CN101240885A - LED small angle long distance optical lens and array - Google Patents

LED small angle long distance optical lens and array Download PDF

Info

Publication number
CN101240885A
CN101240885A CNA2007100099676A CN200710009967A CN101240885A CN 101240885 A CN101240885 A CN 101240885A CN A2007100099676 A CNA2007100099676 A CN A2007100099676A CN 200710009967 A CN200710009967 A CN 200710009967A CN 101240885 A CN101240885 A CN 101240885A
Authority
CN
China
Prior art keywords
optical lens
angle
lens
light
reflector
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
CNA2007100099676A
Other languages
Chinese (zh)
Other versions
CN100538160C (en
Inventor
王敏
林瑞梅
李锦泉
李嘉穗
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Individual filed Critical Individual
Priority to CNB2007100099676A priority Critical patent/CN100538160C/en
Publication of CN101240885A publication Critical patent/CN101240885A/en
Application granted granted Critical
Publication of CN100538160C publication Critical patent/CN100538160C/en
Expired - Fee Related legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Landscapes

  • Lenses (AREA)
  • Led Device Packages (AREA)

Abstract

LED minor angle distant range sending len set and array, relates to optical len, each sending len set is equipped with a lighting chip, each sending len set includes a reflecting bowl and a receiving len; the reflecting bowl is composed of conical section revolution surface having upper-lower openings. The inner reflecting surface is plated with wholly reflecting film, a LED lighting chip is mounted on the focus of the conical section revolution surface; the emitting large-angle optical line is reflected convergence. The photoelectric lens is composed of ring conical section revolution surface, uuper and lower glaring curved surface. The outlet of the reflecting bowl is inosculated to the inlet of the photoelectric lens; the convexity of the center ring belt of the upper-lower curved surfaces of the photoelectric lens forms convex lens which focus is near the focus of the conical section; the smaller angle emitted by LED is shrunk convergence, light from intermediate zone is syntaxised via reflection of the lens. The array is composed of multiple sending lens in arrangement. The advantages of the invention is large angle scattered light emitted by LED chip via secondary light distribution of the reflecting bowl and lens effective gathers energy, shrinks light angle maximum.

