CN203671512U - LED light-emitting component of vehicle headlamp - Google Patents

Abstract

The utility model provides an LED light-emitting component of a vehicle headlamp. The LED light-emitting component of the vehicle headlamp is characterized by comprising a linear LED light source and a secondary optical lens, the secondary optical lens is an integrally formed arc-block-shaped part, and the linear LED light source is arranged below the arc-block-shaped part.

Description

A kind of LED light-emitting component of automobile head light

Technical field

The utility model relates to illumination optical technology, more specifically, relates to a kind of LED light-emitting component of automobile head light.

Background technology

Car light comprises headlight, night-driving lighting lamp, fog lamp, brake lamp, taillight, back-up lamp etc. from application point, and wherein most important for garage's safety is exactly headlight, and headlight refers to the headlamp that is combined in automotive front, and it mainly plays illumination and signal function.The light that headlamp sends can illuminate the road conditions in car body front, make driver can be in night the driving of safety, combination head lamp can be divided into Halogen lamp LED and xenon lamp according to light source at present.

Halogen lamp LED is exactly the special incandescent lamp of a class in fact, its principle be exactly on resistance, have electric current by time can generate heat, in the time that temperature is enough high, send the black body radiation of wavelength at visible light frequency band.Halogen lamp LED is in bulb, to be filled with iodine, and in the time that bulb is lighted, iodine evaporates into gas, and iodine vapor runs into colder tungsten, reacts with it, generates lower boiling tungsten iodide, makes the tungsten volatilization of bulb shell precipitation.So, for example, with the very large incandescent lamp of iodine-tungsten lamp manufacture power, 1000 watts.At present, Halogen lamp LED has been widely used in automotive lighting field.

Xenon lamp (High intensity Discharge, HID) refers to high-voltage gas discharging light, also referred to as heavy metal lamp or xenon lamp.Its principle is in UV-cut uvioresistant crystal quartz glass tube, with number of chemical gas filling, wherein major part is the inert gases such as xenon (Xenon) and iodide, and then see through booster (Ballast) DC voltage moment of 12 volts on car is pressurized to the electric current of 23000 volts, excite the xenon electronics in quartz ampoule free through high pressure amplitude of vibration, between two electrodes, produce light source.

At present, LED light fixture starts to be applied to automotive lighting, but due to its quality problems and lot size problem, make to hold at high price, although LED light source plurality of advantages can meet people to automotive safety, comfortable, luxurious, energy-saving and environmental protection and many-sided requirement such as multi-functional, the inhomogeneous problem of quality and illumination profile becomes the obstacle of car light development.

In addition, automobile lamp is very high to LED component parameters performance requirement, mainly comprises: one, efficient, high-power and high reliability (40 DEG C～125 DEG C); Two, electricity, optical parametric stability, uniformity want high, are less than 0.1V as the threshold voltage inconsistency of a collection of element, and monochromaticjty is good, and aberration is less than 5 nanometers; Three, LED element is lighted after test through 2000 hours (working under direct current) at 136V, and its luminous intensity decay is less than 20%.But all there is for automobile lighting the problem that is difficult to the specification that meets automobile industry in current LED element more or less.

The primary study direction of LED automobile lamp is White LED headlight at present, and LED car light and AFS(adaptivity car lamp control system) combination, wherein the LED element of efficient, high-power and high reliability, car light and special heat dissipation technology and optical design are crucial, and current product and technology all can not reach the requirement of practicality.

Utility model content

For overcoming the above-mentioned defect of prior art, the utility model proposes a kind of LED light-emitting component of automobile head light.

According to an aspect of the present utility model, a kind of LED light-emitting component of automobile head light has been proposed, it is characterized in that, comprise Linear LED light source and secondary optical lens, the arc piece shape part that this secondary optical lens is formed in one; Linear LED light source is arranged in the below of arc piece shape part.

The baseplane of arc piece shape part inwardly arranges channel-shaped portion, and Linear LED light source is arranged in this channel-shaped portion.

Linear LED light source is the linear pattern wafer array structure that Linear LED light source wafer forms.

