CN209230522U - Optical position detection device - Google Patents
Optical position detection device Download PDFInfo
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- CN209230522U CN209230522U CN201822088095.3U CN201822088095U CN209230522U CN 209230522 U CN209230522 U CN 209230522U CN 201822088095 U CN201822088095 U CN 201822088095U CN 209230522 U CN209230522 U CN 209230522U
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- microscope group
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Abstract
This application discloses a kind of optical position detection device, which includes: to detect light source and the diaphragm set gradually along the imaging optical path for detecting light source, projection microscope group, imaging amplification microscope group and detector, wherein detection light source is point light source or linear light source;Microscope group is projected, the light beam from diaphragm is incident on to the surface to be measured of workpiece with certain inclination angle;Imaging amplification microscope group is incident to detector after the reflected beams on surface to be measured can be carried out to 2 grades of amplification imagings.The detection device of the utility model, using independent imaging optical path, edge contour is apparent, detection accuracy is higher, while the oblique incidence mode of different angle can be used, and can avoid the spatial position that other optical paths occupy, and device is simple and reliable, it is low in cost, the change in location of workpiece surface can be amplified 30~160 times, the position detection of submicron order may be implemented.
Description
Technical field
This application involves optical processing technology fields, more particularly to a kind of optical position detection device.
Background technique
Optical position detection method has many advantages, such as non-contact, high-precision and response quickly, is widely used in location control
With the fields such as product Shape measure.
There are many existing optical position detection methods: (also referred to as confocal method, it is micro- to be more common in confocal laser to confocal method
Mirror), trigonometry (being widely adopted in current commercial laser displacement sensor), interferometry (such as double-frequency laser interference
Instrument), (servo-focus of CD-ROM drive is also used for precision optics processing, such as patent i.e. using changing method to method of astigmatism
201010170978.4) etc..
In a special case, above method is difficult to meet demand.Such as: there are other optical paths to occupy workpiece to be measured
The surface of position, optical path position is occupied at this time, and technical solution can not be implemented.
In order to solve the problems, such as that optical path position has been occupied, Chinese Patent No. 201811053107.7 disclose a kind of light
Position detecting device and method are learned, light source is using collimated light beam, the prism geometry amplification that provides, it is necessary to 60 degree
Based on the above glancing incidence, otherwise enlargement ratio is greatly reduced.And glancing incidence have the shortcomings that 2 it is obvious:
1, irradiated area is big, is easy to be influenced by dust and detection surface undulation;
2, when work surface location changes up and down, the region left and right offset therewith of detection light irradiation may deviate predetermined
Detection position.
Utility model content
The purpose of this utility model is to provide a kind of optical position detection devices, to overcome deficiency in the prior art.
To achieve the above object, the utility model provides the following technical solutions:
The embodiment of the present application discloses a kind of optical position detection device, including detection light source and along the imaging of detection light source
Diaphragm, projection microscope group, imaging amplification microscope group and the detector that optical path is set gradually, wherein
Detecting light source is point light source or linear light source;
Microscope group is projected, the light beam from diaphragm is incident on to the surface to be measured of workpiece with certain inclination angle;
Imaging amplification microscope group, is incident to detector after the reflected beams on surface to be measured can be amplified to imaging.
Preferably, in above-mentioned optical position detection device, a processing space is defined, which waits for positioned at workpiece
Surface vertical direction is surveyed,
The detection light source, diaphragm, projection microscope group, imaging amplification microscope group and detector are respectively positioned on outside the processing space.
Preferably, in above-mentioned optical position detection device, the detection light source, diaphragm, projection microscope group are located at described
The side of processing space,
Imaging amplification microscope group and detector are located at the other side of the processing space.
Preferably, in above-mentioned optical position detection device, imaging amplification microscope group include along imaging optical path successively
The enlargement ratio of the 1st grade of amplification microscope group and the 2nd grade of amplification microscope group being arranged, the 2nd grade of amplification microscope group is greater than the 1st grade of magnifying glass
The enlargement ratio of group.
Preferably, in above-mentioned optical position detection device, the 1st grade of amplification microscope group uses object space telecentric beam path.
