CN102385106B - Method for energy grade light ray curve transmission - Google Patents
Method for energy grade light ray curve transmission Download PDFInfo
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- CN102385106B CN102385106B CN201010266432.9A CN201010266432A CN102385106B CN 102385106 B CN102385106 B CN 102385106B CN 201010266432 A CN201010266432 A CN 201010266432A CN 102385106 B CN102385106 B CN 102385106B
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- reflection
- refraction
- cutting
- polycondensation mirror
- total reflection
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Abstract
The invention relates to a method for energy grade light ray curve transmission, which comprises asymmetric polycondensation lenses and is characterized in that a unit element of the energy grade light ray curve transmission is formed by the asymmetric polycondensation lenses. A light ray exit face of a first cut asymmetric polycondensation lens is connected with, smaller than and within a light ray incident face of a second cut asymmetric polycondensation lens. A light ray exit face of the second cut asymmetric polycondensation lens is connected with, smaller than and within a light ray incident face of a third cut asymmetric polycondensation lens. By means of connection in the repeating mode in sequence, a curved optical medium channel is formed, the curved optical medium channel has two curving modes, wherein one mode is that virtual central symmetry axes of the asymmetric polycondensation lenses of the curved optical medium channel forming the curve are in the same plane, and the other mode is that the virtual central symmetry axes of the asymmetric polycondensation lenses of the curved optical medium channel forming the curve are in two or more than two planes.
Description
Technical field
What patent of the present invention related to is the method for energy grade light ray curve transmission, especially a kind ofly by asymmetric polycondensation mirror, forms the method that crooked optical medium passage carries out energy grade light ray curve transmission.
Background technology
Polycondensation mirror is divided into two kinds of refraction, reflection, total reflection polycondensation mirror and refraction, reflection polycondensation mirrors.
The light incident end of polycondensation mirror comprises plane of light incidence, emphasizes the factor that polycondensation mirror is cut simultaneously; The beam projecting end of polycondensation mirror comprises beam projecting face, emphasizes the factor that polycondensation mirror is cut simultaneously.
The method of energy grade light ray curve transmission be reflect, reflection, total reflection polycondensation mirror (application number: 201010028057.4), integrated concentrating method (the application number: 201010134349.6) that refraction, reflection, total reflection polycondensation mirror are main body, refraction, reflection polycondensation mirror (application number: the integrated concentrating method 201010028058.9), reflect, reflection polycondensation mirror being main body (application number: 201010134358.5) be basis.
Summary of the invention
The object of the invention is to form crooked optical medium passage with asymmetric polycondensation mirror, a kind of method of carrying out energy grade light ray curve transmission by crooked optical medium passage is provided.
The method of energy grade light ray curve transmission of the present invention, comprise: asymmetric polycondensation mirror, it is characterized in that: asymmetric polycondensation mirror, consist of the identical element of energy grade light ray curve transmission, asymmetric polycondensation mirror is divided into two kinds of asymmetric refraction, reflection, total reflection polycondensation mirror and asymmetric refraction, reflection polycondensation mirrors, cut the original plane of light incidence of centrosymmetric polycondensation mirror, beam projecting face, the central symmetry axis of polycondensation mirror and the plane of light incidence of polycondensation mirror before cutting, beam projecting face are vertical, plane of light incidence, the beam projecting face of cutting aftercondensated mirror are complete planes, it not curved surface, and plane of light incidence, beam projecting face and the virtual center axis of symmetry out of plumb of cutting aftercondensated mirror, polycondensation mirror after cutting is non-centrosymmetry, and virtual center axis of symmetry is the central symmetry axis before polycondensation mirror does not cut, plane of light incidence, the line of beam projecting face and the central symmetry axis of polycondensation mirror of cutting polycondensation mirror are vertical, and the cutting plane of light incidence of polycondensation mirror is, two lines of beam projecting face have two kinds of position relationships, and the first is parallel, and the second is not parallel, the beam projecting face of the asymmetric polycondensation mirror after first cutting connects the plane of light incidence of the asymmetric polycondensation mirror after second cutting, the beam projecting face of the asymmetric polycondensation mirror after first cutting is less than and does not exceed the plane of light incidence of second asymmetric polycondensation mirror after cutting, the beam projecting face of the asymmetric polycondensation mirror after second cutting connects the plane of light incidence of the asymmetric polycondensation mirror after the 3rd cutting, the beam projecting face of the asymmetric polycondensation mirror after second cutting is less than and does not exceed the plane of light incidence of the 3rd the asymmetric polycondensation mirror after cutting, repeat successively to connect, form crooked optical medium passage, crooked optical medium passage has two kinds of bend mode: the first is to form the virtual center axis of symmetry of asymmetric polycondensation mirror of crooked optical medium passage at same plane, the second is to form the virtual center axis of symmetry of asymmetric polycondensation mirror of crooked optical medium passage on two and plural plane, at crooked optical medium passage, the plane of light incidence of the asymmetric polycondensation mirror of light from first cutting enters, the beam projecting face of the asymmetric polycondensation mirror of light from last cutting is gone out, in this process, realize polycondensation and the adjustment of light transmission direction of light, reach energy grade light ray curve transmission.