The width w scope of LED linear pattern wafer row is at 0.2mm-2mm, and the length L of LED wafer row is between 5mm-50mm.

In linear pattern wafer row adjacent two center wafer spacing p divided by the ratio of the width s of wafer between 0.05-2.

Linear LED light source is engaged on substrate; Substrate comprises thermal insulation layer, circuit layer and two light emitting control walls; Thermal insulation layer is positioned at bottom, and circuit layer is covered on thermal insulation layer, and the wafer of light source is listed as with heat-conducting cream or eutectic mode and is engaged in circuit layer, and two light emitting control walls are positioned at the both sides of wafer row, have interval.

The wafer of Linear LED light source arrange comprise single-row linear pattern, multiple row linear pattern, arc line type and irregular pattern one or more arrange.

The linear pattern wafer array structure of Linear LED light source is that single linear pattern is arranged on the substrate of bottom surface.

Wafer and circuit are directly by covering that brilliant eutectic forms or by wire connecting wafer and circuit layer; Fluorescent bisque is coated wafer top, and the luminous width w being listed as by the Position Control wafer of light emitting control wall.

The wave-length coverage of LED wafer is from 380nm to 480nm.

Secondary optical lens comprises a plurality of reflective surface will, a plane of refraction and a bottom surface, and this plane of refraction is divided into a plurality of small exiting surfaces, and each small exiting surface has different curvature and different normals.

This optical reflection device comprises integrated arc piece part, and this arc piece part comprises fore-end and rear end part; Or this optical reflection device comprises the integrated arc piece shape part that is positioned at the box-shaped part of front end and is positioned at rear end; Wherein, a plurality of reflectings surface comprise the first reflecting surface of the second reflecting surface of corresponding fore-end end face and the cambered surface end face of corresponding arc piece part, and this tip-cambered face portion extends to this bottom surface; The reflecting surface that the first reflecting surface comprises multiple different curvature.

Described plane of refraction has the similar and different plane of refraction of multiple curvature, for the approximate directional light of the first reflecting surface and the reflection of the second reflecting surface is projeced into and is shone direction with different proportion; Described bottom surface has refraction or the reflecting surface of different curvature, penetrates the quantity of plane of refraction for reducing specific light.

Described the first reflecting surface is made up of at least more than one geometric surface, and this geometric surface is linked and formed by one or more of parabola, ellipsoid, sphere, aspheric surface and polynomial surface; Wherein, described the second reflecting surface is plane or geometric curved surfaces.

Light-emitting component of the present utility model can significantly reduce the power that vapour automobile lighting uses, and more than the average life span of car light can being increased to several times.In the time that the luminous width of LED light source is controlled in certain scope, it is required that this light source can be used for vehicle front lighting lamp optical, can meet the required luminous intensity of car headlamp by changing its length of illumination simultaneously, thereby headlight module luminous efficiency can be promoted to more than 60%.

Brief description of the drawings

Fig. 1 is according to the overall schematic of the light-emitting component of headlamp design one of the present utility model;

Fig. 2 is for to design a side schematic view according to light-emitting component of the present utility model;

Fig. 3 designs a perspective internal view according to light-emitting component of the present utility model;

Fig. 4 is the layout drawing of Linear LED light source wafer;

Fig. 5 is the sectional drawing that Linear LED light source is arranged;

Fig. 6 is Linear LED light source electrode and light-emitting area layout drawing;

Fig. 7 is according to the miter angle schematic diagram of light-emitting component design two of the present utility model;

Fig. 8 is the miter angle schematic diagram that adds front leaded light device according to light-emitting component design two of the present utility model;

Fig. 9 is the side schematic view that adds front leaded light device according to light-emitting component design two of the present utility model

Figure 10 is the side schematic view that adds front leaded light device according to light-emitting component design three of the present utility model.

As shown in the figure, in order clearly to realize structure or the method for embodiment of the present utility model, mark in the drawings specific label symbol, but this is only for signal needs, be not intended to the utility model to be limited in this particular device and environment, according to specific needs, those of ordinary skill in the art can adjust these elements, label, environment, revise, and the adjustment of carrying out and amendment are still included in the scope of accompanying claim.

