CN202267783U - Homologous light splitting optical device - Google Patents
Homologous light splitting optical device Download PDFInfo
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- CN202267783U CN202267783U CN 201120423030 CN201120423030U CN202267783U CN 202267783 U CN202267783 U CN 202267783U CN 201120423030 CN201120423030 CN 201120423030 CN 201120423030 U CN201120423030 U CN 201120423030U CN 202267783 U CN202267783 U CN 202267783U
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- light
- right angle
- reflected light
- prism
- beam split
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Abstract
The utility model provides a homologous light splitting optical device, which comprises a block prism arranged on an incident light path, a spectroscope arranged on a first transmission light path of the block prism and a reflector arranged on a second transmission light path of the spectroscope. The second reflected light is reflected by the reflector to form third reflected light, and the light path of the third reflected light is extended along the crossing point of a first reflected light path and the first transmission light path of the block prism. Through the optical device, a beam of aligned laser can form three beams of aligned laser in the three-dimensional direction by two times of light splitting, and the light splitting precision is ensured by optical processing; and the optical device is favorable for large-batch production, and provides a foundation for industrialized production of tapered mirror reflecting laser cast instruments.
Description
Technical field
The utility model belongs to laser and throws the line technology field, is specifically related to a kind of homology beam split optical devices.
Background technology
Laser level is at present at building, decoration and the widely used a kind of laser device of all kinds of project installation industry, and its function mainly is to utilize wire harness laser that three dimensions is carried out level and perpendicular positioning, sign.
Present laser level is made up of eight laser modules usually, and its laser module is with cylindrical lens laser beam to be changed over covering of the fan to distribute, and throws to be linear laser.Using four laser modules is one 360 ° projecting laser line in horizontal space butt joint.Other four mode of laser components are two groups, every group use two laser modules the vertical space butt joint be one less than 360 ° projecting laser line.Two groups of formed lasing areas are vertical each other, utilize laser rays to throw the function of line sign thereby reach at three dimensions.This three-dimensional line function of throwing can realize with three conical reflectors, so the employed laser module of the trans laser level of axicon lens reduces to three by eight, not only simplifies the structure, and has reduced cost.
Utilize conical reflector to reach the trans laser level of this axicon lens of 360 ° of projecting laser line technologies, its key is on three-dimensional, to form three beams of laser, and its optical axis is vertical each other.The orthogonal verticality precision of its optical axis is high more, is a basic guarantee to throwing the line precision.In actual product is used; Reach the orthogonal laser of the high-precision three beams optical axis of formation on the three-dimensional with three laser modules as light source, its shortcoming: the one, the adjustment structure more complicated, the instrument volume is bigger; The 2nd, mechanical adjustment is difficult to guarantee its high precision, is unfavorable for the realization of industrialization.More satisfactory is the method through the optics beam split, laser beam is decomposed into the three beams of laser of the orthogonal three-dimensional of optical axis.Guarantee its vertical precision through optics processing, not only can three laser modules be reduced to a laser module and make light source, further reduce cost, and simplify adjustment structure, the reduction printer body is long-pending, further advances axicon lens reflective laser level to reach industrialization.
The utility model content
The purpose of the utility model provides a kind of homology beam split optical devices; Reach three-dimensional on formation high-precision three beams optical axis orthogonal laser existing adjustment structure more complicated with three laser modules as light source to solve existing axicon lens reflective laser level; The instrument volume is bigger; Mechanical adjustment is difficult to guarantee its high precision, is unfavorable for the problem of the realization of industrialization.
For reaching above-mentioned purpose; The utility model provides a kind of homology beam split optical devices; Spectroscope on the first transmitted light light path that comprise the block prism that is arranged on the optical path of incident light, is arranged on this block prism and be arranged on the catoptron on this spectroscopical second reflected light light path; This second reflected light forms the 3rd reflected light after this mirror reflects, the 3rd reflected light light path is extended along the first reflected light light path of said block prism and the intersection point of the said first transmitted light light path.
