mm;

the third projection lens and the fourth projection lens form a cemented lens through cementing;

the curvature radius r305a of the fifth projection lens close to the diaphragm is between 15mm and 25mm, the curvature radius r305b of the fifth projection lens far from the diaphragm is between 40mm and 50mm, and the refractive index Nd305 of the fifth projection lens is between 1.5 and 1.65;

and the focal length f306 of the sixth projection lens is between 40mm and 55 mm.

In the structure, the first projection lens and the second projection lens can effectively reduce coma aberration of the projection lens and improve imaging quality. The third projection lens and the fourth projection lens form a cemented lens for improving the chromatic aberration of the projection light path and keeping the illumination system at a higher contrast. The intensity of the light beam passing through the diaphragm is adjusted, and then the light beam passes through the fifth projection lens and the sixth projection lens respectively.

The vehicle lamp comprises the vehicle lamp lighting system.

Be applied to the head-light department of car with this car light lighting system, through DMD chip control projection at subaerial pattern, only be the separation blade pattern of limited quantity for pattern among the prior art, the utility model discloses a pattern is more diversified, and in whole projection in-process, all light through the illumination light path all hit the DMD chip partly in addition on, do not cause the waste of light energy, improved the conversion efficiency of whole car light illumination light path.

The utility model provides a pair of car light lighting system and car light can bring following beneficial effect:

1) the utility model discloses a car light lighting system can throw out different patterns, and because all light through the illumination light path all hit the partly of DMD chip on, reduce the waste of light energy, improved the conversion efficiency of whole car light illumination light path.

2) When the pattern is applied to an automobile, the pattern can be projected on the ground as a headlamp, the illumination requirement of the headlamp of the automobile is met, and the illumination of the central brightest point can reach more than 150 lx.

3) The utility model discloses in, because specific setting has been done to the parameter of lens, the picture proportion need not to design according to DMD's proportion, realizes the illumination of inhomogeneous light through the specific parameter cooperation of lens, and the grading light type is close car light type distribution, has avoided the waste of light.

Drawings

The above features, technical features, advantages and implementations of a vehicle lamp lighting system and applications thereof will be further described in the following detailed description of preferred embodiments in a clearly understandable manner with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of a vehicle lamp lighting system according to the present invention;

FIG. 2 is a schematic diagram of the structure of the illumination optical path and the DMD chip in FIG. 1;

FIG. 3 is a schematic diagram of the structure of the projection light path in FIG. 1;

fig. 4 is a schematic diagram of the projection area of the present invention.

The reference numbers illustrate:

10-illumination optical path, 101-laser light source module, 102-first illumination lens, 103-fly eye lens, 104-second illumination lens, 105-third illumination lens, 106-wavelength conversion material, 107-fourth illumination lens, 108-fifth illumination lens, 109-sixth illumination lens, 20-DMD chip, 30-projection optical path, 301-first projection lens, 302-second projection lens, 303-third projection lens, 304-fourth projection lens, 305-diaphragm, 306-fifth projection lens, 307-sixth projection lens, M1-first reflector, M2-second reflector.

Detailed Description

In order to more clearly illustrate embodiments of the present invention or technical solutions in the prior art, specific embodiments of the present invention will be described below with reference to the accompanying drawings. It is obvious that the drawings in the following description are only examples of the invention, and that for a person skilled in the art, other drawings and embodiments can be obtained from these drawings without inventive effort.

For the sake of simplicity, the drawings only schematically show the parts relevant to the present invention, and they do not represent the actual structure of the product.

[ examples 1 to 3 ]

As shown in fig. 1 to 4, the embodiment discloses a specific implementation of a vehicle lamp lighting system, which includes: the LED light source comprises an illumination light path, a DMD chip and a projection light path, wherein light emitted from the illumination light path enters a part of the DMD chip and is reflected to the projection light path, and the projection light path projects the light reflected by the DMD chip, so that a pattern required by a ground projection position can be projected and the front can be illuminated.

As shown in fig. 2, the illumination light path includes a laser light source module, a first illumination lens, a fly-eye lens, a second illumination lens, a third illumination lens, a wavelength conversion material, a fourth illumination lens, a fifth illumination lens, a first reflector, a sixth illumination lens, and a second reflector, which are arranged in sequence, wherein the fourth illumination lens and the third illumination lens have the same shape, and the fourth illumination lens and the third illumination lens are symmetrical to each other.

The focal power of the first lighting lens is positive, the focal power of the second lighting lens is negative, the focal power of the third lighting lens is positive, the focal power of the fourth lighting lens is positive, the focal power of the fifth lighting lens is positive, and the focal power of the sixth lighting lens is positive.

The wavelength conversion material may include a fluorescent color wheel and other devices capable of converting a white light beam, and it should be noted that when the focal power is positive, the refractive convergence of the parallel light beams is positive; when the focal power is negative, the refraction is divergent, so that the parallel light beams are still parallel after being incident, and meanwhile, the third illumination lens and the fourth illumination lens are symmetrically designed, so that the cost is reduced.