Detailed description of the invention

A kind of optical reflection element and the LED light-emitting component that the utility model are provided below in conjunction with the drawings and specific embodiments are described in detail.

In the following description, will multiple different aspects of the present utility model be described, but, for those skilled in the art, can only utilize some or all structure of the present utility model to implement the utility model.For the definition of explaining, set forth specific number, configuration and order, but clearly, in the situation that there is no these specific detail, also can implement the utility model.In other cases, in order not obscure the utility model, will no longer be described in detail for some well-known features.

Embodiment 1

In the present embodiment, in order to guide the light of launching from light source, particularly in order to guide the light of launching from Linear LED light source in car headlamp, the present embodiment provides a kind of optical reflection device, and this optical reflection device comprises a plurality of reflective surface will, a plane of refraction and a bottom surface.This plane of refraction is divided into a plurality of small exiting surfaces, and each small exiting surface has different curvature and different normals.Wherein, this optical reflection device can be optical lens 7 as shown in Figure 1.

In an example, this optical reflection device comprises arc piece part, and wherein, this arc piece part is one-body molded.In one embodiment, a wherein part for this arc piece part can be box-shaped part, and this box-shaped part and arc piece shape part are one-body molded.

Wherein, this optical reflection device 7 comprises as end face, plane of refraction, bottom surface and two sides.The reflective surface will corresponding to end face of this optical reflection device, comprises planar section and cambered surface part, and this planar section connects cambered surface part, and this cambered surface part extends to bottom surface.

Particularly, with reference to figure 2, optical reflection device comprises that the first reflecting surface 2, the second reflecting surface 3, plane of refraction 4 and bottom surface 5, the first reflectings surface 2 form cambered surface part recited above together with the second reflecting surface 3.The light of light source, through the reflection of the first reflecting surface 2 and/or the second reflecting surface 3, further, after plane of refraction 4 correctings, becomes approximate directional light to be projeced into and is shone direction, and represent specific luminous intensity distribution distribution in direction of illumination specified distance.

Baseplane in arc piece shape part inwardly arranges channel-shaped portion, and light source is placed in to this channel-shaped portion below, and the outside that is formed on lens with aligning machine is installed fixing.In the arc piece part of optical reflection device 7, light source upwards just right part the groove of part semicircle, part plane is set, the light of, directive optical reflection device 7 that light source sends for guiding.

The some or all of end face of optical reflection device 7 is arranged electrodeposited coating.In one embodiment, electrodeposited coating covers 1/4 cambered surface and whole planar section of the end face of optical reflection device 7.Particularly, electrodeposited coating is arranged in the skin of optical reflection device 7.In addition, the some or all of sole arrangement electrodeposited coating of optical reflection device 7.

Wherein, the first reflecting surface 2 and second reflecting surface 3 of optical reflection device 7 can change into approximate directional light by the light of more than 50% light source, are parallel to bottom surface 5 and penetrate through plane of refraction 4.

Wherein, lens reflection face 4 can be designed as the similar and different plane of refraction of multiple curvature, is projeced into by according to direction with different proportion for approximate directional light that the first reflecting surface 2 and the second reflecting surface 3 are reflected, distributes to produce specific luminous intensity distribution.

Wherein, lens bottom surface 5 can be designed as refraction or the reflecting surface of different curvature, penetrates the quantity of plane of refraction 4 for reducing specific light, distributes to strengthen luminous intensity distribution.

Wherein, the light that light source penetrates penetrates after groove 6, and part light penetrates towards the direction of plane of refraction 4 after reflecting via the first reflecting surface 2.This first reflecting surface 2 is made up of one or more geometric surface, this geometric surface can be linked and be formed by one or more of parabola, ellipsoid, sphere, aspheric surface and polynomial surface, its objective is that reflection part light makes light advance towards the direction of plane of refraction.

In addition, the light that light source penetrates penetrates via groove 6, part light via the second reflecting surface 3 reflection after, by the light collection that is emitted to side to zone line.This second reflecting surface can be plane or geometric curved surfaces.

