CN201210201Y - Light ray parallel adjusting apparatus - Google Patents
Light ray parallel adjusting apparatus Download PDFInfo
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- CN201210201Y CN201210201Y CNU200820078801XU CN200820078801U CN201210201Y CN 201210201 Y CN201210201 Y CN 201210201Y CN U200820078801X U CNU200820078801X U CN U200820078801XU CN 200820078801 U CN200820078801 U CN 200820078801U CN 201210201 Y CN201210201 Y CN 201210201Y
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- light
- beam splitter
- polarizing beam
- wave plates
- laser
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Abstract
The utility model relates to an optical-line paralleling-adjusting device, and belongs to the technical field of the opto-electric detection. A collimated laser (1) with high stability is used to transmit the collimated laser light that is split by an optical splitter (2) in a polarization way; a quarter of gamma wave plate is respectively arranged on a reflection optical path and a transmission optical path of the polarization optical splitter (2); the angle between the fast-shaft direction of the wave plate and the polarization direction of the laser light is 45 degrees. The light is reflected in an opposite direction through a same flat reflector (9), so that the adjusted optical light is injected on a same angle detector (8); by adjusting the two-dimensional reflector (6), the parallelism of the two outgoing optical light reaches one second of arc or less. The device also can adjust the parallelism of a plurality of beams of the optical light, and has simple structure, flexible application, strong universality, low cost, convenient correction, and high adjustment precision.
Description
Technical field
The utility model belongs to photoelectric detection technology field, the high precision adjustment of the depth of parallelism between particularly a kind of light.Utilize adjusted parallel beam can carry out the measurement of paralleism of two line slideways, can also carry out the rolling angle measurement of line slideway auxiliary itself.
Background technology
The numerically-controlled machine line slideway auxiliary need carry out rolling angle measurement, and the simplest measuring method is to utilize parallel rays to measure.Although can make light produce parallel rays,, be difficult to obtain the two-beam line parallel below 1 second of arc, and high-precision pentagonal prism cost is also expensive because pentagonal prism can only guarantee the vertical of a direction by two pentagonal prisms.
The purpose of this utility model is to provide a kind of laser parallel adjusting gear and method with versatility, adjusts precision and is better than 1 second of arc.Utilize parallel rays that the method obtains to debug rolling angle measurement with guide rail itself as the collimation between the guide rail closely.
Summary of the invention
The device of the parallel adjustment of a kind of light is: the collimation laser device sends the collimation laser of high stability, through the polarizing beam splitter beam split.Wherein place λ/4 wave plates on the reflected light path of polarizing beam splitter, the quick shaft direction of wave plate and the polarization direction of laser are at 45, incide on the plane mirror again.And on the transmitted light path of polarizing beam splitter, place another one λ/4 wave plates, the quick shaft direction of wave plate and the polarization direction of laser are also at 45, again by the mirror reflection of a two-dimensional adjustable plane reflection, make that its reflection direction is parallel with the reflected light of polarizing beam splitter to be incided on the same plane mirror.Plane reflector makes the reverse polarizing beam splitter that turns back to of two light.Because two light beams see through λ/4 wave plates twice respectively, the direction of vibration of light has rotated 90 ° respectively, and therefore original reflected light through polarizing beam splitter becomes transmitted light, and the transmitted light through polarizing beam splitter became reflected light originally.Incide on the same detector by lens.
Described collimated light device comprises semiconductor laser and the gas laser through the single-mode fiber collimation.
Described polarizing beam splitter can be unpolarized semi-transparent semi-reflecting optical splitter, at this moment two λ/4 wave plates can, just energy loss will take place in the light that reflects from plane mirror.
Described detector can be wherein a kind of of 4 quadrant detector, Position-Sensitive Detector and CCD.
Described detector must be placed on the lens focal plane.
Described lens can also substitute with lens combination.
Described device can produce the multi beam parallel rays by increasing polarizing beam splitter and λ/4 wave plates.