Above-mentioned block prism is formed by the first right angle isosceles prism and the second right angle isosceles prism gummed; The following right angle face of the said first right angle isosceles prism is arranged on the optical path of incident light; The inclined-plane of this first right angle isosceles prism is provided with semi-transparent semi-reflecting beam split plated film; Face incides on this inclined-plane said incident light through this time right angle, is divided into said first reflected light by the beam split plated film and reaches said first transmitted light that sees through this inclined-plane; Face penetrates said first reflected light through the side right angle of this first right angle isosceles prism.
Above-mentioned spectroscope comprises transmission plane and reflecting surface; Said first transmitted light incides behind this reflecting surface a part and is reflected and forms said second reflected light and incide on the said catoptron; Another part passes this reflecting surface and penetrates formation second transmitted light through said transmission plane, and this second transmitted light penetrates along said first transmitted light light path.
Above-mentioned catoptron is special-shaped side right angle wedge mirror or side right-angle prism, and this side right-angle prism comprises long right angle face, and this long right angle face is provided with total reflection film, and this long right angle face is arranged on the said second catoptrical light path; This second reflected light forms said the 3rd reflected light after this long right angle face total reflection; The inclined-plane of the said first isosceles prism is arranged on the 3rd catoptrical light path.
The locus of the long right angle face of above-mentioned spectroscopical reflecting surface and said side right angle wedge mirror should make said second reflected light not with the inclined-plane interference of the said first right angle isosceles prism.
Above-mentioned incident light is an optical alignment laser.
Above-mentioned collimation laser is semiconductor, He-Ne or CO
2Laser.
Above-mentioned right angle isosceles prism, spectroscope and side right angle wedge mirror are processed with optical glass or optical plastic.
Above-mentioned first reflected light, first transmitted light and the 3rd reflected light are through the three-dimensional coordinate initial point, respectively along Y axle, Z axle, X-direction output.
The utility model has the advantages that: a branch of collimation laser can form the three beams collimation laser of three-dimensional through twice beam split; And through its beam split precision of optics processing assurance; Not only help mass production, and provide the foundation for the industrialization of axicon lens reflective laser level.
Description of drawings
Combine accompanying drawing and embodiment that the utility model is elaborated at present:
Fig. 1 is the light path synoptic diagram of the homology beam split optical devices that provide of the utility model.
Fig. 2 is the position view of each optical element of the homology beam split optical devices that provide of the utility model.
Fig. 3 is the structural representation of block prism.
Among the figure: 1, input laser; 2, first reflected light; 3, first transmitted light; 4, reflected light; 5; The 3rd reflected light; 6, second reflected light; 7, second transmitted light; 8,9, beam split plated film face; 10, full reflective surface; 11, optical axes crosspoint; 12, first isosceles right-angle prism; 13, descend the right angle face; 14, inclined-plane; 15, spectroscope; 16, block prism; 17, catoptron; 18, long right angle face; 19, the second isosceles prism; 20, side right angle face.
Embodiment
Embodiment 1:
The homology beam split optical devices that provided; As shown in Figure 2; Spectroscope 15 on the first transmitted light light path that comprise the block prism 16 that is arranged on the optical path of incident light, is arranged on this block prism 16 and be arranged on the catoptron 17 on the second reflected light light path of this spectroscope 15; This second reflected light forms the 3rd reflected light after these catoptron 17 reflections, the 3rd reflected light light path is extended along the first reflected light light path of block prism 16 and the intersection point of the first transmitted light light path.Certainly, block prism 16 wherein also can be substituted by other optical components that can realize beam split and printing opacity in the prior art, has just selected block prism 16 as beam split and transmissive mirror in this example.