Wherein, can drop on the 3rd reflecting surface 5 via the part light after the first reflecting surface or the reflection of the second reflecting surface, on bottom surface.Can on the 3rd reflecting surface, micro-structural be set, the light dropping on the 3rd reflecting surface can be advanced towards plane of refraction.The reflecting effect of this micro-structural tool height, makes light be able to be directed to plane of refraction after reflection, to improve the utilization rate of light.

Wherein, all light via reflecting surface reflection is advanced towards the direction of plane of refraction, during via plane of refraction, by the design of a plurality of small planes of refraction, can allow light advance and there is the function of leaded light towards specific direction, make Energy distribution meet the laws and regulations requirement of car headlamp.

Wherein, exit facet can connect certain ad-hoc location of the guiding device of particular design or the latter half of exit facet can arrange light shield layer, to add presenting of high light type.

In a further embodiment, for the global design shape of light-emitting component, as shown in Fig. 7-Fig. 9, Fig. 7 is according to the miter angle schematic diagram of light-emitting component design two of the present utility model; Fig. 8 is the miter angle schematic diagram that adds front leaded light device according to light-emitting component design two of the present utility model; Fig. 9 is the side schematic view that adds front leaded light device according to light-emitting component design two of the present utility model.In this figure, this optical reflection device comprises arc piece part as a whole, and wherein, this arc piece part is one-body molded.Front leaded light device is arranged in this arc piece rear end.The light that lens reflection face 4 penetrates can increase lens module entirety light extraction efficiency and can increase the luminous intensity of light type keypoint part after reflecting surface 10 correctings of lightguide 9, the energy that can again modify light type after coordinating suitable light type finishing face 11 to design divides Fabric, and strengthens dead line effect.

Figure 10 is the side schematic view that adds front leaded light device according to light-emitting component design three of the present utility model.Wherein this optical reflection device comprises arc piece part as a whole, and this arc piece part is irregular arc body.

Embodiment 2

In the present embodiment, provide a kind of LED light-emitting component, Fig. 1 illustrates the overall schematic of this LED light-emitting component.As shown in Figure 1, this LED light-emitting component comprises a Linear LED light source 1 and a secondary optical lens 7, and this optical lens 7 comprises box-shaped part and arc piece shape part, and box-shaped part and arc piece shape part are one-body molded.Wherein, Linear LED light source 1 is arranged in the below of arc piece shape part.

Fig. 3 is the perspective internal view according to light-emitting component of the present utility model, as shown in Figure 3, arranges semi-circular recesses 6, the light sending for guiding Linear LED light source 1 in inside, Linear LED light source 1 upper end of secondary optical lens 7.Linear LED light source 1 is parallel to lens light direct of travel to be arranged, its width need be less than 2 millimeters, and LED light source length direction is perpendicular to lens light direct of travel, and length requires to select according to the length of lens and luminous intensity.

Particularly, Fig. 4 is the layout drawing of Linear LED light source wafer, and wherein, LED wafer row can be engaged on substrate with traditional routing or to cover brilliant eutectic mode, form circuit luminous.The width w scope of LED wafer row is at 0.2mm-2mm, and two center wafer spacing p should be between 0.05-2 divided by the ratio of the width s of wafer.The length L of LED wafer row should be between 5mm-50mm, is appreciated that for the length L of LED wafer row, according to the needs of the development of technology and application, this length further can be dwindled.

Wherein, Linear LED light source chip is linear planar structure, and single linear pattern is arranged on the substrate of bottom surface.According to the enlightenment of the present embodiment, one of ordinary skill in the art will appreciate that, arranging of this light source chip can be not limited to linear pattern, can be also multiple row, or arc line shaped, or irregular pattern is arranged.Certainly, wherein need to consider, for the layout of different light source chips, correspondingly need to adjust interior shape and the layout structure of reflecting surface and plane of refraction.

Fig. 5 is the sectional drawing that Linear LED light source is arranged, wherein, LED wafer row can traditional routings or are engaged in to cover brilliant eutectic mode that on substrate, to form circuit luminous.Wherein, substrate comprises thermal insulation layer, circuit layer and two light emitting control walls.

