CN100480624C - Optical scanning outside diameter measuring system without scanning objective lens and measuring method thereof - Google Patents
Optical scanning outside diameter measuring system without scanning objective lens and measuring method thereof Download PDFInfo
- Publication number
- CN100480624C CN100480624C CNB2003101117512A CN200310111751A CN100480624C CN 100480624 C CN100480624 C CN 100480624C CN B2003101117512 A CNB2003101117512 A CN B2003101117512A CN 200310111751 A CN200310111751 A CN 200310111751A CN 100480624 C CN100480624 C CN 100480624C
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- Prior art keywords
- scanning
- mirror
- outside diameter
- diameter measuring
- measuring system
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Abstract
The invention is a kind of optical scanning external diameter measuring system which hasn't the scanning object lens and the measuring method. The system is made up of two or more optical scanning units without scanning object lens, each unit is assembled with any angle, each unit is made up by connecting light source, collimating mirror, scanning rotary mirror, the receiving object lens, photoelectric receiver. The photoelectric receiver connects with computer through wires. The method uses any two units as a group, the distance between the scanning mirror and the reflection centre point is l0, the offset centre angle to light of the measured object are 2theta 1 and 2 theta 2, the line between the object gravity center and the scanning mirror reflection centre point are alpha 1, alpha 2, the diameter is d: d= dkl0 according to following method, k= 1/(cos alpha 1/ sin theta 1 + cos alpha 2/ sin theta 2). The invention has no object lens, the producing is easy, it realiezes the computer digit compensate for system difference, the stability is good, it has high reliability, the assemble and maintaining is easy, the cost is low.
Description
Technical field
The present invention relates to the geometric measurement equipment technical field, specifically be meant a kind of optical scanning outside diameter measuring system and measuring method thereof of object scanning lens free.
Background technology
Existing optical scanning outside diameter measuring system is made up of light source, collimating mirror, reflection tilting mirror, scanning objective, receiving objective and photoelectric device, its course of work is: the light that light source sends is behind the collimating mirror collimation, be incident upon and become deflection light on the deflecting mirror, be scanning survey light again behind scanning objective, the scanning ray measured object blocks the formation shade, receive and measurement shade width, can obtain object size.Prior art manufacture and design with practicality in have a following problem:
1. the scanning system precision depends primarily on the processing and the installation accuracy of high-precision scanning objective, and on the principle scheme, owing to existing the error that exists because of scanning objective design, manufacturing to be difficult to full remuneration, the range of dynamic measurement under the high precision prerequisite is limited.
2. difficulty is all compared in above-mentioned scanning objective design, manufacturing and assembling, so production efficiency is low, manufacturing cost is high, has limited the equipment promotion use.
3. when system used, because influence of temperature change scanning objective precision, system was to the environmental requirement height during actual the use, and in general production environment, system reliability is not high.
4. measurement range is limited by the scanning objective size, and range extension has big difficulty.
Summary of the invention
Purpose of the present invention is exactly in order to solve above-mentioned the deficiencies in the prior art part, a kind of optical scanning outside diameter measuring system and measuring method thereof of object scanning lens free are provided, this system's manufacture craft is simple, Installation and Debugging make things convenient for, expand measurement range easily, and the good ratio of performance to price makes it can more effectively extend to the detection control procedure of all kinds of wire production.
The optical scanning outside diameter measuring method of a kind of object scanning lens free of the present invention is characterized in that, adopting any two or more light scanning units is one group, constitutes measuring system, the scanning testee; Each light scanning unit is interconnected successively by light source, collimating mirror, scanning mirror, receiving objective, photelectric receiver to be formed, and does not have scanning objective; Each unit is relatively or by arbitrarily angled installation; If the distance between two scanning mirror reflection kernels or the equivalent central point is l
0, testee is respectively 2 θ to light deflection center subtended angle
1, 2 θ
2, between testee center and two scanning mirror reflection kernels or the equivalent central point between line and scanning mirror reflection kernel or the equivalent central point angle of line be respectively α
1, α
2, by measuring l
0, θ
1, θ
2, α
1, α
2, obtain the testee diameter d in the following manner:
Be d=2kl
0, wherein, k=1/ (cos α
1/ sin θ
1+ cos α
2/ sin θ
2).
In order to realize the present invention better, can take multiple measurements sampling by following manner, determine α
1, α
2:
Be sin θ
1Sin α
1=sin θ
2Sin α
2
The optical scanning outside diameter measuring system of a kind of object scanning lens free of the present invention, it is characterized in that, it is made of the light scanning unit of two object scanning lens frees, Unit two are relatively or by arbitrarily angled installation, each unit is interconnected successively by light source, collimating mirror, scanning mirror, receiving objective, photelectric receiver to be formed, do not have scanning objective, photelectric receiver also is connected with computing machine by signal wire.