Description

LED small angle long distance light microscopic group and array
Technical field: the present invention relates to optical lens, be specially adapted to LED low-angle light-emitting lens.
Prior art: led light source is efficient with it, energy-saving and environmental protection, long-life, undersized advantage have been widely used in imaging lighting fields such as background light source, display device, duplicator, laser printer, above-mentioned application is confined to closely face battle array illumination usually, the simple grain combination shows purposes, this is because the decision of the LED scattering characteristics of luminescence, its initial angle of divergence can be near 180 °, this is favourable for large area lighting closely, but illumination distances is limited.Therefore, LED producer has carried out simple luminous intensity distribution usually when encapsulation, shrink the angle of divergence.For example adopt the lens pillar encapsulation, can a certain amount of contraction angle of divergence, can see 60 °, 30 °, the 15 ° half-power angles of divergence on the market, but its light utilization efficiency is low, collector lens directly contacts with the luminescence chip encapsulation, and the operating temperature height is very easily aging, crack, the light transmission of lens is descended greatly.The diffuse reflection in packaging body of a large amount of light produces more thermal energy and causes the further ageing failure of package lens.Some high power light sources are arranged with the combination lighting of above-mentioned LED array, but volume is big, the angle of divergence is bigger than normal, is not easy to high-power long distance light.
Consult the led light source Chinese patent, mainly concentrate on LED encapsulation and in illuminator closely, the most close patent has two.Application number 200380105936.0 " lens array plate and manufacture method thereof ", goal of the invention are effectively diffused light to be gathered a light to utilize the surface (as the imaging surface LCD panel of duplicator or laser printer etc., to belong to closely uniform illumination system.Application number 200710118965.0, " a kind of led light source lens that are used for ", the purpose of invention is to make light that led light source sends form the optical illumination scope of rectangle, square or a strip in the far field behind lens, and the strip on road surface evenly throws light on when conveniently being used for the road illumination.Be used for the LED street lighting and belong to the middle distance illuminator.The light beam of its outgoing differs greatly at X and two perpendicular orientation angles of divergence of Y, can't be to long distance light.And owing to will cut out the illumination field of view of rectangle, by or cut part light, caused the loss of light energy.
Safety defense monitoring system such as safe city engineering has tended to day and night round-the-clock monitoring in recent years, and to outdoor monitoring at night, universal demand adopts infrared illumination, to reduce light pollution.LED infrared light supply manufacturing technology and technology are ripe, and near-infrared LED makes it become infrared light supply preferably with low power consuming, long-life characteristics.Under the in-plant illuminator no matter be visible light or infrared light generally adopts LED to make light source.Remote infrared illumination system, what generally adopt at present is single the infrared LED binding array that encapsulates through simple optically focused, forms high-power LED array to long distance light with the large tracts of land binding.But, restricting its further development and application because its volume is big and the previous reasons life-span is short, illuminator maintenance cost height.Have constantly that the safety monitoring user proposes to need that a kind of volume is little, the life-span is long, the length of the high and low energy consumption of luminous efficiency is apart from infrared illumination system, our remote low-angle light-emitting lens group proposes under such Market and Technology background and researches and develops.
Summary of the invention: the objective of the invention is efficiently to collect light energy for after making the secondary light-distribution of large-angle scattered light through reflector and lens that led chip sends, convergent beam realizes that low-angle is to long distance light.A kind of small angle long distance light microscopic group and array are provided.
Light-emitting lens prescription case of the present invention is:
Luminescence chip of each light-emitting lens assembly, each light-emitting lens group comprise reflector and receive optical lens;
Reflector is made up of the interior surface of revolution of upper and lower opening.Surface of revolution is formed around its symmetry axis revolution by conic section; Interior reflective surface plating total reflection film, the bottom of reflector are that its center of circle of level overlaps with the focus of conic section, and the LED luminescence chip is installed in the focal position;