Wherein, thermal insulation layer is positioned at bottom, and circuit layer is covered on thermal insulation layer, and wafer is engaged in circuit layer with heat-conducting cream or eutectic mode, and two light emitting control walls are positioned at the both sides of wafer, have interval.Circuit layer in the bottom of the compartment of a side is removed.The formation of wafer and circuit can directly by covering, brilliant eutectic forms or by wire connecting wafer and circuit layer, fluorescent bisque is coated wafer top, and by its luminous width w of light emitting control wall control.

Wherein, Linear LED light source uses the row of single a row or multi-row LED wafer composition, the white light that collocation phosphor powder sends, the wave-length coverage of LED wafer can be from 380nm to 480nm, and the single wavelength part that LED wafer sends absorbs the white light that transfers again wide wavelength via phosphor powder.

Wherein, line style LED light source configures corresponding current source finishing circuit, can directly use distribution for automobile (11-18V) and electric current output is effectively controlled in to steady-state operation.This light-emitting component can be integrated in a bare engine module via exchanging structure on-line equipment in automotive headlamp assembly, as the main illumination source of automotive headlamp.

Further, the some or all of end face of optical lens 7 is arranged electrodeposited coating.In one embodiment, electrodeposited coating covers 1/4 cambered surface and whole planar section of the end face of optical lens 7.Particularly, electrodeposited coating is arranged in the skin of optical lens 7.In addition, the some or all of sole arrangement electrodeposited coating of optical lens 7.

Fig. 6 is Linear LED light source electrode and light-emitting area layout drawing, and as shown in the figure, based on the layout of above-mentioned LED light source, LED luminous zone concentrates on middle part, and distribution of electrodes is at edge.

Fig. 2 is the side schematic view according to light-emitting component of the present utility model, and as shown in Figure 2, the end face of this optical lens comprises planar section and cambered surface part, and this planar section connects cambered surface part, and this cambered surface part extends to bottom surface.

Particularly, optical lens 7 comprises that the first reflecting surface 2, the second reflecting surface 3, plane of refraction 4 and bottom surface 5, the first reflectings surface 2 form cambered surface part recited above together with the second reflecting surface 3.Lang Baite (Lambertian) luminous intensity distribution that Linear LED light source 1 sends is through the reflection of the first reflecting surface 2 and/or the second reflecting surface 3, further after plane of refraction 4 correctings, become approximate directional light to be projeced into and shone direction, and represent the specific luminous intensity distribution distribution in place in direction of illumination specified distance.When for headlamp, this luminous intensity distribution distribute meet standard GB/T 25991-2010 defined automotive headlamp in 25 meters of light distribution regulations.

Wherein, the first reflecting surface 2 of optical lens 7 and the second reflecting surface 3 can change into approximate directional light by the Lang Baite light of 50% above LED light source, are parallel to lens bottom surface 5 and penetrate through lens reflection face 4.

Wherein, lens reflection face 4 can be designed as the similar and different plane of refraction of multiple curvature, is projeced into by according to direction with different proportion for approximate directional light that the first reflecting surface 2 and the second reflecting surface 3 are reflected, distributes to produce specific luminous intensity distribution.Wherein, lens bottom surface 5 can be designed as refraction or the reflecting surface of different curvature, penetrates the quantity of plane of refraction 4 for reducing specific light, distributes to strengthen luminous intensity distribution.

Wherein, the light that the linear LED light source 1 of polycrystalline penetrates penetrates via semi-circular recesses 6, and to the inside of secondary optical lens 7, part light penetrates towards the direction of plane of refraction 4 after reflecting via the first reflecting surface 2.This first reflecting surface 2 is made up of at least more than one geometric surface, this geometric surface can be linked and be formed by one or more of parabola, ellipsoid, sphere, aspheric surface and polynomial surface, its objective is that reflection part light makes light advance towards the direction of plane of refraction.

In addition, the light that the linear LED light source 1 of polycrystalline penetrates penetrates via semi-circular recesses 6, to the inside of secondary optical lens 7, part light via the second reflecting surface 3 reflections after, by the light collection that is emitted to side to zone line.This second reflecting surface can be plane or geometric curved surfaces.