In order to realize the present invention better, between described scanning mirror and the receiving objective plane mirror is installed; Described receiving objective is reflective or refraction type or the two combination; Install the protective device of optical filter or proofing dust and protecting glass or other transparent material making or the combination of said apparatus before the described photelectric receiver additional; Described scanning mirror has one or more, and scanning mirror has one or more reflectings surface, and the protective device that proofing dust and protecting glass or other transparent material are made is installed before or after the described scanning mirror; Described light source is LASER Light Source or led light source.
The present invention uses two-way (multichannel) measurement scheme, can effectively eliminate the influence of the errors of principles on the theory and technology, avoid the difficulty that the processing of high precision linear sweep object lens, debugging and maintenance are brought in the prior art simultaneously, debugging is with easy to maintenance, can reach higher measuring accuracy (1um), manufacturing cost reduces relatively, is convenient to extend to general application scenario.
The present invention compared with prior art has following advantage and beneficial effect:
1. object scanning lens free of the present invention uses a spherical aberration to obtain the collimation lens of well-corrected, does not have off-axis aberration, analyzing spot on axle and the outer consistance of axle better, be convenient to adjust, pupil location is required to reduce relatively, make relatively easily.
2. the present invention uses two scanning element unitized constructions, does not have uncertain systematic error on the principle, does not also have the influence of scanning objective residual aberration, carries out easily than perfect system error compensation, has realized the computer numerical compensation of systematic error.
3. the present invention is not owing to there is scanning objective, the sensing ring that influence is measured is reduced few, the actual good operating stability of using, reliability improves, measure only relevant with angular velocity, and do not have direct relation with measurement field place sweep trace speed, and the sight when with tradition scanning objective being arranged is different, and the latter requires the sweep trace constant airspeed.
4. the present invention uses two-way (multichannel) Scan Architecture, effectively eliminates systematic error, can reach high measuring accuracy in bigger dynamic range, is applicable to the online detection under the general environment of plant, and stability is better.
5. Installation and Debugging of the present invention and maintenance are more simple and convenient, and when being used for the delicate metering purposes, can considering to use in opposite directions, structure (is α
i=0), can reach degree of precision, this moment, structure can be designed to the separate unit form, and Installation and Debugging are simple and fast very.
6. manufacturing cost of the present invention effectively reduces.
Description of drawings
Fig. 1 is a component units structure principle chart of the present invention;
Fig. 2 is the scanning outside diameter measuring systematic schematic diagram of being made up of two unit of the present invention;
Fig. 3 be of the present invention by two unit form but have only the scanning outside diameter measuring systematic schematic diagram of a scanning mirror;
Fig. 4 is the measuring principle figure of existing system.
Embodiment
Below in conjunction with drawings and Examples, the present invention is done detailed description further.
As shown in Figure 1, each unit is interconnected successively by light source 1, collimating mirror 2, scanning mirror 3, receiving objective 5, photelectric receiver 6 to be formed, and photelectric receiver 6 also is connected with computing machine by signal wire.Light source (LASER Light Source or led light source) 1 is incident upon on the scanning mirror 3 behind collimating mirror 2 collimations and forms scanning light beam, scanning light beam scanning testee 4 backs form the scanning shade, receive by thereafter photelectric receiver 6 through receiving objective 5, treatment circuit send computing machine after with signal Processing, constitutes elementary cell of the present invention.Scanning mirror 3 has one or more reflectings surface; receiving objective 5 is reflective or refraction type or the two combination; install the protective device that optical filter or proofing dust and protecting glass or other transparent material make or the combination of said apparatus before the photelectric receiver 6 additional, install the protective device that proofing dust and protecting glass or other transparent material are made before or after the scanning mirror 3 additional.As shown in Figure 4, the present invention compares with existing system, object scanning lens free 13.
As shown in Figure 2, system of the present invention is made of two unit, i.e. two unit of light source 1, collimating mirror 2, scanning mirror 3, receiving objective 5, photelectric receiver 6 and light source 7, collimating mirror 8, scanning mirror 9, receiving objective 10, photelectric receiver 11 compositions.Relatively independent on each cellular construction, and press arbitrarily angled installation relatively or according to the triangulation principle, central processing unit (or computing machine) according to specific measurement equation, calculates compensation back output measurement result behind the measuring-signal that receives from two unit.
As shown in Figure 3, system of the present invention has introduced two plane mirrors 12, and light source 1, collimating mirror 2, scanning mirror 3 have only a cover, and measuring principle is identical with Fig. 2 with effect, and structure is compact more, can reach the measuring accuracy of higher (micron order).The compensating element, that only increases the sheet glass of character by way of compensation in scanning mirror 3 back or have slight curvature is still a kind of feasible structure.