Described receipts optical lens is made up of the ring conic section surface of revolution in week, last bright dipping curved surface and following incident curved surfaces.The revolution curve of receiving optical lens can be different sections or a different conic section with same conic section of reflector, but the outlet of reflector has corresponding identical cooperation position to concern with the inlet of receiving optical lens; Receive the following incident curved surfaces of optical lens and be made up of two parts, the center endless belt is the convex surface with revolution symmetry, and outer endless belt is the concave surface with revolution symmetry; Last exiting surface also is made up of two parts, the center endless belt is the symmetrical convex surface of revolution, outer endless belt is bigger and convex surface or a concave surface of relative center endless belt radius of curvature, and this outer endless belt curvature meets the following conditions: make to arrive behind this endless belt light low-angle deviation to equal the extreme angles θ less than design cOutgoing; The center of surface endless belt constitutes the focus of its focus of convex lens at conic section about receiving optical lens; This receipts optical lens meets the following conditions: the center smaller angle light beam that the corresponding formation of center of surface endless belt convex lens send led chip about the receipts optical lens shrinks and converges, with the very little angle of departure outgoing near 0 °; The transition region that led chip sends enters the concave surface of the outer collar region of the following incidence surface of receiving optical lens than the wide-angle light beam, outwards behind the deviation receiving the surface of revolution of optical lens conic section greater than the incidence angle directive of the cirtical angle of total reflection, and within it wall and produce total reflection after through behind the outer collar region deviation of receipts bright dipping curved surface on the optical lens with extreme angles θ smaller or equal to design cOutgoing.
The height of reflector is complementary with receipts optical lens height and gets final product, and the total height after the combination is associated with the design rising angle with the ratio L/D of bright dipping bore; Total height after the combination meets the following conditions: rising angle is more little, and L/D is just big more, and the lens packet size is big more; The outer ring district wide-angle light beam that led chip sends enters the concave surface that enters the outer collar region of the following incidence surface of receiving optical lens after the revolution reflecting surface reflection of reflector, the outside a little deviation of quilt enters the inside deviation of outer collar region of exiting surface, at last with the extreme angles θ smaller or equal to design cOutgoing.
The scheme of array of the present invention is to be combined by a plurality of light-emitting lens group patterns, and arrangement pitches meets the following conditions: the light of each group does not disturb and enters another group and suitably be advisable in the gap.
After the invention has the advantages that the secondary light-distribution of large-angle scattered light that led chip sends, efficiently collect light energy, and shrink luminous angle to greatest extent, make its lighting angle reach design angle θ through reflector and lens c(embodiment of the invention design angle θ c≤ 10 °), realize that remote low-angle light transmits.Secondary light-distribution optics packet size is little, and is easy for installation.LED behind the array luminous intensity distribution forms high brightness, face battle array illumination uniformly in the far field, be particularly suitable for the high brightness uniform illumination system of medium and long distance.
Description of drawings:
Fig. 1 is the light-emitting lens group structural representation of the embodiment of the invention 1
Fig. 2 is the embodiment of the invention 2 light-emitting lens groups 3 * 3 array structure schematic diagrames
Fig. 3 is the cutaway view of Fig. 2
The specific embodiment:
Each light-emitting lens group comprises reflector 7 and receives optical lens 9.Luminescence chip 3 of each light-emitting lens assembly.Luminescence chip 3 is contained on the luminescence chip substrate 4, and luminescence chip substrate 4 cooperates as shown in Figure 1 with 5 location, reflector baseplane.
Reflector 7 is made up of as shown in Figure 1 the interior surface of revolution of upper and lower opening.(example 1 of the present invention is a parabola to the surface of revolution 6 of reflector 7, also can be ellipse and hyperbola by conic section.) one section form around the revolution of its symmetry axis.The baseplane 5 of reflector 7 is that its center of circle of level overlaps with the focus of conic section, LED luminescence chip 3 is installed in the focal position, after the wide-angle light that the led chip 3 in the focal position is sent arrives surface of revolution 6 internal reflections to become very little angle outgoing with optical axis.Interior reflective surface surface of revolution 6 plating total reflection films of reflector 7.