Embodiment 2:
Basis at embodiment 1; When block prism 16 is formed by two isosceles right-angle prism gummeds; The concrete realization of the homology beam split optical devices that present embodiment provided sees also Fig. 1 and Fig. 2; Input laser 1 incides following right angle face 13 (see figure 3)s of first isosceles right-angle prism 12 of block prism 16 along Z-direction input, again the inclined-plane 14 (being coated with semi-transparent semi-reflecting beam split plated film face 8 on it) through this first isosceles right-angle prism 12; Tell first reflected light 2 along Y direction output, the energy of this first reflected light 2 account for input laser 1 gross energy 1/3; Another bundle light of beam split plated film face 8 i.e. first transmitted light 3 continues along Z-direction output, and its energy accounts for the gross energy about 2/3 of input laser 1.The inclined-plane of first isosceles right-angle prism 12 is arranged on the 3rd catoptrical light path
Through the beam split plated film face 9 on the spectroscope 15, tell second reflected light 6 and second transmitted light 7 through first transmitted light 3 of beam split plated film face 8, respectively account for about 1/2 of first transmitted light, 3 luminous energies.Second transmitted light 7 is exported along Z-direction; Second reflected light 6 produces first reflected light 2 and first transmitted light 3 optical axes crosspoints 11 of the 3rd reflected light 5, the three reflected light 5 outputs through beam split plated film face 8 through the full reflective surface 10 of catoptron 17, and exports along X-direction.
Wherein the 3rd reflected light 6 not with 8 interferences of beam split plated film face; Optical axes crosspoint 11 is the 3rd reflected light 5 of three-dimensional output light Y axle first reflected light 2 (or-Y axle reflected light 4, this reflected light 4 is by beam split plated film face 8 half-twists, due to the reflection incident laser 1), X axle, the three-dimensional coordinate initial point O of second transmitted light 7 on the Z axle.So, become and realized the three beams collimation laser of a branch of collimation laser, and guarantee its beam split precision, not only help mass production, and provide the foundation for the industrialization of axicon lens reflective laser level through optics processing through twice beam split formation three-dimensional.
The composition structure of these homology beam split optical devices; High-visible by Fig. 2; Spectroscope 15 on first transmitted light, 3 light paths that comprise the block prism 16 that is arranged on incident light (the input laser 1 shown in Figure 1) light path, are arranged on this block prism 16 and be arranged on the catoptron 17 on the light path of second reflected light 6 of this spectroscope 15; The intersection point O of the light path of this second reflected light 6 light path edge first reflected light 2 of formation the 3rd reflected light 5, the three reflected light 5 after these catoptron 17 reflections and the light path of first transmitted light 3 extends.
Say that more carefully spectroscope 15 comprises transmission plane and reflecting surface; First transmitted light 3 incides behind this reflecting surface a part and is reflected and forms second reflected light 6 and incide on the catoptron 17, and another part passes this reflecting surface and penetrates through transmission plane and form second transmitted light 7, and this second transmitted light 7 penetrates along first transmitted light, 3 light paths.And catoptron 17 is special-shaped side right angle wedge mirror or side right-angle prism, and this side right-angle prism comprises long right angle face 18, and this long right angle face 18 is provided with total reflection film, and it is arranged on the light path of second reflected light 6; This second reflected light 6 forms the 3rd reflected light 5 after these long right angle face 18 total reflections.
The reflecting surface of spectroscope 15 be beam split plated film face 9 and the side right angle wedge mirror among Fig. 1 be the locus of the long right angle face 18 of catoptron 17 should make second reflected light 6 not with inclined-plane 14 interferences of the first right angle isosceles prism 12; For example when the length of side of block prism 16 is 6mm; The minimum angle of the vertical axis of spectroscope 15 and block prism 16 is 33.4 degree, and the light of reflection this moment is on the inclined-plane 14 of first isosceles right-angle prism 12 at the cemented surface that could light vertically be injected block prism 16 through catoptron 17 8.