Structurally, the laser light source module, the first illuminating lens, the fly eye lens, the second illuminating lens, the third illuminating lens, the wavelength conversion material, the fourth illuminating lens and the fifth illuminating lens are coaxial and form 12 degrees with the horizontal plane, namely a line B parallel to the horizontal plane extends out of the center of the laser light source module, the included angle between the coaxial direction far away from the DMD chip and the line B is 12 degrees, the included angle between the first reflecting mirror and the horizontal plane is 34-46 degrees, the included angle between the second reflecting mirror and the horizontal plane is 24-36 degrees, along the advancing direction of laser, the central axis of the sixth illuminating lens deviates 12 degrees towards the direction far away from the DMD chip, the first reflecting mirror and the second reflecting mirror extend upwards towards opposite directions, specifically, the first reflecting mirror is inclined towards the DMD chip from bottom to top along the height direction of the first reflecting mirror, the second reflecting mirror is inclined from bottom to top along the height direction of the second reflecting mirror, and is inclined towards the direction away from the DMD chip.

As shown in FIG. 3, the effective focal length of the projection optical path ranges from 27.5mm to 29.5mm, and the focal number of the projection optical path ranges from 27.5mm to 29.5 mm.

The projection light path comprises a first projection lens, a second projection lens, a third projection lens, a fourth projection lens, a diaphragm, a fifth projection lens and a sixth projection lens which are sequentially arranged, wherein the third projection lens and the fourth projection lens form a cemented lens through gluing.

The focal power of the first projection lens is positive, the focal power of the second projection lens is positive, the focal power of the third projection lens is positive, the focal power of the fourth projection lens is negative, the focal power of the fifth projection lens is negative, and the focal power of the sixth projection lens is positive. The first projection lens, the second projection lens, the third projection lens, the fourth projection lens, the diaphragm, the fifth projection lens and the sixth projection lens are coaxial and parallel to the horizontal plane.

As shown in fig. 2, the arrow a in the traveling directional diagram of the laser light indicates that the laser light emitted by the laser light source module sequentially passes through the first illumination lens, the fly-eye lens, the second illumination lens, the third illumination lens, the wavelength conversion material, the fourth illumination lens, and the fifth illumination lens, is reflected by the first reflector, passes through the sixth illumination lens, and is reflected by the second reflector onto the DMD chip, and the laser light reflected by the DMD chip sequentially passes through the first projection lens, the second projection lens, the third projection lens, the fourth projection lens, the diaphragm, the fifth projection lens, and the sixth projection lens, and is projected.

When the light path is applied to an automobile and used as a headlamp, the headlamp is replaced by the lighting light path, so that a required pattern can be projected on the ground, and a certain area can be illuminated in front of the automobile, and the area meets the lighting requirement of the headlamp of the automobile.

The following parameters (focal length, radius of curvature of front surface, radius of curvature of back surface, refractive index of material, abbe number of material, distance between adjacent surfaces) of the above lenses were obtained as examples 1 to 3 using different values and are correspondingly recorded in tables 1 to 6, respectively.

Example 1:

[ TABLE 1 ]

In table 1, the distance between adjacent surfaces represents the distance from the midpoint of the corresponding surface of the row to the midpoint of the surface of the next row, and the surface numbers are numbered along the penetration sequence of the laser, for example: the surface of the first illumination lens close to the laser light source module is S1, the surface of the first illumination lens far away from the laser light source module is S2, and so on.

[ TABLE 2 ]

In table 2, the distance between adjacent surfaces represents the distance from the midpoint of the corresponding surface of the row to the midpoint of the surface of the next row, and the surface numbers are numbered along the penetration sequence of the laser, for example: the surface of the first projection lens close to the DMD chip is Y1, the surface of the first projection lens far from the DMD chip is Y2, and so on.

The laser emitted by the laser light source module in embodiment 1 passes through the illumination light path and then enters 3/4 of the DMD chip, that is, 3/4 of the DMD chip is illuminated, and is reflected by the DMD chip and then is projected out through the projection light path, the angle of the projected light is 18 ° × 13 ° (horizontal direction × vertical direction), the projection area at the position 25m in front of the automobile is 8 mx 5.55m (horizontal direction × vertical direction), and the illuminance of the brightest point in the center is 210 lx.

As shown in fig. 4, the illumination area and the screen projection area in the drawing indicate portions irradiated on the ground, the screen projection area is 5m to 25m in front of the vehicle, the illumination area is 25m to infinity in front of the vehicle, a pattern to be projected is projected in the screen projection area, and the anti-glare area in the drawing actually refers to an area where light rays are projected on a vertical plane at a distance of 25 meters from the front of the vehicle, that is, the area is 8m × 5.55 m.

Example 2:

[ TABLE 3 ]

[ TABLE 4 ]

The table of this example has the same meaning as in example 1.

In embodiment 2, the laser emitted from the laser light source module passes through the illumination light path and then is incident on 73% of the area of the DMD chip, that is, 73% of the DMD chip is illuminated, and is reflected by the DMD chip, and is projected out through the projection light path, the angle of the projected light is 17.8 ° × 13 ° (horizontal direction × vertical direction), the projection area at the position 25m in front of the automobile is 7.8 × 5.55m, and the illuminance of the brightest point in the center is 214 lx.