Described receipts optical lens 9 is made up of as shown in Figure 1 the ring conic section surface of revolution 8 in week, last bright dipping curved surface and following incident curved surfaces.The revolution curve of receiving optical lens 9 can be different sections or a different conic section with 7 same conic sections of reflector, but the outlet of reflector 7 has corresponding identical position to concern with the inlet of receiving optical lens 9.Receive the following incident curved surfaces of optical lens 9 and be made up of two parts, center endless belt 2 is the convex surfaces with revolution symmetry, and outer endless belt 1 is the concave surface with revolution symmetry.Last exiting surface also is made up of two parts, and center ring 11 bands are the symmetrical convex surfaces of revolution, and outer endless belt 10 is bigger convex surface or the concave surfaces of relative center endless belt 11 radius of curvature.
The described receipts optical lens low-angle light beam that the corresponding formation of center of surface endless belt convex lens send led chip 3 about in the of 9 shrinks and converges, with the very little angle of divergence outgoing near 0 °; The light that led chip 3 sends than wide-angle enters outer endless belt 1 deviation of the incident curved surfaces of receiving optical lens 9, with greater than cirtical angle of total reflection θ IcThe incidence angle of=arcsin (1/n) arrives the ring surface of revolution 8 in week, and produces total reflection, passes through behind outer endless belt 10 deviations of exiting surface with smaller or equal to design limit angle θ again cOutgoing; Wide-angle light that led chip 3 sends arrive enter the following incident curved surfaces of receiving optical lens 9 after surface of revolution 6 internal reflections of reflector 7 outer endless belt 1 a little outwards deviation arrive again behind the inside a little deviation of outer endless belt 10 of the last bright dipping curved surface of receiving optical lens 9 with smaller or equal to design limit angle θ cOutgoing.Realized that thus efficient collection of led chip 3 scattered lights converge the purpose that the back is sent with low-angle.The light energy effective rate of utilization is greater than 90%.
The revolution curve of described receipts optical lens 9 is a parabolical part in embodiment 1, also can be elliptic curve, a hyp part.Reflector 7 interior reflective surface also can be the surface of revolution---the conical surfaces that the straight line at certain inclination angle is arranged with central shaft except above-mentioned conic section, and receiving optical lens 9 materials is materials of printing opacity, and refractive index is between 1.3-3.5.
The height of reflector 7 highly is complementary with receipts optical lens 9 and gets final product, and the total height L after the combination is associated with the design rising angle with the ratio L/D of bright dipping bore D.Rising angle is more little, and L/D is just big more, and the lens packet size is big more.L/D can be at 0-∞.Therefore, method of the present invention in theory can design the very low-angle light-emitting lens group near 0 degree.But take all factors into consideration the balance of sending optic angle degree and mirror packet size, embodiment of the invention design angle is 10 °.
Described light-emitting lens group pattern embodiment has two, and mode one several light-emitting lens groups are that cell array combines, and arrangement pitches meets the following conditions: the light of each group does not disturb and enters another group and suitably be advisable in the gap.Mode two is that the reflector array group is synthesized reflector plate 14 with the synthetic luminescence chip plate 13 of luminescence chip array group, receives the synthetic optical lens plate 15 of receiving of optical lens array group.They have identical spacing and array mode, and arrangement pitches satisfies condition: the light of each group does not disturb and enters another group and suitably be advisable at interval.Array LED chip board 13, reflector plate 14 and receive optical lens plate 15 and install as Fig. 2 with the cooperation position of determining.Each reflector is to corresponding receipts optical lens in the receivable optical lens plate 15 in the reflector plate 14.Led chip of the corresponding configuration in the center, baseplane of each reflector, the receipts optical lens that the light that makes each led chip send enters corresponding reflector and cooperates with it, and make each several part light meet aforesaid mode, through the θ of light-emitting lens group pattern with design cLow-angle is sent.
Structure, material and the operation principle of each luminescence chip in the described luminescence chip plate 13 is with aforesaid identical.
Structure, material and the operation principle of each reflector in the described reflector plate 14 is with aforesaid identical.
In the described receipts optical lens plate 15 each is received structure, material and the operation principle of optical lens with aforesaid identical.
Low-angle that the present invention announces send optical lens group embodiment 1 as shown in Figure 1
The present invention is further illustrated by embodiment below in conjunction with accompanying drawing.
The structure of reflector 7 as shown in Figure 1, its medial surface 6 is by parabola y 2Surface of revolution and plating total reflection film that=2px rotates around symmetry axis.The baseplane 5 of reflector 7 be the level circle wherein the heart overlap with the focus of conic section, upper shed plane 12 is a light-emitting window, 5 vertical range is the height h of reflector to the baseplane on last plane 12, the diameter d of reflector 7 light-emitting windows, the diameter of the light-emitting window of reflector 7 and the d/h=0.2-4 of height.The catercorner length of led chip 3 is less than the diameter on reflector 7 open bottom planes 5.