Wherein, can drop on the 3rd reflecting surface 5 via the part light after the first reflecting surface or the reflection of the second reflecting surface, on bottom surface.Can on the 3rd reflecting surface, micro-structural be set, the light dropping on the 3rd reflecting surface can be advanced towards plane of refraction.The reflecting effect of this micro-structural tool height, makes light be able to be directed to plane of refraction after reflection, to improve the utilization rate of light.

Wherein, all light via reflecting surface reflection is advanced towards the direction of plane of refraction, during via plane of refraction, by the design of a plurality of small planes of refraction, can allow light advance and there is the function of leaded light towards specific direction, make Energy distribution meet the laws and regulations requirement of car headlamp.

Wherein, the location arrangements light shield layer of the latter half of exit facet, makes the less position of the latter half of exit facet need the outgoing of shading light according to bright dipping, to meet the needs of light type.

Embodiment 3

In the present embodiment, provide a kind of light structures of automobile head light, wherein, this light structures comprises and comprises the pedestal of being prepared by Heat Conduction Material, configures the linear LED light-emitting component of this polycrystalline on this pedestal.Preferably, this pedestal is made up of the metal material such as aluminium, and in this way, pedestal can serve as the fin of the heat producing for LED light-emitting component.

This light structures arranges lens radiator structure in reflection from lens layer top, wherein can comprise lens heat radiation conducting shell and radiation and convection layer, and lens heat radiation conducting shell is outwards in conjunction with radiation and convection layer.

Wherein, optical lens and lens heat radiation conducting shell can be bonding by high temperature heat-conducting cream and high temperature colloid.Wherein, lens heat radiation conducting shell and radiation and convection layer also can be bonding by high temperature heat-conducting cream and high temperature colloid.

Wherein, lens heat radiation conducting shell outwards conducts to the heat energy of staying on secondary optical lens on many radiation and convections layer and radiating element, makes heat energy to be pulled away moment and can not to be accumulated on the light contact-making surface of reflecting layer and secondary optical lens.

Wherein, in the present embodiment, the linear LED light-emitting component of polycrystalline comprises a Linear LED light source 1 and a secondary optical lens 7, and this optical lens 7 comprises box-shaped part and arc piece shape part, and box-shaped part and arc piece shape part are one-body molded.Wherein, Linear LED light source 1 is arranged in the below of arc piece shape part.

Baseplane in arc piece shape part inwardly arranges channel-shaped portion, and by Linear LED light source 1, as for this channel-shaped portion below, this channel-shaped portion arranges light refraction face for the light concentrating LED light source and send and is directed to specific direction; These channel-shaped portion both sides also can increase effect of guiding LED light source by design reflectivity face.

As shown in Figure 3, semi-circular recesses 6, the light sending for guiding Linear LED light source 1 are arranged in Linear LED light source 1 upper end.Linear LED light source 1 is parallel to lens light direct of travel to be arranged, its width need be less than 2 millimeters, and LED light source length direction is perpendicular to lens light direct of travel, and length requires to select according to the length of lens and luminous intensity.

Particularly, with reference to figure 4, wherein, LED wafer row can traditional routings or are engaged in to cover brilliant eutectic mode that on substrate, to form circuit luminous, the width w scope of LED wafer row is at 0.2mm-2mm, two center wafer spacing p should be between 0.05-2 divided by the ratio of the width s of wafer, and the length L of LED wafer row should be between 5mm-50mm.For the length L of LED wafer row, according to the needs of the development of technology and application, this length further can be dwindled.

Wherein, Linear LED light source chip is linear planar structure, and single linear pattern is arranged on the substrate of bottom surface.According to the enlightenment of the present embodiment, one of ordinary skill in the art will appreciate that, arranging of this light source chip can be not limited to linear pattern, can be also multiple row, or arc line shaped, or irregular pattern is arranged; Certainly, wherein need to consider, for the layout of different light source chips, correspondingly need to adjust shape and the structure of reflecting surface and plane of refraction.

