CN204346373U - A kind of metering type micro-nano bench height measurement mechanism - Google Patents
A kind of metering type micro-nano bench height measurement mechanism Download PDFInfo
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- CN204346373U CN204346373U CN201520016874.6U CN201520016874U CN204346373U CN 204346373 U CN204346373 U CN 204346373U CN 201520016874 U CN201520016874 U CN 201520016874U CN 204346373 U CN204346373 U CN 204346373U
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Abstract
The utility model discloses a kind of metering type micro-nano bench height measurement mechanism, comprise support system and be arranged on the micro-gauge head of white light, displacement scanning system and the metering system in support system.The beneficial effects of the utility model are: this metering type micro-nano bench height measurement mechanism is mainly used to measure the height of micro-nano step or the degree of depth of groove.System adopts thickness two-stage displacement scanning system, and the nanometer displacement platform of Piezoelectric Ceramic can realize Subnano-class stepping in micron order sweep limit; The lifting table of Piezoelectric Ceramic can realize submicron order stepping in grade sweep limit; Z-direction measurement range is maximum reaches 200 microns.Micro-interference gauge head adopts white light source (namely adopting the micro-gauge head of white light), based on white light interference theory, can realize the Z-direction resolution of 0.1nm, directly can obtain the three-dimensional appearance of measured surface simultaneously.Adopt laser interferometer composition metering system, displacement is directly traceable to the wavelength standard of meter Ding Yi in International System of Units.
Description
Technical field
The utility model relates to micro-nano bench height field of measuring technique, is specifically related to a kind of metering type micro-nano bench height measurement mechanism.
Background technology
At present, general stylus scans and microscan two kinds of methods measure the nanometer channel degree of depth, but these two kinds of measuring methods all exist certain technological deficiency, and concrete defect is as follows:
Stylus scans method is utilized to measure.During measurement, contact pilotage contacts with measured surface and along measured surface rectilinear motion, the upper and lower displacement of contact pilotage passes to survey sensor by leverage, and the output valve of sensor is and obtains the degree of depth of tested nanometer channel or the height of nanometer step.But measured profile is the convolution of contact pilotage and measured surface surface topography, the pattern of contact pilotage can be brought in profile, causes measuring error; Contact pilotage diameter has certain size simultaneously, directly cannot contact, also can affect surface measurement accuracy with piece surfaces such as having darker minor groove, aperture.Stylus scans method adopts sensor measurement displacement, and it cannot realize displacement magnitude tracing based on inductance or Principles of Laser, just can measure after must calibrating.The single measurement of stylus scans method can only obtain an outline line, cannot realize quick three-dimensional scanning.
Microscan method is utilized to measure.During measurement, the micro-gauge head of Piezoelectric Ceramic scans perpendicular to sample surfaces, gather nanometer channel or step upper and lower surface interference image, simulate upper and lower surface 3-D view, image upper and lower surface spacing is the degree of depth of tested nanometer channel or the height of nanometer step.Although microscan method can obtain 3-D view, its length travel all comes from grating scale, just can measure after still needing calibration.
In sum, also not having one can realize at present, value directly traces to the source, and has grade measurement range, nanometer measurement accuracy, directly can obtain gash depth (bench height) the surveying instrument equipment of 3-D view.
Utility model content
For solve in prior art also do not have one can realize value directly traces to the source, there is grade measurement range, nanometer measurement accuracy, directly can obtain the technological deficiency of the nanometer channel depth measurement device of 3-D view, the utility model is designed a kind of value that achieves and is directly traced to the source, has grade measurement range, nanometer measurement accuracy, directly can obtain the metering type micro-nano bench height measurement mechanism of 3-D view.