Embodiments of the invention 1 are received optical lens 7 as shown in Figure 1, the printing opacity entity of being made up of lower surface camber on parabola surface of revolution 8 and the center symmetry.The revolution parabola of receiving optical lens 9 and the revolution parabola of reflector 7 are different two sections of same curve, are curve overlapping part as Fig. 1 at mating part.Present embodiment 1 overlapping part vertical height is about 1-3mm, send the axial height of optical lens 9 to be about 6-10mm, axially highly be about 10-14mm after sending optical lens 9 and reflector 7 assemblings, this height is relevant with the design rising angle with the ratio (D/H) of bright dipping bore, rising angle is more little, and D/H is more little.Lower surface camber all is a central shaft symmetry surface of revolution on the receipts optical lens 7.Following light inlet center of surface zone 2 is protruding sphere (1<R<10), but is not limited to protruding sphere, also can be the revolution convex surface or the plane of conic section; Outer collar region 1 is to be about 60 °-90 ° concave cone face with the central shaft angle, but is not limited to the concave cone face, also can be conic section revolution concave surface; The corresponding central area 11 of last exiting surface is protruding sphere (5<R<20), and it can be other quadratic surface revolution convex surface or plane.The concave spherical surface that outer collar region 10 is (1<R<10).The revolution parabolic focus of its focus of convex lens at reflector 7 and receipts optical lens 9 formed on the corresponding protruding sphere of central area, top and bottom or plane.
Concrete optical path analysis such as Fig. 1:
The scattered light that led chip 3 sends in present embodiment 1 is divided three zones to handle, 0 °~25 ° of center low-angles, and transition region is than 25 °~50 ° of wide-angles, 50 °~90 ° of outer ring district wide-angles.
Center low-angle light enters the protruding sphere of the center band 2 of receiving 9 times incidence surfaces of optical lens, assemble deviation arrive go up exiting surface center band 11 protruding sphere once more behind the deviation with low-angle light outgoing near 0 °, simulated 0 ° as Fig. 1 ,+25 °, the deviation outgoing situation of-25 ° of three light.
The transition region that led chip 3 sends enters the concave surface of the outer collar region 1 of the following plane of incidence of receiving optical lens 9 than the light of 25 °~50 ° of wide-angles, through behind the outside deviation receiving the parabola surface of revolution 8 of optical lens 9 greater than the incidence angle directive of the angle of total reflection, and within it wall and produce total reflection after through behind outer collar region 10 deviations of receipts bright dipping curved surface on the optical lens 9 with extreme angles θ smaller or equal to design c(present embodiment design rising angle θ c=10 °) outgoing.
50 °~90 ° light of the outer ring district wide-angle that led chip 3 sends are introduced into the parabola revolution interior reflective surface 6 of reflector 7, reflection back low-angle enters the concave surface of the outer collar region 1 of the following incidence surface of receiving optical lens, the outer collar region 10 that the outside a little deviation of quilt enters exiting surface is again by inside deviation, at last with the extreme angles θ smaller or equal to design c(present embodiment design rising angle θ c=10 °) outgoing.
To sum up, central idea of the present invention is that scattered light with led chip 3 divides three zones to handle.The light of wide-angle be introduced into reflector 7 reflection back be basically parallel to axis direction enter receive the outer endless belt 1 of 9 times incidence surfaces of optical lens after, a little outwards behind the deviation outside last exiting surface behind the inside a little deviation of endless belt 11 with low-angle (θ c≤ 10 °) outgoing.Directly enter than high angle scattered light and to receive the outer collar region 1 outside deviation of optical lens 9 lower surfaces and strengthen incidence angle, on receiving the optical lens 9 parabolic surfaces of revolution 8 after the total reflection again on the process outside the exiting surface endless belt 11 further revise the low-angle outgoing.Low-angle light directly enters to be received optical lens 9 lower surface centers 2 protruding spheres and assembles deviations and arrive the protruding sphere 10 in upper surface centers and can gather correction again, and with near 0 ° of parallel light emergence, three part light are finally all with θ cThe angle outgoing of>θ>0.In this example θ c=10 °.
The invention also discloses the embodiment of the invention that is used for led chip 3 * 3 arrays 2 light-emitting lens groups 3 * 3 array figure as shown in Figure 2.Light-emitting lens group reflector is the array conjoined structure, and receiving optical lens is the array conjoined structure.Reflector plate 14 can be designed to corresponding array structure according to the different arrays of led chip with receipts optical lens plate 15.3 * 3 arrays of several embodiment 2 can splice and combine bigger array.