Preferably, in above-mentioned optical position detection device, the enlargement ratio of the 1st grade of amplification microscope group is 3~4
Times, preferably 3 times.
Preferably, in above-mentioned optical position detection device, the enlargement ratio of the 2nd grade of amplification microscope group is 5~20
Times, preferably 6 times.
Preferably, in above-mentioned optical position detection device, it is arranged between the 1st grade of amplification microscope group and the workpiece for measurement
There is the second reflecting mirror;The projection microscope group includes the lens/lens group set gradually along imaging optical path and the first reflecting mirror.
Preferably, in above-mentioned optical position detection device, the diaphragm is aperture or slit diaphragm.
Compared with the prior art, the advantages of the utility model are:
(1) detection device and method of the utility model are examined using point light source or linear light source using imaging optical path
It surveys, after light is incident upon detector surface, the edge contour of hot spot is more clear sharp keen, and it is smart to help to obtain higher detection
Degree.
(2) detection device and method of the utility model, projecting beam can be wide-angle glancing incidence, be also possible to smaller
Angle, enlargement ratio is unaffected, thus applicable situation is wider.
(3) detection device and method of the utility model can avoid the spatial position that other optical paths occupy, and device
It is simple and reliable, it is low in cost, the change in location of workpiece surface can be amplified 30~160 times, the position of submicron order may be implemented
Set detection.
Detailed description of the invention
In order to illustrate the technical solutions in the embodiments of the present application or in the prior art more clearly, to embodiment or will show below
There is attached drawing needed in technical description to be briefly described, it should be apparent that, the accompanying drawings in the following description is only this
The some embodiments recorded in application, for those of ordinary skill in the art, without creative efforts,
It is also possible to obtain other drawings based on these drawings.
Fig. 1 show the structural schematic diagram of optical position detection device in the utility model specific embodiment;
Fig. 2 show optical path in the utility model specific embodiment and shows in the detail structure that workpiece for measurement surface is imaged
It is intended to;
Fig. 3 show the reflection image s of imaging optical path s in the utility model specific embodiment1And s2Subsequent central light pass
Defeated detail view.
Specific embodiment
The following will be combined with the drawings in the embodiments of the present invention, carries out the technical scheme in the embodiment of the utility model
In detail, it is fully described by, it is clear that the described embodiments are only a part of the embodiments of the utility model, rather than whole
Embodiment.Based on the embodiments of the present invention, those of ordinary skill in the art are in the premise for not making creative work
Under every other embodiment obtained, fall within the protection scope of the utility model.
It is in the description of the present invention, it should be noted that term " center ", "upper", "lower", "left", "right", " perpendicular
Directly ", the orientation or positional relationship of the instructions such as "horizontal", "inner", "outside" is to be based on the orientation or positional relationship shown in the drawings, and is only
For ease of description the utility model and simplify description, rather than the device or element of indication or suggestion meaning must have it is specific
Orientation, be constructed and operated in a specific orientation, therefore should not be understood as limiting the present invention.In addition, term " the
One ", " second ", " third " are used for descriptive purposes only and cannot be understood as indicating or suggesting relative importance.
In the description of the present invention, it should be noted that unless otherwise clearly defined and limited, term " is pacified
Dress ", " connected ", " connection " shall be understood in a broad sense, for example, it may be being fixedly connected, may be a detachable connection, or integrally
Connection;It can be mechanical connection, be also possible to be electrically connected;Can be directly connected, can also indirectly connected through an intermediary,
It can be the connection inside two elements.For the ordinary skill in the art, above-mentioned art can be understood with concrete condition
The concrete meaning of language in the present invention.
As shown in connection with fig. 1, in the embodiment of the application, a kind of optical position detection device is provided, using optics hand
Whether the roughness or positional fluctuation on section detection 10 surface of workpiece meet processing request.
A processing space 20 is defined first, which is located at workpiece surface vertical direction to be measured, it is furthermore preferred that
The space of the entire vertical direction in 10 surface of workpieces processing is processing space 20.Other optical paths 30 can be set in the processing space, than
Such as it is cut by laser optical path, semiconductor lithography optical path.