Example 3:

[ TABLE 5 ]

[ TABLE 6 ]

The table of this example has the same meaning as in example 1.

The laser emitted by the laser light source module in embodiment 3 passes through the illumination light path and then is incident on 77% of the area of the DMD chip, that is, 77% of the DMD chip is illuminated, and is reflected by the DMD chip, and is projected out through the projection light path, the angle of the projected light is 18.2 ° × 13 ° (horizontal direction × vertical direction), the projection area at the position 25m in front of the automobile is 8.2 × 5.55m, and the illuminance of the brightest point in the center is 203 lx.

The conversion efficiency of the lamp lighting system obtained by the test using the example 1 to example 3 in an automobile as a headlamp is shown in table 7.

[ TABLE 7 ]

While the illuminance of the brightest point in the center of the headlamp in the prior art is 100lx to 150lx and the conversion efficiency of the optical system of the DLP projector in the prior art is 65, it can be seen from table 7 that the conversion efficiency of examples 1 to 3 is higher than that of the prior art by 5% to 10%, the light energy can be more sufficiently utilized, and the illuminance of examples 1 to 3 is significantly higher.

Example 4

The utility model also provides a car light illumination method, throw light on through the car light lighting system of any embodiment in embodiment 1 ~ 3.

In this embodiment, laser emitted by the laser light source module sequentially passes through the first illumination lens group to form a light spot, and then enters the wavelength conversion component, a white light beam formed by conversion of the wavelength conversion component enters the second illumination lens group, and is reflected to the sixth illumination lens in the third illumination lens group by the first reflector in the third illumination lens group, and then is reflected to the DMD chip by the second reflector in the third illumination lens group, and is reflected to the projection optical path by the DMD chip to perform illumination projection.

The conversion efficiency of the lighting of the vehicle lamp can be improved, and meanwhile, the brightness and the illumination area of the vehicle lamp are improved.

Example 5

The utility model also provides a car light has used the car light lighting system in the arbitrary embodiment in embodiment 1 ~ 3 to throw light on.

Specifically, the vehicle lamp can comprise a front vehicle lamp of an automobile, and when the vehicle lamp needs to be used for lighting and projecting, the vehicle lamp can be used for lighting and projecting with high conversion rate, high brightness and large area by implementing the vehicle lamp lighting system of any one of 1-3.

It should be noted that the above embodiments can be freely combined as necessary. The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims

1. A vehicular lamp lighting system characterized by comprising:

2. The vehicular lamp illumination system according to claim 1, characterized in that:

the first illumination lens group comprises a first illumination lens, a fly-eye lens, a second illumination lens and a third illumination lens which are sequentially arranged;

the third illuminating lens is arranged opposite to the wavelength conversion component, and the second illuminating lens and the third illuminating lens collimate and transmit the homogenized laser to the wavelength conversion component.

3. The vehicular lamp illumination system according to claim 1, characterized in that:

the second illumination lens group comprises a fourth illumination lens and a fifth illumination lens;

4. The vehicular lamp illumination system according to claim 1, characterized in that:

the laser light source module, the first illumination lens group and the second illumination lens group are coaxial and form a preset first angle with the horizontal plane;

5. The vehicular lamp illumination system according to claim 2, characterized in that:

focal length f of the first illumination lens₁₀₂Between 40mm and 70 mm;

thickness d of the fly-eye lens₁₀₃＞3mm；

Focal length f of the second illumination lens₁₀₄Between-40 mm and-15 mm, and the absolute values of the radii of curvature of the front and rear surfaces of the second illumination lens are equal;

focal length f of the third illumination lens₁₀₅Between 15mm and 40 mm;

a focal length f of the sixth illumination lens₁₀₆Between 40mm and 50 mm.

6. The vehicular lamp illumination system according to claim 1, characterized in that:

the focal number range of the projection light path is 27.5 mm-29.5 mm.

7. The vehicular lamp illumination system according to claim 1, characterized in that:

the projection optical path comprises a first projection lens, a second projection lens, a third projection lens, a fourth projection lens, a diaphragm, a fifth projection lens and a sixth projection lens which are sequentially arranged, wherein the focal power of the first projection lens is positive, the focal power of the second projection lens is positive, the focal power of the third projection lens is positive, the focal power of the fourth projection lens is negative, the focal power of the fifth projection lens is negative, and the focal power of the sixth projection lens is positive;

8. The vehicular lamp illumination system according to claim 7, characterized in that:

focal length f of the first projection lens₃₀₁Between 60mm and 100 mm;

focal length f of the second projection lens₃₀₂Between 60mm and 100 mm;

radius of curvature r of the fifth projection lens close to the diaphragm_305aThe curvature radius r of the fifth projection lens far away from the diaphragm is between 15mm and 25mm_305bThe refractive index Nd of the fifth projection lens is between 40mm and 50mm₃₀₅Between 1.5 and 1.65;

focal length f of the sixth projection lens₃₀₆Between 40mm and 55 mm.

9. A vehicular lamp characterized by comprising the vehicular lamp illumination system according to any one of claims 1 to 8.