Claims (7)

1, LED small angle long distance light microscopic group comprises led light source, lens, it is characterized in that luminescence chip 3 of each light-emitting lens assembly, and each light-emitting lens group comprises reflector 7 and receives optical lens 9;
Reflector 7 is made up of the interior surface of revolution 6 of upper and lower opening.Surface of revolution 6 is formed around its symmetry axis revolution by conic section; Interior reflective surface plating total reflection film, the bottom of reflector 7 are that its center of circle of level overlaps with the focus of conic section, and LED luminescence chip 3 is installed in the focal position;
Described receipts optical lens 9 is made up of the ring conic section surface of revolution in week, last bright dipping curved surface and following incident curved surfaces.The revolution curve of receiving optical lens 9 can be different sections or a different conic section with 7 same conic sections of reflector, but the outlet of reflector 7 has corresponding identical cooperation position to concern with the inlet of receiving optical lens 9; Receive the following incident curved surfaces of optical lens 9 and be made up of two parts, center endless belt 2 is the convex surfaces with revolution symmetry, and outer endless belt 1 is the concave surface with revolution symmetry; Last exiting surface also is made up of two parts, center endless belt 11 is the symmetrical convex surfaces of revolution, outer endless belt 10 is bigger and convex surface or concave surfaces of relative center endless belt 11 radius of curvature, and these outer endless belt 10 curvature meet the following conditions: make to arrive behind this endless belt light low-angle deviation to equal the extreme angles θ less than design cOutgoing; Receive optical lens 9 about its focus of center of surface endless belt formation convex lens in the focus of conic section; This receipts optical lens 9 meets the following conditions: the receipts optical lens center smaller angle light beam that the corresponding formation of center of surface endless belt convex lens send led chip 3 about in the of 9 shrinks and converges, with the very little angle of departure outgoing near 0 °; The transition region that led chip 3 sends enters the concave surface of the outer collar region of the following incidence surface of receiving optical lens 9 than the wide-angle light beam, outwards behind the deviation receiving the surface of revolution 8 of optical lens 9 conic sections greater than the incidence angle directive of the cirtical angle of total reflection, and within it wall and produce total reflection after through behind outer collar region 10 deviations of receipts bright dipping curved surface on the optical lens 9 with extreme angles θ smaller or equal to design cOutgoing;
The height of reflector 7 highly is complementary with receipts optical lens 9 and gets final product, and the total height after the combination is associated with the design rising angle with the ratio L/D of bright dipping bore; Total height after the combination meets the following conditions: rising angle is more little, and L/D is just big more, and the lens packet size is big more; The outer ring district wide-angle light beam that led chip 3 sends enters the concave surface that enters the outer collar region 1 of the following incidence surface of receiving optical lens 9 after revolution reflecting surface 7 reflection of reflector 7, the outside a little deviation of quilt enters the outer collar region 10 inside deviations of exiting surface, at last with the extreme angles θ smaller or equal to design cOutgoing.
2, LED small angle long distance light microscopic group according to claim 1 is characterized in that receiving the refractive index of optical lens 9 between 1.3~3.5.
3, LED small angle long distance light microscopic group according to claim 1 is characterized in that the d/h=0.2-4 of the height of the diameter of light-emitting window and reflector 7.
4, LED small angle long distance light microscopic group according to claim 1 is characterized in that the diameter of LED luminescence chip 3 Diagonal Dimension less than the baseplane 5 of reflector 7.
5, LED small angle long distance light microscopic group array is characterized in that it being to be combined by a plurality of light-emitting lens group patterns, and arrangement pitches meets the following conditions: the light of each group does not disturb and enters another group and suitably be advisable in the gap;
Luminescence chip 3 of each light-emitting lens assembly, each light-emitting lens group comprise reflector 7 and receive optical lens 9;
Reflector 7 is made up of the interior surface of revolution 6 of upper and lower opening.Surface of revolution 6 is formed around its symmetry axis revolution by conic section; Interior reflective surface plating total reflection film, the bottom of reflector 7 are that its center of circle of level overlaps with the focus of conic section, and LED luminescence chip 3 is installed in the focal position;
Described receipts optical lens 9 is made up of the ring conic section surface of revolution in week, last bright dipping curved surface and following incident curved surfaces.The revolution curve of receiving optical lens 9 can be different sections or a different conic section with 7 same conic sections of reflector, but the outlet of reflector 7 has corresponding identical cooperation position to concern with the inlet of receiving optical lens 9; Receive the following incident curved surfaces of optical lens 9 and be made up of two parts, center endless belt 2 is the convex surfaces with revolution symmetry, and outer endless belt 1 is the concave surface with revolution symmetry; Last exiting surface also is made up of two parts, center endless belt 11 is the symmetrical convex surfaces of revolution, outer endless belt 10 is bigger and convex surface or concave surfaces of relative center endless belt 11 radius of curvature, and these outer endless belt 10 curvature meet the following conditions: make to arrive behind this endless belt light low-angle deviation to equal the extreme angles θ less than design cOutgoing; Receive optical lens 9 about its focus of center of surface endless belt formation convex lens in the focus of conic section; This receipts optical lens 9 meets the following conditions: the receipts optical lens center smaller angle light beam that the corresponding formation of center of surface endless belt convex lens send led chip 3 about in the of 9 shrinks and converges, with the very little angle of departure outgoing near 0 °; The transition region that led chip 3 sends enters the concave surface of the outer collar region of the following incidence surface of receiving optical lens 9 than the wide-angle light beam, outwards behind the deviation receiving the surface of revolution 8 of optical lens 9 conic sections greater than the incidence angle directive of the cirtical angle of total reflection, and within it wall and produce total reflection after through behind outer collar region 10 deviations of receipts bright dipping curved surface on the optical lens 9 with extreme angles θ smaller or equal to design cOutgoing;
The height of reflector 7 highly is complementary with receipts optical lens 9 and gets final product, and the total height after the combination is associated with the design rising angle with the ratio L/D of bright dipping bore; Total height after the combination meets the following conditions: rising angle is more little, and L/D is just big more, and the lens packet size is big more; The outer ring district wide-angle light beam that led chip 3 sends enters the concave surface that enters the outer collar region 1 of the following incidence surface of receiving optical lens 9 after revolution reflecting surface 7 reflection of reflector 7, the outside a little deviation of quilt enters the outer collar region 10 inside deviations of exiting surface, at last with the extreme angles θ smaller or equal to design cOutgoing.
6. LED small angle long distance light microscopic group array according to claim 5, it is characterized in that the synthetic luminescence chip plate 13 of luminescence chip 3 array group, reflector 7 array group are synthesized reflector plate 14, receive the synthetic optical lens plate 15 of receiving of optical lens 9 array group, they have identical spacing and array mode, arrangement pitches satisfies condition: the light of each group does not disturb and enters another group and suitably be advisable array LED chip board 13, reflector plate 14 and the cooperation position installation of receipts optical lens plate 15 to determine at interval.
7. LED small angle long distance light microscopic group array according to claim 5, it is characterized in that several light-emitting lens groups are that cell array combines, arrangement pitches meets the following conditions: the light of each group does not disturb and enters another group and suitably be advisable in the gap.
CNB2007100099676A 2007-12-10 2007-12-10 LED small angle long distance light microscopic group and array Expired - Fee Related CN100538160C (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CNB2007100099676A CN100538160C (en) 2007-12-10 2007-12-10 LED small angle long distance light microscopic group and array