The method of energy grade light ray curve transmission of the present invention is provided in detail by the following drawings and embodiment.
accompanying drawing explanation
Fig. 1 is the schematic cross-section that the polycondensation mirror of the method for energy grade light ray curve transmission cuts.
embodiment
Embodiment: the identical element of energy grade light ray curve transmission needs stationary installation to fix asymmetric polycondensation mirror, guarantees that crooked optical medium passage is stable; The identical element of energy grade light ray curve transmission is in sealing state, and its effect is that the effect that guarantees optical medium is not weakened.
Fig. 1 is the schematic cross-section that the polycondensation mirror of the method for energy grade light ray curve transmission cuts, (1) represent the central symmetry axis of polycondensation mirror, the overall transfer direction that simultaneously represents light in polycondensation mirror, (2) intersection point of the central symmetry axis (1) of the plane of light incidence after the cutting of expression polycondensation mirror and polycondensation mirror, (3) represent the plane of light incidence after polycondensation mirror cutting, (4) represent polycondensation mirror, (5) represent the beam projecting face after polycondensation mirror cutting, the intersection point of the beam projecting face after the cutting of (6) expression polycondensation mirror and the central symmetry axis (1) of polycondensation mirror; The method of attachment of asymmetric polycondensation mirror is: the intersection point (6) of the beam projecting face of first asymmetric polycondensation mirror overlaps with the intersection point (2) of the plane of light incidence of second asymmetric polycondensation mirror, the intersection point (6) of the beam projecting face of second asymmetric polycondensation mirror overlaps with the intersection point (2) of the plane of light incidence of the 3rd asymmetric polycondensation mirror, repeat successively to connect, form crooked optical medium passage.From symmetrical polycondensation mirror to asymmetric polycondensation mirror, the method of cutting polycondensation mirror is divided into three kinds: the first is the light incident end of cutting polycondensation mirror, plane of light incidence (3) after the light incident end of polycondensation mirror is cut by polycondensation mirror replaces, and the beam projecting end of polycondensation mirror does not cut, the beam projecting end of polycondensation mirror overlaps with the beam projecting face (5) after polycondensation mirror cutting; The second is the beam projecting end of cutting polycondensation mirror, beam projecting face (5) after the beam projecting end of polycondensation mirror is cut by polycondensation mirror replaces, and polycondensation mirror light incident end does not cut, the light incident end of polycondensation mirror overlaps with the plane of light incidence (3) after polycondensation mirror cutting; The third is light incident end and the beam projecting end of cutting polycondensation mirror, and the plane of light incidence (3) after the light incident end of polycondensation mirror is cut by polycondensation mirror replaces, and the beam projecting face (5) after the beam projecting end of polycondensation mirror is cut by polycondensation mirror replaces.Due to refraction, reflection, the contracting of total reflection polycondensation mirror and refraction, reflection polycondensation mirror does not have polycondensation ability to the light outside critical angle and critical zone, symmetrical polycondensation mirror through cutting, become asymmetrical polycondensation mirror, have equally the light outside critical angle and critical zone is not had to polycondensation ability, therefore the crooked optical medium passage being formed by asymmetric polycondensation mirror, the curvature of crooked optical medium passage must be in the critical range of polycondensation mirror, by asymmetric refraction, reflection, the curvature range of the crooked optical medium passage that total reflection polycondensation mirror forms is greater than asymmetric refraction, the curvature range of the crooked optical medium passage that reflection polycondensation mirror forms, when the curvature range of crooked optical medium passage is in asymmetric refraction, within the critical buckling of reflection polycondensation mirror, crooked optical medium passage can be selected two kinds of asymmetric polycondensation mirrors: the first is non-symmetrical refraction, reflection, total reflection polycondensation mirror, the second is non-symmetrical refraction, reflection polycondensation mirror, when the curvature range of crooked optical medium passage is within the critical buckling of asymmetric refraction, reflection, total reflection polycondensation mirror, crooked optical medium passage is by asymmetric refraction, reflection, total reflection polycondensation mirror, when the curvature range of crooked optical medium passage is greater than the critical buckling of asymmetric polycondensation mirror, light is escaped in crooked optical medium passage, causes optical energy loss.