LED wafer row can traditional routings or are engaged in to cover brilliant eutectic mode that on substrate, to form circuit luminous.Wherein, substrate comprises thermal insulation layer, circuit layer and two light emitting control walls.Thermal insulation layer is positioned at bottom, and circuit layer is covered on thermal insulation layer, and wafer is engaged in circuit layer with heat-conducting cream or eutectic mode, and two light emitting control walls are positioned at the both sides of wafer, have interval.Circuit layer in the bottom of the compartment of a side is removed.The formation of wafer and circuit can directly by covering, brilliant eutectic forms or by wire connecting wafer and circuit layer, fluorescent bisque is coated wafer top, and by its luminous width w of light emitting control wall control.

Further, the some or all of end face of optical lens 7 is arranged electrodeposited coating.In one embodiment, electrodeposited coating covers 1/4 cambered surface and whole planar section of the end face of optical lens 7.Particularly, electrodeposited coating is arranged in the skin of optical lens 7.In addition, the some or all of sole arrangement electrodeposited coating of optical lens 7.

As shown in Figure 2, the end face of this optical lens comprises planar section and cambered surface part, and this planar section connects cambered surface part, and this cambered surface part extends to bottom surface.Particularly, optical lens 7 comprises that the first reflecting surface 2, the second reflecting surface 3, plane of refraction 4 and bottom surface 5, the first reflectings surface 2 form cambered surface part recited above together with the second reflecting surface 3.Lang Baite (Lambertian) luminous intensity distribution that Linear LED light source 1 sends is through the reflection of the first reflecting surface 2 and/or the second reflecting surface 3, further after plane of refraction 4 correctings, become approximate directional light to be projeced into and shone direction, and represent the specific luminous intensity distribution distribution in place in direction of illumination specified distance.When for headlamp, this luminous intensity distribution distribute meet standard GB/T 25991-2010 defined automotive headlamp in 25 meters of light distribution regulations.

In this embodiment, the linear LED light-emitting component of polycrystalline is the LED light-emitting component in embodiment 2 roughly the same, and the detail of the linear LED light-emitting component of polycrystalline will repeat no more.

Embodiment 4

In another embodiment of the present utility model, a kind of radiator structure of LED optical element is provided, wherein, this radiator structure comprises optical lens, lens heat radiation conducting shell, radiation and convection layer and radiating element.Wherein, the outer lens heat radiation conducting shell of arranging of this optical lens, lens heat radiation conducting shell is outwards in conjunction with radiation and convection layer, and lens heat radiation conducting shell is engaged in heat dissipation element.

Wherein, optical lens and lens heat radiation conducting shell can be bonding by high temperature heat-conducting cream and high temperature colloid.Wherein, lens heat radiation conducting shell and radiation and convection layer also can be bonding by high temperature heat-conducting cream and high temperature colloid.

Wherein, lens heat radiation conducting shell outwards conducts to the heat energy of staying on secondary optical lens on radiation and convection layer and radiating element, makes heat energy to be pulled away moment and can not to be accumulated on the light contact-making surface of reflecting layer and secondary optical lens.

When heat energy is passed to radiation and convection layer via lens heat radiation conducting shell, its radiation and convection layer is because surperficial special construction can go out hot type by thermal convection current and thermal-radiating effect.On the other hand, heat energy also can be passed on radiating element by scioptics heat radiation conducting shell, conducts the heat dissipation element that heat energy is directed to rear by heat.

So; the combination of lens heat radiation conducting shell and radiation and convection layer; and be arranged on the surface of secondary optical lens and radiating element; can utilize hot conduction, thermal convection current and thermal-radiating radiating mode that hot type is gone out; reduce heat history, protection high reflection conducting shell and lens and can not destroy because of thermal stress material structure, there is the function increasing the service life, reflection ray that simultaneously again can be suitable; make light via the optical characteristics that secondary optical lens produced, reach the effect in design.

Wherein, the material of lens heat radiation conducting shell is to be good such as fine copper, red metal, fine aluminium, the contour heat-conducting of alloy aluminum, but not to limit for this reason.Thickness is between 500um-4000um.