For achieving the above object, the technical solution adopted in the utility model is:
A kind of metering type micro-nano bench height measurement mechanism, comprise support system and be arranged on the micro-gauge head of white light, displacement scanning system and the metering system in support system, support system comprises base plate and is fixed in " [" shape column on base plate; The micro-gauge head of white light comprises light source module, lighting module, CCD module, pipe mirror module and interference objective module, light source module and lighting module are by the first Fiber connection, CCD module and pipe mirror module and be all threaded connection between interference objective module and lighting module, by bayonet socket clamping between pipe mirror module and lighting module; Displacement scanning system comprises and being arranged on " lifting table of [" shape column inwall, the lifting support plate being fixed in lifting table sidewall and the nanometer displacement platform be arranged on lifting support plate and adjustable inclination objective table, adjustable inclination objective table is fixed in above nanometer displacement platform, and lifting support plate is by linear bearing structure and " [" shape column is slidably connected; Metering system comprises the laser interferometer be fixed in bottom lifting support plate, reference mirror and measurement catoptron, and wherein laser interferometer comprises and interferes head and LASER Light Source, interferes head to be connected with LASER Light Source by the second optical fiber; Interfere and head offers measuring beam and to import and export and reference beam is imported and exported, reference mirror is fixed in interference head surface and perpendicular to reference beam; Displacement scanning system bottom is connected with tilt adjustment structure, measures catoptron and to be fixed on tilt adjustment structure bottom face and perpendicular to measuring beam; The optical axis of the micro-gauge head of white light and the light shaft coaxle of laser interferometer.
This metering type micro-nano bench height measurement mechanism is mainly used to measure the height of nanometer step or the degree of depth of groove.System adopts thickness two-stage displacement scanning system, and the nanometer displacement platform of Piezoelectric Ceramic can realize Subnano-class stepping in micron order sweep limit; The lifting table of Piezoelectric Ceramic can realize submicron order stepping in grade sweep limit; Z-direction measurement range is maximum reaches 200 microns.Micro-interference gauge head adopts white light source (namely adopting the micro-gauge head of white light), white light interference image has the zero order interference fringe feature larger than the subsidiary interference streak amplitude of both sides, zero order interference fringe centralized positioning measurand upper and lower surface position is adopted according to this feature, the Z-direction resolution of 0.1nm can be realized, directly can obtain the three-dimensional appearance of measured surface simultaneously.Adopt the first fiber optic conduction between light source module and lighting module, reduce light source and to generate heat the Thermal Error brought; In addition, this design also makes replacing light source bulb easier than light illumination integral structure.
Further, base plate and " be provided with arc surface base between [" shape column." left and right sides and the back side of [" shape column are all provided with wiring casing, wiring casing offer the panel beating wire casing passed through for the first optical fiber.
Further, " left and right sides and the back side of [" shape column are all provided with wiring casing, wiring casing offer the panel beating wire casing passed through for the first optical fiber.
Further, lifting support plate is provided with floor and lower floor, the structure and lifting support plate is formed in one.Lifting support plate adopts upper and lower rib structure, can dispersing nanometer displacement platform and adjustable inclination objective table pressure and strengthen the robust motion of lifting table.
Further, between adjustable inclination objective table and nanometer displacement platform, card extender is installed; Offer through hole in the middle part of nanometer displacement platform, tilt adjustment structure is bolted card extender bottom and by the through hole of nanometer displacement platform.
Further, tilt adjustment structure adopts flexible hinge structure.
Further, nanometer displacement platform is parallel with optical axis with the direction of scanning of lifting table, and nanometer displacement platform and lifting table all vertically placement/horizontal positioned.
Preferably, the distance measured between catoptron and reference mirror is 3mm-5mm.The dead path-length error of laser interferometer can be reduced.
Further, linear bearing structure comprises the identical slide assemblies of two groups of structures, often organize slide assemblies to include guide shaft seat and be fixed in the guide shaft on guide shaft seat top, guide shaft bottom is fixedly connected with guide shaft seat by two supporting semicircle locking members, and top extends upwardly to stretches out lifting support plate and through the bearing be fixed in above lifting support plate.This linear bearing structure effectively reduces the lateral stress of lifting support plate.