Claims (2)
1. a method for energy grade light ray curve transmission, energy grade light ray curve transmission identical element comprises: plane of light incidence, beam projecting face is cut refraction in the slope, reflection, total reflection polycondensation mirror, is characterized in that: pass through plane of light incidence, beam projecting face is cut refraction in the slope, reflection, total reflection polycondensation mirror forms the identical element of energy grade light ray curve transmission, cuts refraction, reflection, the original plane of light incidence of total reflection polycondensation mirror, beam projecting face, the refraction before cutting, reflection, the central symmetry axis of total reflection polycondensation mirror and refraction, reflection, the plane of light incidence of total reflection polycondensation mirror, beam projecting face is vertical, the refraction after cutting, reflection, the plane of light incidence of total reflection polycondensation mirror, beam projecting face is that complete plane is not curved surface, and the refraction after cutting, reflection, the plane of light incidence of total reflection polycondensation mirror, refraction before beam projecting face and cutting, reflection, the not parallel also out of plumb of central symmetry axis of total reflection polycondensation mirror, the refraction after cutting, reflection, the plane of light incidence of total reflection polycondensation mirror, beam projecting face is with respect to the refraction before cutting, reflection, the inclined-plane of the central symmetry axis of total reflection polycondensation mirror, the refraction after single cutting, reflection, the plane of light incidence of total reflection polycondensation mirror, beam projecting mask is gradient, the refraction after cutting, reflection, total reflection polycondensation mirror is non-centrosymmetrical, the refraction after first cutting, reflection, the beam projecting face of total reflection polycondensation mirror connects the refraction after second cutting, reflection, the plane of light incidence of total reflection polycondensation mirror, forms the flexibility connecting, the refraction after first cutting, reflection, the beam projecting face of total reflection polycondensation mirror is less than and does not exceed second refraction after cutting, reflection, the plane of light incidence of total reflection polycondensation mirror, the refraction after second cutting, reflection, the beam projecting face of total reflection polycondensation mirror connects the refraction after the 3rd cutting, reflection, the plane of light incidence of total reflection polycondensation mirror, the refraction after second cutting, reflection, the beam projecting face of total reflection polycondensation mirror is less than and does not exceed the 3rd refraction after cutting, reflection, the plane of light incidence of total reflection polycondensation mirror, repeats to connect successively, forms crooked optical medium passage, and crooked optical medium passage has two kinds of bend mode: the first is the asymmetric refraction that forms crooked optical medium passage, reflection, central symmetry axis before the cutting of total reflection polycondensation mirror is at same plane, and the second is the asymmetric refraction that forms crooked optical medium passage, reflection, central symmetry axis before the cutting of total reflection polycondensation mirror is in plural plane, at crooked optical medium passage, refraction, the reflection of light from first cutting, the plane of light incidence of total reflection polycondensation mirror enter, refraction, the reflection of light from last cutting, the beam projecting face of total reflection polycondensation mirror are gone out, in this process, realize polycondensation and the adjustment of light transmission direction of light, reach energy grade light ray curve transmission.