Wherein, the material of radiation and convection layer is ceramic as good taking aluminium oxide, aluminium nitride etc., but not to limit for this reason.Thickness is good between 20um-500um.

Finally it should be noted that, above embodiment is only in order to describe the technical solution of the utility model instead of this technical method is limited, the utility model can extend to other amendment, variation, application and embodiment in application, and therefore thinks that all such amendments, variation, application, embodiment are in spirit of the present utility model and teachings.

Claims (14)

1. a LED light-emitting component for automobile head light, is characterized in that, comprises Linear LED light source and secondary optical lens, the arc piece shape part that this secondary optical lens is formed in one; Linear LED light source is arranged in the below of arc piece shape part.

2. LED light-emitting component according to claim 1, is characterized in that, the baseplane of arc piece shape part inwardly arranges channel-shaped portion, and Linear LED light source is arranged in this channel-shaped portion.

3. LED light-emitting component according to claim 1, is characterized in that, Linear LED light source is the linear pattern wafer array structure that Linear LED light source wafer forms.

4. LED light-emitting component according to claim 3, is characterized in that, the width w scope of LED linear pattern wafer row is at 0.2mm-2mm, and the length L of LED wafer row is between 5mm-50mm.

5. LED light-emitting component according to claim 3, is characterized in that, in linear pattern wafer row adjacent two center wafer spacing p divided by the ratio of the width s of wafer between 0.05-2.

6. LED light-emitting component according to claim 3, is characterized in that, Linear LED light source is engaged on substrate; Substrate comprises thermal insulation layer, circuit layer and two light emitting control walls; Thermal insulation layer is positioned at bottom, and circuit layer is covered on thermal insulation layer, and the wafer of light source is listed as with heat-conducting cream or eutectic mode and is engaged in circuit layer, and two light emitting control walls are positioned at the both sides of wafer row, have interval.

7. LED light-emitting component according to claim 1, is characterized in that, the wafer of Linear LED light source arrange comprise single-row linear pattern, multiple row linear pattern, arc line type and irregular pattern one or more arrange.

8. LED light-emitting component according to claim 3, is characterized in that, the linear pattern wafer array structure of Linear LED light source is that single linear pattern is arranged on the substrate of bottom surface.

9. LED light-emitting component according to claim 6, is characterized in that, wafer and circuit are directly by covering that brilliant eutectic forms or by wire connecting wafer and circuit layer; Fluorescent bisque is coated wafer top, and the luminous width w being listed as by the Position Control wafer of light emitting control wall.

10. LED light-emitting component according to claim 9, is characterized in that, the wave-length coverage of LED wafer is from 380nm to 480nm.

11. LED light-emitting components according to claim 1, it is characterized in that, secondary optical lens comprises a plurality of reflective surface will, a plane of refraction and a bottom surface, and this plane of refraction is divided into a plurality of small exiting surfaces, and each small exiting surface has different curvature and different normals.

12. LED light-emitting components according to claim 11, is characterized in that, this optical reflection device comprises integrated arc piece part, and this arc piece part comprises fore-end and rear end part; Or this optical reflection device comprises the integrated arc piece shape part that is positioned at the box-shaped part of front end and is positioned at rear end; Wherein, a plurality of reflectings surface comprise the first reflecting surface of the second reflecting surface of corresponding fore-end end face and the cambered surface end face of corresponding arc piece part, and this tip-cambered face portion extends to this bottom surface; The reflecting surface that the first reflecting surface comprises multiple different curvature.

13. LED light-emitting components according to claim 11, is characterized in that, described plane of refraction has the similar and different plane of refraction of multiple curvature, for the approximate directional light of the first reflecting surface and the reflection of the second reflecting surface is projeced into and is shone direction with different proportion; Described bottom surface has refraction or the reflecting surface of different curvature, penetrates the quantity of plane of refraction for reducing specific light.

14. LED light-emitting components according to claim 12, it is characterized in that, described the first reflecting surface is made up of at least more than one geometric surface, and this geometric surface is linked and formed by one or more of parabola, ellipsoid, sphere, aspheric surface and polynomial surface; Wherein, described the second reflecting surface is plane or geometric curved surfaces.

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