Measuring principle of the present invention is: establishing the distance of light between two scanning mirror A, B reflection kernel point is l
0, testee is 2 θ to light deflection center subtended angle, by concerning between each geometric sense among the figure that can release the testee diameter is:
d=2kl
0 (1)
In the formula,
k=1/(cosα
1/sinθ
1+cosα
2/sinθ
2) (2)
Equation (1) is a measurement equation of the present invention.θ
1, θ
2Can directly be drawn by counting circuit, two measurement primary optical axis angles are (α
1+ α
2), when practical solution is implemented, for determining α
1, α
2, following check equations is arranged
sinθ
1sinα
1=sinθ
2sinα
2 (3)
The accurate position of decidable baseline AB, α sample by formula (3) by repeatedly measuring
1, α
2Can accurately judge thus.System's measurement of correlation data are by Computer Processing, thereby can accurately draw the testee diameter dimension quickly and easily.
The error analysis of system of the present invention:
To formula (1) the right respectively about θ
iAnd α
i(i=1,2) differential, can try to achieve because the relative error that measurement of angle causes:
Δd
αi/d=-k(sinα
i/sinθ
i)Δα
i (5)
By the ratio relation of investigation formula (5), can draw the relative weighting relation that causes the diameter measurement error under the equal angular error condition with formula (4):
As mentioned above, can realize the present invention preferably.
Claims (8)
1. the optical scanning outside diameter measuring method of an object scanning lens free is characterized in that, adopting any two or more light scanning units is one group, constitutes measuring system, the scanning testee; Each light scanning unit is interconnected successively by light source, collimating mirror, scanning mirror, receiving objective, photelectric receiver to be formed, and does not have scanning objective; Each unit is relatively or by arbitrarily angled installation; If the distance between two scanning mirror reflection kernels or the equivalent central point is l
0, testee is respectively 2 θ to light deflection center subtended angle
1, 2 θ
2, between testee center and two scanning mirror reflection kernels or the equivalent central point between line and scanning mirror reflection kernel or the equivalent central point angle of line be respectively α
1, α
2, by measuring l
0, θ
1, θ
2, α
1, α
2, obtain the testee diameter d in the following manner:
Be d=2kl
0, wherein, k=1/ (cos α
1/ sin θ
1+ cos α
2/ sin θ
2).
2. the optical scanning outside diameter measuring method of a kind of object scanning lens free according to claim 1 is characterized in that, takes multiple measurements sampling by following manner, determines α
1, α
2:
Be sin θ
1Sin α
1=sin θ
2Sin α
2
3. the optical scanning outside diameter measuring system of an object scanning lens free, it is characterized in that, it is made of the light scanning unit of two object scanning lens frees, Unit two are relatively or by arbitrarily angled installation, each unit is interconnected successively by light source, collimating mirror, scanning mirror, receiving objective, photelectric receiver to be formed, do not have scanning objective, photelectric receiver also is connected with computing machine by signal wire.
4. the optical scanning outside diameter measuring system of a kind of object scanning lens free according to claim 3 is characterized in that, between described scanning mirror and the receiving objective plane mirror is installed.
5. the optical scanning outside diameter measuring system of a kind of object scanning lens free according to claim 3 is characterized in that, described receiving objective is reflective or refraction type or the two combination.
6. the optical scanning outside diameter measuring system of a kind of object scanning lens free according to claim 3 is characterized in that, installs the protective device of optical filter or proofing dust and protecting glass or other transparent material making or the combination of said apparatus before the described photelectric receiver additional.
7. the optical scanning outside diameter measuring system of a kind of object scanning lens free according to claim 3; it is characterized in that; described scanning mirror has one or more; scanning mirror has one or more reflectings surface, and the protective device that proofing dust and protecting glass or other transparent material are made is installed before or after the described scanning mirror.
8. the optical scanning outside diameter measuring system of a kind of object scanning lens free according to claim 3 is characterized in that, described light source is LASER Light Source or led light source.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CNB2003101117512A CN100480624C (en) | 2003-10-14 | 2003-10-14 | Optical scanning outside diameter measuring system without scanning objective lens and measuring method thereof |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CNB2003101117512A CN100480624C (en) | 2003-10-14 | 2003-10-14 | Optical scanning outside diameter measuring system without scanning objective lens and measuring method thereof |
Publications (2)
Publication Number | Publication Date |
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CN1529121A CN1529121A (en) | 2004-09-15 |
CN100480624C true CN100480624C (en) | 2009-04-22 |
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ID=34304785
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CNB2003101117512A Expired - Fee Related CN100480624C (en) | 2003-10-14 | 2003-10-14 | Optical scanning outside diameter measuring system without scanning objective lens and measuring method thereof |
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Families Citing this family (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN103673906B (en) * | 2013-12-12 | 2016-07-06 | 北京动力源创科技发展有限公司 | Laser scanning caliper and the method measuring workpiece external diameter |
CN106524932A (en) * | 2016-12-29 | 2017-03-22 | 合肥工业大学 | Symmetrical optical bridge type self-stabilizing laser diameter measurement system, and calibration method and measurement method thereof |
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2003
- 2003-10-14 CN CNB2003101117512A patent/CN100480624C/en not_active Expired - Fee Related
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