The parallel method of adjustment step of a kind of light of the present utility model is:
(1) the collimation laser device sends stabilized lasers by the polarizing beam splitter beam split, is divided into perpendicular linear polarization S and parallel lines polarization P laser;
(2) block the transmitted light P of polarizing beam splitter with cardboard, make perpendicular linear polarization laser S see through λ/4 wave plates, become circularly polarized light, incide on the plane mirror, wherein the fast axle of λ/4 wave plates is at 45 with the S polarization direction;
(3) adjusting plane mirror makes reverse the returning of circular polarization light see through λ/4 wave plates for the second time, this moment, light became linearly polarized light by circularly polarized light, but the polarization direction has rotated 90 °, therefore light sees through polarizing beam splitter and lens, incide in the detection, and make light incide the center of detector, take reading;
(4) keep plane mirror motionless, cardboard is taken away, be placed on the reflected light S that blocks polarizing beam splitter on the reflected light path of polarizing beam splitter;
(5) the transmitted light P of polarizing beam splitter sees through another one λ/4 wave plates, and the plane reflection mirror reflection by can two-dimensional adjustment is incided on the above-mentioned fixed plane mirror light again.Wherein the fast axle of λ/4 wave plates is at 45 with the P polarization direction, and the polarized light that sees through this λ/4 wave plates also becomes circularly polarized light;
(6) fixed catoptron makes that circular polarization light is reverse to be returned, plane reflection mirror reflection through the two-dimensional adjustable joint, see through λ/4 wave plates for the second time, make circularly polarized light become linearly polarized light, but its direction of vibration has rotated 90 °, therefore light sees through lens through the polarizing beam splitter reflection, incides on the detector;
(7) regulate the two-dimensional adjustable plane mirror, make the reverse position readings that incides the luminous point on the detector identical with the above-mentioned reading of writing down;
(8) withdraw above-described cardboard and the fixed pan catoptron of being in the light, then two outgoing light are parallel rays.
Described method can produce the multi beam parallel rays by the reflection direction of adjusting the polarizing beam splitter that increases.
The utility model is that a kind of being applicable to produces two parallel ray beams, has following advantage:
1, adjusting gear and method are simple, and cost is lower.
2, adjust the precision height, utilize the high stable collimation laser can adjust between the light collimation below 1 second of arc.
3, utilize the method can also adjust two bundles with the collimation between the glazed thread.
Description of drawings
Further specify the utility model below in conjunction with the drawings and specific embodiments.
Fig. 1 is for adjusting the embodiment one of parallel beam light.
Fig. 2 is angle measuring principle figure.
Fig. 3 is for adjusting the embodiment two of two-beam line parallel.
Fig. 4 is for adjusting the embodiment three of three-beam line parallel simultaneously.
Among the figure: 1-is the collimation laser instrument; 2-is a polarizing beam splitter; 3,4-is λ/4 wave plates; 5-is the facet catoptron; 6-is the two-dimensional adjustment device; 7-is convex lens; 8-is a 4 quadrant detector; 9-is big plane mirror; 10-is semi-transparent semi-reflecting optical splitter; 11-is a polarizing beam splitter.
Embodiment
Further specify the utility model below in conjunction with accompanying drawing.
Fig. 1 is for adjusting the principle device of two parallel ray beams.Collimation laser device 1 sends stabilized lasers by polarizing beam splitter 2 beam split, is divided into perpendicular linear polarization S and parallel lines polarization P laser.Block the transmitted light P of polarizing beam splitter with cardboard, make perpendicular linear polarization laser S see through λ/4 wave plates 3, become circularly polarized light, incide on the plane mirror 9, wherein the fast axle of λ/4 wave plates 3 is at 45 with the S polarization direction.Adjusting plane mirror 9 makes reverse the returning of circular polarization light see through λ/4 wave plates 3 for the second time, this moment, light became linearly polarized light by circularly polarized light, but the polarization direction has rotated 90 °, therefore light sees through polarizing beam splitter 2 and lens 7, incide on the 4 quadrant detector 8, and make light incide the center of detector 8, take reading.Keep plane mirror 9 motionless, cardboard is taken away, be placed on the reflected light S that blocks polarizing beam splitter 2 on the reflected light path of polarizing beam splitter 2.The transmitted light P of polarizing beam splitter 2 sees through another one λ/4 wave plates 4, and the plane mirror 5 by can two-dimensional adjustment reflects again, and plane mirror 5 is fixed on the two-dimensional adjustment device 6, and light is incided on the above-mentioned fixed plane mirror 9.Wherein the fast axle of λ/4 wave plates 4 is at 45 with the P polarization direction, and the polarized light that sees through this λ/4 wave plates 4 also becomes circularly polarized light.Fixed catoptron 9 makes that circular polarization light is reverse to be returned, plane mirror 5 reflections through the two-dimensional adjustable joint, see through λ/4 wave plates 4 for the second time, make circularly polarized light become linearly polarized light, but its direction of vibration has rotated 90 °, therefore light sees through lens 7 through polarizing beam splitter 2 reflections, incides on the 4 quadrant detector 8.Regulate two-dimensional adjustable plane mirror 5, make the reverse position readings that incides the luminous point on the detector 8 identical with the above-mentioned reading of writing down.Withdraw above-described cardboard and the fixed pan catoptron 9 of being in the light, then two outgoing light are parallel rays.