Optical position detection device is optical path independently of optical path 30, being exclusively used in the detection of 10 surface location of workpiece, due to
Its independence can be used in different optical devices, do not need to reequip original optical device, also do not need to borrow
With the original optical element of optical device.
Interference in order to avoid optical position detection device to original optical device, optical position detection device, which is set to, to be added
The outside in work space 20, the input path generated is from the side oblique incidence of processing space 20, and from the another of processing space 20
Side inclination is projected.
In one embodiment, optical position detection device includes detection light source 401, and detection light source 401 can be point light source,
It may be linear light source, to generate the incident light 403 for workpiece surface detection.
In a preferred embodiment, detection light source 401 can be laser diode, LED or He-Ne laser etc., light source
Wavelength is generally higher than 450nm, and luminous power is weaker.
Optical position detection device includes the diaphragm 402 along imaging optical path setting, specially aperture or slit light
Door screen, for constructing imaging optical path, diaphragm 402 is placed in the vertical lower of detection light source 401.
In one embodiment, diaphragm 402 is the diaphragm using roundlet hole shape, diameter 200um;The illumination of diaphragm
Light (incident light) uses the crosslights of low-angle to illuminate to promote edge imaging quality;The illuminating ray angle of divergence is less than 5 degree.
Optical position detection device further includes the projection microscope group along imaging optical path setting, including is set gradually along imaging optical path
Lens/lens group 404 and the first reflecting mirror 405, for the incident beam projection imaging of self-test light source in future 401, projection
Microscope group is set to the underface of diaphragm 402.
In one embodiment, the lens/lens group 404 projected in microscope group uses 1 times of optical path, with least cost obtains
Obtain higher image quality.
Incident light 403 from detection light source 401 preferably projects vertically downwards, passes through aperture or slit
It is radiated at after diaphragm in lens/lens group 404 of projection microscope group.
First reflecting mirror 405 is set to the underface of lens/lens group 404, with certain inclination angle be incident on workpiece 10 to
It surveys surface and specifies areas adjacent (can be top, can also be lower section).
In the technical solution, detection light source 401, diaphragm 402, lens/lens group 404 and the first reflecting mirror 405 are set to
The same side of processing space 20, detection light source 401, diaphragm 402, lens/lens group 404 and the first reflecting mirror 405 are successively by suitable
Sequence is setting up and down, can reduce the occupancy of horizontal space.
Optical position detection device further includes imaging amplification microscope group, and the reflected beams on surface to be measured can be carried out to 2 grades of imagings
Detector 409 is incident to after amplification.
Imaging amplification microscope group and detector 409 are located at the same side of processing space 20, and are in opposite with detection light source 401
Side.
In one embodiment, detector 409 is CCD, unit size about 10um, number of unit 1600*1200, width
Face is 16mm*12mm.
Imaging amplification microscope group includes the second reflecting mirror 406 set gradually in light path, the 1st grade of amplification microscope group 407
It is greater than the enlargement ratio of the 1st grade of amplification microscope group with the enlargement ratio of the 2nd grade of amplification microscope group 408, the 2nd grade of amplification microscope group 408
407.The 1st grade of amplification microscope group uses object space telecentric beam path.
1st grade of amplification microscope group can tentatively be amplified the reflected beams on surface to be measured, and specific enlargement ratio is 3~4 times,
Preferably 3 times.
Second reflecting mirror 406 from the reflected light on the surface to be measured of workpiece 10 will reflex to along the vertical direction the 1st grade and put
Big microscope group 407.
The imaging optical path tentatively amplified by the 1st grade of amplification microscope group can be further amplified for 2nd grade of amplification microscope group 408.
Further, the imaging optical path of entrance can be further amplified 5~20 times or so by the 2nd grade of amplification microscope group 408,
Preferably 6 times.
In the technical solution, the installation space of 10 surrounding of workpiece is limited, for the purposes of avoiding the occupancy of horizontal space, detection
Device 409, the 2nd grade of amplification microscope group 408, the 1st grade of amplification microscope group 407 and the second reflecting mirror 406 are set gradually up and down in order.