The beneficial effects of the utility model are: 1, adopt the first fiber optic conduction between light source module and lighting module, reduce light source and to generate heat the Thermal Error brought; In addition, this design also makes replacing light source bulb easier than light illumination integral structure.2, the micro-gauge head of white light adopts Mirau type interference objective, and reference mirror and spectroscope are positioned at inside, and light beam is less by ectocine; Mirau type interference objective herein also can be easy be replaced by Michelson and Linnik interference objective, realize the measurement of dissimilar sample.3, system adopts thickness two-stage displacement scanning system, and the nanometer displacement platform of Piezoelectric Ceramic can realize Subnano-class stepping in micron order sweep limit; The lifting table of Piezoelectric Ceramic can realize submicron order stepping in grade sweep limit; Z-direction measurement range is maximum reaches 200 microns.4, adopt gauge head motionless, objective table scan mode, white light micro-interference system can be made not by the impact of motion structure vibration, reliable and stable.5, " marble that [" shape column and base plate adopt weight very greatly, not easily to produce distortion is made, and stable mechanical performance is reliable.6, the center of gravity of the micro-gauge head of white light is positioned at the table top of marble base, because marble weight is comparatively large, can ensure the mechanical stability of gauge head.7, displacement scanning system adopts linear bearing support structure, effectively ensure that the single-way moving of displacement scanning system, reduces the Abbe error that kinematic axis brings with measurement axle disalignment.8, the optical axis of the micro-gauge head of white light and the light shaft coaxle of laser interferometer reduce Abbe error and cosine error.9, adopt laser interferometer, reference mirror and measurement catoptron to form metering system, displacement directly can be traceable to the wavelength standard of meter Ding Yi in International System of Units.10, measure catoptron parallel with the reflecting surface of reference mirror and fore-and-aft distance is 3mm-5mm, the dead path-length error of laser interferometer can be reduced.
Accompanying drawing explanation
Fig. 1 is the structural representation of metering type micro-nano bench height measurement mechanism described in the utility model;
Fig. 2 is the structural representation of the micro-gauge head of white light described in the utility model;
Fig. 3 is the light path design block diagram of the micro-gauge head of white light described in the utility model;
Fig. 4 is the structural representation of displacement scanning system described in the utility model (comprise " [" shape column);
Fig. 5 is the partial enlarged drawing at Fig. 4 A place;
Fig. 6 is the partial enlarged drawing at Fig. 4 B place;
Fig. 7 is the structural representation of metering system described in the utility model;
Fig. 8 is the structural representation of interference head described in the utility model;
Fig. 9 is the structural representation of tilt adjustment structure described in the utility model.
In figure,
1, support system; 11, base plate; 12, " [" shape column; 121, wiring casing; 122, panel beating wire casing; 13, arc surface base; 2, the micro-gauge head of white light; 21, housing; 22, light source module; 23, lighting module; 24, CCD module; 25, pipe mirror module; 26, interference objective module; 27, the first optical fiber; 28, sample; 3, displacement scanning system; 31, lifting table; 32, support plate is elevated; 321, upper floor; 322, lower floor; 33, nanometer displacement platform; 34, adjustable inclination objective table; 35, linear bearing structure; 351, guide shaft seat; 352, guide shaft; 353, semicircle locking member; 354, bearing; 37, tilt adjustment structure; 38, card extender; 4, metering system; 41, head is interfered; 411, measuring beam is imported and exported; 412, reference beam is imported and exported; 42, reference mirror; 421, the second optical fiber; 422, LASER Light Source; 43, catoptron is measured.
Embodiment
Below in conjunction with accompanying drawing, explanation is explained in detail to structure of the present utility model.