Twice light take measurement of an angle principle as shown in Figure 2, detector 8 is placed on the focal plane of lens 7, when incident ray departed from lens 7 optical axis θ, luminous point had the skew of displacement d on detector, then the light deviation angle is:
tgθ=d/f (1)
Fig. 3 is for adjusting the embodiment two of two-beam line parallel, and with respect to embodiment one (Fig. 1), Fig. 3 has lacked two λ/4 wave plates, and polarizing beam splitter 2 is replaced by unpolarized semi-transparent semi-reflecting optical splitter 10.The concrete parallel focusing process of light is: collimation laser device 1 sends stabilized lasers by semi-transparent semi-reflecting optical splitter 10 beam split, is divided into reflected light and transmitted light.Block transmitted light with cardboard, reflected light is incided on the plane mirror 9.Adjust plane mirror 9 and make that light is reverse to turn back to semi-transparent semi-reflecting optical splitter 10, this moment, light was divided equally by semi-transparent semi-reflecting optical splitter 10 once more, and wherein transmitted light sees through lens 7, incides on the detector 8, and make light incide the center of 4 quadrant detector 8, take reading.Keep plane mirror 9 motionless, cardboard is taken away, be placed on the reflected light path of optical splitter 10, block the reflected light of optical splitter 10.Plane mirror 5 reflections of the transmitted light of optical splitter 10 by can two-dimensional adjustment, plane mirror 5 is fixed on the two-dimensional adjustment device 6, and light is incided on the above-mentioned fixed plane mirror 9.Fixed catoptron 9 makes that light is reverse to be returned, and through plane mirror 5 reflections of two-dimensional adjustable joint, incides on the optical splitter 10, and light passes through semi-transparent semi-reflecting optical splitter 10 beam split once more, and wherein reflected light sees through lens 7, incides on the 4 quadrant detector 8.Regulate two-dimensional adjustable plane mirror 5, make the reverse position readings that incides the luminous point on the detector 8 identical with the above-mentioned reading of writing down.Withdraw above-described cardboard and the fixed pan catoptron 9 of being in the light, then two outgoing light are parallel rays.
Fig. 4 is for adjusting the embodiment of three-beam line parallel simultaneously.This embodiment has increased a polarizing beam splitter 11 on Fig. 1 basis.Collimation laser device 1 sends stabilized lasers by polarizing beam splitter 2 beam split, is divided into perpendicular linear polarization S and parallel lines polarization P laser.Block the transmitted light P of polarizing beam splitter with cardboard, make perpendicular linear polarization laser S see through λ/4 wave plates 3, become circularly polarized light, incide on the plane mirror 9, wherein the fast axle of λ/4 wave plates 3 is at 45 with the S polarization direction.Adjusting plane mirror 9 makes reverse the returning of circular polarization light see through λ/4 wave plates 3 for the second time, this moment, light became linearly polarized light by circularly polarized light, but the polarization direction has rotated 90 °, therefore light sees through polarizing beam splitter 2 and lens 7, incide on the 4 quadrant detector 8, and make light incide the center of detector 8, take reading.Keep plane mirror 9 motionless, cardboard is taken away, be placed on the reflected light S that blocks polarizing beam splitter 2 on the reflected light path of polarizing beam splitter 2.Through λ/4 wave plates 4, wherein the fast axle of λ/4 wave plates 4 is at 45 with the P polarization direction from polarizing beam splitter 2 transmitted light P, and when light saw through λ/4 wave plates 4, light became circularly polarized light by linearly polarized laser.Circularly polarized laser is divided into two orthogonal linearly polarized lasers through polarizing beam splitter 11, and wherein reflected light is a S ' linear polarization, and transmitted light is a P ' linear polarization.Block the transmitted light P ' of polarizing beam splitter 11 back again with an other cardboard.Reflected light S ' incides on the fixed pan catoptron 9, and catoptron 9 makes the light retrodirective reflection to polarizing beam splitter 11, through polarizing beam splitter 11 reflections, sees through λ/4 wave plates 4 once more, and linearly polarized light becomes circularly polarized light.Circularly polarized light is through polarizing beam splitter 2 beam split, and reflected light sees through lens 7, incides on the 4 quadrant detector 8.Adjust the reflection direction of polarizing beam splitter 11, make the reading that incides on the 4 quadrant detector 8 with reading is identical for the first time.At this moment the first bundle light S is parallel with the second bundle light S '.Behind polarizing beam splitter 11, withdraw second block of cardboard, be placed on the reflected light S ' of polarizing beam splitter 11, block the light that returns.Transmitted light P ' behind the polarizing beam splitter 11 is incided on the stationary mirror 9 through plane mirror 5.Stationary mirror 9 makes that light is reverse to be returned, and through plane mirror 5 reflections, sees through polarizing beam splitter 11 and λ/4 wave plates 4, and at this moment linearly polarized laser also becomes circularly polarized light.Circularly polarized laser is through polarizing beam splitter 2 beam split, and wherein reflected light sees through lens 7, incides on the 4 quadrant detector 8.Adjust plane mirror 5 reflection directions, make the reading that incides on the 4 quadrant detector 8 with reading is identical for the first time.At this moment the first bundle light S is parallel with three beams light P '.。Withdraw above all be in the light cardboard and fixed pan catoptrons 9, then the three beams emergent ray is a parallel rays.In like manner can also carry out parallel rays adjustment more than the three beams by increasing polarizing beam splitter and λ/4 wave plates.