It should be noted that the block prism 16 that the utility model provides also can be the other forms of optical component that can realize spectrophotometric result in the prior art equally.More it should be noted that everyly all can reach the same or similar system of the said function of the optical system that is provided with present embodiment, all should within the coverage of present embodiment, belong within the protection domain of present patent application through the prior art means.
Claims (9)
1. homology beam split optical devices; It is characterized in that: the spectroscope on the first transmitted light light path that comprise the block prism that is arranged on the optical path of incident light, is arranged on this block prism and be arranged on the catoptron on this spectroscopical second reflected light light path; This second reflected light forms the 3rd reflected light after this mirror reflects, the 3rd reflected light light path is extended along the first reflected light light path of said block prism and the intersection point of the said first transmitted light light path.
2. homology beam split optical devices as claimed in claim 1; It is characterized in that: said block prism is formed by the first right angle isosceles prism and the second right angle isosceles prism gummed; The following right angle face of the said first right angle isosceles prism is arranged on the optical path of incident light; The inclined-plane of this first right angle isosceles prism is provided with semi-transparent semi-reflecting beam split plated film; Face incides on this inclined-plane said incident light through this time right angle, is divided into said first reflected light by the beam split plated film and reaches said first transmitted light that sees through this inclined-plane; Face penetrates said first reflected light through the side right angle of this first right angle isosceles prism.
3. according to claim 1 or claim 2 homology beam split optical devices, it is characterized in that: said spectroscope comprises transmission plane and reflecting surface; Said first transmitted light incides behind this reflecting surface a part and is reflected and forms said second reflected light and incide on the said catoptron; Another part passes this reflecting surface and penetrates formation second transmitted light through said transmission plane, and this second transmitted light penetrates along said first transmitted light light path.
4. homology beam split optical devices as claimed in claim 3; It is characterized in that: said catoptron is special-shaped side right angle wedge mirror or side right-angle prism; And this side right-angle prism comprises long right angle face; This long right angle face is provided with total reflection film, and this long right angle face is arranged on the said second catoptrical light path; This second reflected light forms said the 3rd reflected light after this long right angle face total reflection; The inclined-plane of the said first isosceles prism is arranged on the 3rd catoptrical light path.
5. homology beam split optical devices as claimed in claim 4 is characterized in that: the locus of the long right angle face of said spectroscopical reflecting surface and said side right angle wedge mirror should make said second reflected light not with the inclined-plane interference of the said first right angle isosceles prism.
6. homology beam split optical devices as claimed in claim 5 is characterized in that: said incident light is an optical alignment laser.
7. homology beam split optical devices as claimed in claim 6 is characterized in that: said collimation laser is semiconductor, He-Ne or CO
2Laser.
8. homology beam split optical devices as claimed in claim 7 is characterized in that: said right angle isosceles prism, spectroscope and side right angle wedge mirror are processed with optical glass or optical plastic.
9. homology beam split optical devices as claimed in claim 8 is characterized in that: said first reflected light, first transmitted light and the 3rd reflected light are through the three-dimensional coordinate initial point, respectively along Y axle, Z axle, X-direction output.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 201120423030 CN202267783U (en) | 2011-10-31 | 2011-10-31 | Homologous light splitting optical device |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 201120423030 CN202267783U (en) | 2011-10-31 | 2011-10-31 | Homologous light splitting optical device |
Publications (1)
Publication Number | Publication Date |
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CN202267783U true CN202267783U (en) | 2012-06-06 |
Family
ID=46158570
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN 201120423030 Expired - Lifetime CN202267783U (en) | 2011-10-31 | 2011-10-31 | Homologous light splitting optical device |
Country Status (1)
Country | Link |
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CN (1) | CN202267783U (en) |
-
2011
- 2011-10-31 CN CN 201120423030 patent/CN202267783U/en not_active Expired - Lifetime
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CX01 | Expiry of patent term |
Granted publication date: 20120606 |
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CX01 | Expiry of patent term |