2. a kind of method of energy grade light ray curve transmission according to claim 1, is characterized in that: refraction, reflection, plane of light incidence after the cutting of total reflection polycondensation mirror and the refraction before cutting, reflection, the central symmetry axis of total reflection polycondensation mirror intersects formation plane of incidence intersection point (2), refraction, reflection, beam projecting face after the cutting of total reflection polycondensation mirror and the refraction before cutting, reflection, the central symmetry axis of total reflection polycondensation mirror intersects formation exit facet intersection point (6), the refraction after cutting, reflection, the method of attachment of total reflection polycondensation mirror is: the refraction after first cutting, reflection, refraction after the exit facet intersection point (6) of total reflection polycondensation mirror and second cutting, reflection, the plane of incidence intersection point (2) of total reflection polycondensation mirror overlaps, the refraction after second cutting, reflection, refraction after the exit facet intersection point (6) of total reflection polycondensation mirror and the 3rd cutting, reflection, the plane of incidence intersection point (2) of total reflection polycondensation mirror overlaps, and repeats successively to connect, and forms crooked optical medium passage.
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CN201010266432.9A CN102385106B (en) | 2010-08-30 | 2010-08-30 | Method for energy grade light ray curve transmission |
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CN102385106B true CN102385106B (en) | 2014-04-02 |
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CN102978108B (en) * | 2011-09-05 | 2014-12-03 | 成都易生玄科技有限公司 | Method for controlling internal environment of biogas digester by polycondensation light |
CN103503725A (en) * | 2012-06-27 | 2014-01-15 | 成都易生玄科技有限公司 | Indoor plant cultural method with condensed and transmitted light |
CN103574391A (en) * | 2012-07-31 | 2014-02-12 | 成都易生玄科技有限公司 | Sterilizing illuminating lamp with light condensation and transmission functions |
CN104234580B (en) * | 2013-06-08 | 2016-11-16 | 成都易生玄科技有限公司 | A kind of polycondensation, the door frame device of transmission ray |
Citations (2)
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CN1580902A (en) * | 2003-08-05 | 2005-02-16 | 财团法人工业技术研究院 | Light source modulating device for function curve type lens grating |
CN1708708A (en) * | 2002-11-01 | 2005-12-14 | 欧姆龙株式会社 | Optical multiplexer/demultiplexer and production method for optical multiplexer/demultiplexer |
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JP2004309610A (en) * | 2003-04-03 | 2004-11-04 | Dainippon Printing Co Ltd | Lenticular lens sheet and transmission screen using same |
JP5009017B2 (en) * | 2007-03-26 | 2012-08-22 | 三菱電機株式会社 | Phase distribution controller |
ES2335637B1 (en) * | 2008-04-08 | 2011-05-27 | Universitat Politècnica De Catalunya | OPTICAL DEVICE AND PROCEDURE FOR THE RECONSTRUCTION AND COMPENSATION OF THE WAVE FRONT FROM A COMPLEX OPTICAL ELEMENT. |
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CN1708708A (en) * | 2002-11-01 | 2005-12-14 | 欧姆龙株式会社 | Optical multiplexer/demultiplexer and production method for optical multiplexer/demultiplexer |
CN1580902A (en) * | 2003-08-05 | 2005-02-16 | 财团法人工业技术研究院 | Light source modulating device for function curve type lens grating |
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JP特开2004-309610A 2004.11.04 |
JP特开2008-241896A 2008.10.09 |
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Effective date of registration: 20200422 Address after: 236000 Yingtai Road, Yingshang County Industrial Park, Fuyang City, Anhui Province Patentee after: HAIQUAN FENGLEI NEW ENERGY POWER GENERATION Co.,Ltd. Address before: High tech Zone Gaopeng road in Chengdu city of Sichuan province 610041 No. 5 A-93 Patentee before: CHENGDU YISHENGXUAN TECHNOLOGY Co.,Ltd. |
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Granted publication date: 20140402 Termination date: 20200830 |