2 grades of amplifications for amplifying microscope group and the 2nd grade of amplification microscope group by the 1st grade, the change in location of workpiece surface can be put
It is 30~160 times big, the position detection of submicron order may be implemented, precision is high.
Referring to shown in Fig. 2, aperture or slit diaphragm (diaphragm 402) are detected light source 401 and illuminate, incident light 403
The specified areas adjacent in the surface to be measured of workpiece 10 (can be top, can also be lower section) is projected into real image, note by projecting microscope group
Make s, surface to be measured is approximately mirror surface, to s at virtual image s1, the shape after the surface reflection to be measured of workpiece 10 of incident light 403 at this time
At reflection light 403a, it should be noted that in order to protrude testing principle, the center light of reflection light is only depicted in figure
Line eliminates other light, as shown in Figure 3;After upper and lower position variation occurs for the surface to be measured of workpiece 10, s1It is moved to s2, at this time
Incident light 403 forms reflection light 403b after the surface reflection to be measured of workpiece 10, equally, reflected light is only depicted in figure
The central ray of line.
After two beam reflection lights are reflected by the second reflecting mirror 406, by the 1st grade of amplification microscope group 407 and the 2nd grade of magnifying glass
After 408 amplification imaging of group, it is projected to 409 surface of detector, corresponding position s1' and s2', the displacement signal on workpiece for measurement surface
Detector detection virtual image s can be converted to1' and s2' change in displacement.
In order to realize good imaging effect, ideally, s1To s2Line should be vertical with primary optical axis, so that
s1To s2It is respectively positioned on the object plane of the 1st grade of amplification microscope group 407.And above-mentioned vertical relation is difficult to meet under actual conditions, projecting beam
Incident angle is bigger, about close with ideal situation.In order to solve this problem, the 1st grade of amplification microscope group 407 uses object space telecentricity light
Road, so that s1To s2Even if deviating object plane, the lateral position of imaging thereafter is nor affected on, to guarantee measurement accuracy.
Testing principle explanation: the change in location of workpiece surface is eventually converted into diaphragm aperture (or slit) in detector
The picture point center variation of surface imaging, it is unrelated with the size of picture point.
Due to the limitation of installation space, s1And s2The 1st grade of amplification microscope group 407 of distance farther out, thus it is preferred 1st grade amplification
Low enlargement ratio in the use of microscope group 407.To obtain longer operating distance.Correspondingly, the 2nd grade of amplification microscope group 408 can be used
Magnification at high multiple multiplying power, but its enlargement ratio is limited by 409 size of detector.
The geometry enlargement ratio of the optical position detection device of the application consists of three parts:
(1), surface to be measured is approximately mirror surface, as moving distance be 2 times of mirror surface moving distance.
(2), the enlargement ratio of the 1st grade of amplification microscope group 407.
(3), the enlargement ratio of the 2nd grade of amplification microscope group 408.
In one embodiment:
Diaphragm of the diaphragm 402 using roundlet hole shape, diameter 200um;
The incident light 403 that the illumination detection light source 401 of diaphragm is issued, is illuminated using the crosslights of low-angle, to mention
Edge imaging quality is risen, and the illuminating ray angle of divergence is less than 5 degree.
Lens/the lens group 404 projected in microscope group uses 1 times of optical path, with least cost obtains higher image quality.
The enlargement ratio of 1st grade of amplification microscope group 407 is 3 times, and the enlargement ratio of the 2nd grade of amplification microscope group 408 is 6 times.
Detector 409 is CCD, unit size about 10um, number of unit 1600*1200, breadth 16mm*12mm.
Incident light passes through above-mentioned circular hole diaphragm, is irradiated into lens/lens group 404, passes through the throwing of lens/lens group 404
Shadow imaging in the surface to be measured of workpiece 10 and forms real image s by the reflection of the first reflecting mirror 405, is similar to mirror surface with surface to be measured,
To s at virtual image s1, and form reflection light 403a.After upper and lower position variation occurs for surface to be measured, s1It is moved to s2, it is formed simultaneously
Reflection light 403b, above two reflection light after the reflection of the second reflecting mirror 406 vertically into the 1st grade of amplification microscope group 407,
3 times of amplifications are carried out, preliminary amplified light is again introduced into the 2nd grade of amplification microscope group, is further amplified 6 times, and after imaging
It is projected to 409 surface of detector, corresponding position s1' and s2', the change in location of workpiece surface is eventually converted into diaphragm 402 and exists
Picture point, that is, s of 409 surface of detector imaging1' and s2' center variation.