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CNB2007100099676A CN100538160C (en) 2007-12-10 2007-12-10 LED small angle long distance light microscopic group and array

Publications (2)

Publication Number Publication Date
CN101240885A true CN101240885A (en) 2008-08-13
CN100538160C CN100538160C (en) 2009-09-09

Family

ID=39932611

Family Applications (1)

Application Number Title Priority Date Filing Date
CNB2007100099676A Expired - Fee Related CN100538160C (en) 2007-12-10 2007-12-10 LED small angle long distance light microscopic group and array

Country Status (1)

Country Link
CN (1) CN100538160C (en)

Cited By (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101994991B (en) * 2009-08-27 2012-02-29 杨璨源 Energy saving lamp
WO2014009761A1 (en) * 2012-07-11 2014-01-16 Stevan Pokrajac Led light assembly
CN103851367A (en) * 2012-12-01 2014-06-11 欧普照明股份有限公司 Light source
WO2014205611A1 (en) * 2013-06-26 2014-12-31 欧普照明股份有限公司 Illumination lamp and illumination light distribution module thereof
CN105705859A (en) * 2013-10-31 2016-06-22 松下知识产权经营株式会社 Illumination device
CN105782903A (en) * 2014-12-26 2016-07-20 杭州上达光电科技有限公司 LED optical system
TWI593916B (en) * 2013-12-27 2017-08-01 鴻海精密工業股份有限公司 Lens assembly and light source module having the same
CN107120571A (en) * 2015-03-25 2017-09-01 龙江汇 Led lamp
CN107859887A (en) * 2017-11-07 2018-03-30 成都新柯力化工科技有限公司 A kind of LED matrix cultivated for cordyceps sinensis
CN111063787A (en) * 2014-01-23 2020-04-24 亮锐控股有限公司 Light emitting device with self-aligned preformed lens
CN111323376A (en) * 2020-04-16 2020-06-23 中国科学院电工研究所 Parallel incidence infrared thermal radiation photoacoustic spectrum gas sensing device
CN113589581A (en) * 2021-08-06 2021-11-02 惠州伟志电子有限公司 Vehicle-mounted display screen and backlight module thereof
CN118099337A (en) * 2024-04-23 2024-05-28 广州市鸿利秉一光电科技有限公司 UV LED packaging structure and method

Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101994991B (en) * 2009-08-27 2012-02-29 杨璨源 Energy saving lamp
WO2014009761A1 (en) * 2012-07-11 2014-01-16 Stevan Pokrajac Led light assembly
CN103851367A (en) * 2012-12-01 2014-06-11 欧普照明股份有限公司 Light source
WO2014205611A1 (en) * 2013-06-26 2014-12-31 欧普照明股份有限公司 Illumination lamp and illumination light distribution module thereof
CN105705859B (en) * 2013-10-31 2018-11-13 松下知识产权经营株式会社 Lighting device
CN105705859A (en) * 2013-10-31 2016-06-22 松下知识产权经营株式会社 Illumination device
TWI593916B (en) * 2013-12-27 2017-08-01 鴻海精密工業股份有限公司 Lens assembly and light source module having the same
CN111063787A (en) * 2014-01-23 2020-04-24 亮锐控股有限公司 Light emitting device with self-aligned preformed lens
CN105782903A (en) * 2014-12-26 2016-07-20 杭州上达光电科技有限公司 LED optical system
CN107120571A (en) * 2015-03-25 2017-09-01 龙江汇 Led lamp
CN107859887A (en) * 2017-11-07 2018-03-30 成都新柯力化工科技有限公司 A kind of LED matrix cultivated for cordyceps sinensis
CN111323376A (en) * 2020-04-16 2020-06-23 中国科学院电工研究所 Parallel incidence infrared thermal radiation photoacoustic spectrum gas sensing device
CN111323376B (en) * 2020-04-16 2023-03-28 中国科学院电工研究所 Parallel incidence infrared thermal radiation photoacoustic spectrum gas sensing device
CN113589581A (en) * 2021-08-06 2021-11-02 惠州伟志电子有限公司 Vehicle-mounted display screen and backlight module thereof
CN118099337A (en) * 2024-04-23 2024-05-28 广州市鸿利秉一光电科技有限公司 UV LED packaging structure and method

Also Published As

Publication number Publication date
CN100538160C (en) 2009-09-09

Similar Documents

Publication Publication Date Title
CN100538160C (en) LED small angle long distance light microscopic group and array
EP2607169B1 (en) An improved LED device for wide beam generation and method of making the same
US8434914B2 (en) Lens generating a batwing-shaped beam distribution, and method therefor
CN101907263B (en) Lens member and optical unit using said lens member
US8132942B2 (en) LED devices for offset wide beam generation
CN101772669B (en) Street lighting arrangement
AU2015238892A1 (en) An optical lens and a miner's helmet lamp
CN203298189U (en) LED light source with COB module
CN102080805A (en) LED array street lamp lens module and manufacturing method thereof
CN103644487A (en) Light-emitting diode (LED) runway center line lamp optical system based on free curved lens
EP2802920A1 (en) Improved optical systems and led luminaires
CN104169776A (en) Improved optical systems and LED luminaires
CN205669770U (en) A kind of compound Fresnel Lenses being applicable to navigation light Optical devices
CN102313243B (en) Non-imaging LED (light emitting diode) collimation system with compact structure
CN103994396A (en) LED secondary refraction and reflection lens for direct lighting type backlight source
CN102901045A (en) Fresnel lens for high-power light-emitting diode (LED) light source
CN114440142B (en) LED optical system for forming special-shaped outline light spots based on micro-lens array
CN207394744U (en) A kind of Combined lens
CN214948814U (en) Airport taxiway lamp
CN202835182U (en) Fresnel lens for LED light source with high power
CN107178764A (en) A kind of compound Fresnel Lenses suitable for navigation light Optical devices
CN201412732Y (en) LED traffic light assembly
CN212584890U (en) Lens assembly with adjustable irradiation angle and lamp
CN204005733U (en) Bis-refraction-reflection lens of LED for downward back radiant
CN102080808B (en) Lens for LED (light emitting diode) outdoor lamps

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
C14 Grant of patent or utility model
GR01 Patent grant
DD01 Delivery of document by public notice

Addressee: Lin Ruimei

Document name: Notification to Pay the Fees

CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20090909

Termination date: 20141210

EXPY Termination of patent right or utility model