Claims (6)
1, the device of the parallel adjustment of a kind of light, it is characterized in that: collimation laser device (1) sends the collimation laser of high stability, through polarizing beam splitter (2) beam split, on the reflected light path of polarizing beam splitter (2), place λ/4 wave plates (3), λ/the quick shaft direction of 4 wave plates (3) and the polarization direction of laser are at 45, incide on the plane mirror (9) again; And on the transmitted light path of polarizing beam splitter (2), place another one λ/4 wave plates (4), λ/the quick shaft direction of 4 wave plates (4) and the polarization direction of laser are also at 45, again by a two-dimensional adjustable plane mirror (5) reflection, make that its reflection direction is parallel with the reflected light of polarizing beam splitter (2) to be incided on the same plane mirror (9); Plane mirror (9) makes the reverse polarizing beam splitter (2) that turns back to of two light; Because two light beams see through λ/4 wave plates (3,4) twice respectively, the direction of vibration of light has rotated 90 ° respectively, and therefore original reflected light through polarizing beam splitter (2) becomes transmitted light, and the transmitted light that passes through polarizing beam splitter (2) originally becomes reflected light; Incide on the same detector (8) by lens (7).
2, device as claimed in claim 1 is characterized in that: described collimation laser device (1) is semiconductor laser or gas laser through the single-mode fiber collimation.
3, device as claimed in claim 1 is characterized in that: described detector (8) is 4 quadrant detector or Position-Sensitive Detector or CCD.
4, device as claimed in claim 1 is characterized in that: described detector (8) is placed on lens (7) focal plane.
5, device as claimed in claim 1 is characterized in that: described lens (7) are lens combination.
6, device as claimed in claim 1 is characterized in that: described device produces the multi beam parallel rays by increasing polarizing beam splitter and λ/4 wave plates.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CNU200820078801XU CN201210201Y (en) | 2008-01-29 | 2008-01-29 | Light ray parallel adjusting apparatus |
Applications Claiming Priority (1)
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CNU200820078801XU CN201210201Y (en) | 2008-01-29 | 2008-01-29 | Light ray parallel adjusting apparatus |
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CN201210201Y true CN201210201Y (en) | 2009-03-18 |
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CNU200820078801XU Expired - Lifetime CN201210201Y (en) | 2008-01-29 | 2008-01-29 | Light ray parallel adjusting apparatus |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103398676A (en) * | 2013-08-13 | 2013-11-20 | 中航虹波风电设备有限公司 | Detection method for parallelism and coaxiality of flanges at two ends of pylon |
CN109752858A (en) * | 2019-03-18 | 2019-05-14 | 贵州航天电子科技有限公司 | A kind of linearly polarized laser transmitting optics |
CN111384655A (en) * | 2020-03-25 | 2020-07-07 | 龙天洋 | Self-feedback high-stability laser pulse compressor |
-
2008
- 2008-01-29 CN CNU200820078801XU patent/CN201210201Y/en not_active Expired - Lifetime
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103398676A (en) * | 2013-08-13 | 2013-11-20 | 中航虹波风电设备有限公司 | Detection method for parallelism and coaxiality of flanges at two ends of pylon |
CN109752858A (en) * | 2019-03-18 | 2019-05-14 | 贵州航天电子科技有限公司 | A kind of linearly polarized laser transmitting optics |
CN111384655A (en) * | 2020-03-25 | 2020-07-07 | 龙天洋 | Self-feedback high-stability laser pulse compressor |
CN111384655B (en) * | 2020-03-25 | 2023-03-14 | 龙天洋 | Self-feedback high-stability laser pulse compressor |
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Legal Events
Date | Code | Title | Description |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
AV01 | Patent right actively abandoned |
Granted publication date: 20090318 Effective date of abandoning: 20080129 |