By above-mentioned setting and detection, the system overall geometry enlargement ratio value of this optical position detection is 2*3*6=36
Times.Meanwhile it is 0.2*36=7.2mm that diaphragm circular hole, which is incident upon the size on 409 surface of detector,.This system height detection range is
(16mm-7.2mm)/36 ≈ 0.25mm, simultaneity factor detection resolution are 10um/36=0.28um.
In conclusion the detection device and method of the utility model, using independent imaging optical path, edge contour is more clear
Clear, detection accuracy is higher, while the oblique incidence mode of different angle can be used, and can avoid the space bit that other optical paths occupy
It sets, and device is simple and reliable, it is low in cost.
Finally, it should be noted that the above various embodiments is only to illustrate the technical solution of the utility model, rather than it is limited
System;Although the present invention has been described in detail with reference to the aforementioned embodiments, those skilled in the art should
Understand: it is still possible to modify the technical solutions described in the foregoing embodiments, or to some or all of
Technical characteristic is equivalently replaced;And these are modified or replaceed, it does not separate the essence of the corresponding technical solution, and this is practical new
The range of each embodiment technical solution of type.
Claims (11)
1. a kind of optical position detection device, which is characterized in that including detection light source and along detection light source imaging optical path according to
Diaphragm, projection microscope group, imaging amplification microscope group and the detector of secondary setting, wherein
Detecting light source is point light source or linear light source;
Microscope group is projected, the light beam from diaphragm is incident on to the surface to be measured of workpiece with certain inclination angle;
Imaging amplification microscope group, is incident to detector after the reflected beams on surface to be measured can be amplified to imaging.
2. optical position detection device according to claim 1, which is characterized in that define a processing space, the processing is empty
Between be located at workpiece surface vertical direction to be measured,
The detection light source, diaphragm, projection microscope group, imaging amplification microscope group and detector are respectively positioned on outside the processing space.
3. optical position detection device according to claim 2, which is characterized in that the detection light source, diaphragm, projection lens
Group is located at the side of the processing space,
Imaging amplification microscope group and detector are located at the other side of the processing space.
4. optical position detection device according to claim 1, which is characterized in that imaging amplification microscope group include along at
The enlargement ratio of the 1st grade of amplification microscope group and the 2nd grade of amplification microscope group set gradually as optical path, the 2nd grade of amplification microscope group is greater than
The enlargement ratio of 1st grade of amplification microscope group.
5. optical position detection device according to claim 4, which is characterized in that the 1st grade of amplification microscope group uses object
Square telecentric beam path.
6. optical position detection device according to claim 4, which is characterized in that the amplification of the 1st grade of amplification microscope group
Multiplying power is 3~4 times.
7. optical position detection device according to claim 6, which is characterized in that the amplification of the 1st grade of amplification microscope group
Multiplying power is 3 times.
8. optical position detection device according to claim 4, which is characterized in that the amplification of the 2nd grade of amplification microscope group
Multiplying power is 5~20 times.
9. optical position detection device according to claim 8, which is characterized in that the amplification of the 2nd grade of amplification microscope group
Multiplying power is 6 times.
10. optical position detection device according to claim 4, which is characterized in that the 1st grade of amplification microscope group with it is to be measured
The second reflecting mirror is provided between workpiece;The projection microscope group includes the lens/lens group set gradually along imaging optical path and
One reflecting mirror.
11. optical position detection device according to claim 1, which is characterized in that the diaphragm is aperture or narrow
Stitch diaphragm.
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CN109443210A (en) * | 2018-12-13 | 2019-03-08 | 苏州亿拓光电科技有限公司 | Optical position detection device and method |
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CN109443210A (en) * | 2018-12-13 | 2019-03-08 | 苏州亿拓光电科技有限公司 | Optical position detection device and method |
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