As shown in figs 1-9, a kind of metering type micro-nano bench height measurement mechanism that the utility model provides, comprise support system 1 and be arranged on the micro-gauge head 2 of white light, displacement scanning system 3 and the metering system 4 in support system, support system comprises base plate 11 and is fixed in " [" shape column 12 on base plate; The micro-gauge head of white light comprises light source module 22, lighting module 23, CCD module 24, pipe mirror module 25 and interference objective module 26, light source module is connected by the first optical fiber 27 with lighting module, CCD module and pipe mirror module and be all threaded connection between interference objective module and lighting module, by bayonet socket clamping between pipe mirror module and lighting module; Displacement scanning system comprises and being arranged on " lifting table 31 of [" shape column inwall, the lifting support plate 32 being fixed in lifting table sidewall and the nanometer displacement platform 33 be arranged on lifting support plate and adjustable inclination objective table 34, adjustable inclination objective table is fixed in above nanometer displacement platform, and lifting support plate is by linear bearing structure 35 and " [" shape column is slidably connected; Metering system comprises the laser interferometer be fixed in bottom lifting support plate, reference mirror 42 and measure catoptron 43, and wherein laser interferometer comprises and interferes 41 and a LASER Light Source 423, interferes head to be connected with LASER Light Source by the second optical fiber 422; Interfere head offers measuring beam import and export 411 and reference beam import and export 412, reference mirror is fixed in interferes head surface and perpendicular to reference beam; Displacement scanning system bottom is connected with tilt adjustment structure 37, measures catoptron and to be fixed on tilt adjustment structure bottom face and perpendicular to measuring beam; The optical axis of the micro-gauge head of white light and the light shaft coaxle of laser interferometer, displacement scanning system direction of scanning is parallel with optical axis.The distance measured between catoptron and reference mirror reaches grade, preferred 3mm-5mm.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, base plate and " be provided with arc surface base 13 between [" shape column.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, " left and right sides and the back side of [" shape column are all provided with wiring casing 121, wiring casing offer the panel beating wire casing 122 passed through for the first optical fiber.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, lifting support plate is provided with floor 321 and lower floor 322, the structure and lifting support plate is formed in one.Lifting support plate adopts upper and lower rib structure, can dispersing nanometer displacement platform and adjustable inclination objective table pressure and strengthen the robust motion of lifting table.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, is provided with card extender 38 between adjustable inclination objective table and nanometer displacement platform; Offer through hole in the middle part of nanometer displacement platform, tilt adjustment structure is bolted card extender bottom and by the through hole of nanometer displacement platform.Tilt adjustment structure adopts flexible hinge structure.Nanometer displacement platform should be vertical with optical axis with the direction of scanning of lifting table, and it is different because of product that it places attitude, vertically can place/horizontal positioned.Nanometer displacement platform is bolted on lifting support plate by four, and adjustable inclination objective table is fixed on nanometer displacement platform by card extender.Tilt adjustment structure adopts flexible hinge structure, the angle of inclination of adjustable X, Y both direction, when laser interferometer is installed for the first time, utilizes this tilt adjustment structural adjustment to measure the angle of inclination of catoptron, measuring beam can be made to be in optimum position.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, the micro-gauge head of white light can adopt Mirau type interference objective, also can adopt Michelson and Linnik type interference objective.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, the interference of laser interferometer between 411 and LASER Light Source 413 available fiber import laser, also usable reflectance mirror imports laser.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, linear bearing structure comprises the identical slide assemblies of two groups of structures, often organize slide assemblies to include guide shaft seat 351 and be fixed in the guide shaft 352 on guide shaft seat top, guide shaft bottom is fixedly connected with guide shaft seat by two supporting semicircle locking members 353, and top extends upwardly to stretches out lifting support plate and through the bearing 354 be fixed in above lifting support plate.This linear bearing structure effectively reduces the lateral stress of lifting support plate.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, the micro-gauge head of white light also comprises the housing 21 for accommodating lighting module, pipe mirror module and interference objective module.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, form primarily of the micro-gauge head of the white light be arranged in support system, displacement scanning system and metering system three part, during measurement, displacement scanning system drives tested nanometer channel or step to scan up and down, the micro-gauge head of white light gathers the interference fringe of measurand upper and lower surface, the displacement of nanometer displacement platform in metering system displacement monitoring scanning system.Analyze interference fringe by special software and find upper and lower surface position, corresponding with the displacement that metering system measures, its shift differences is the degree of depth of nanometer channel or the height value of step.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, concrete structure and the principle of work of the micro-gauge head of white light are as follows: light source module adopts white light source module, the light that white light source module sends, two bundles are divided into by entering interference objective module after lighting module, a branch ofly be irradiated on sample 28, on a branch of catoptron be irradiated in interference objective module, two-beam is finally all reflected back and is entered in CCD module by pipe mirror module and to produce interference wherein.Adopt fiber optic conduction between light source module and lighting module, reduce light source and to generate heat the Thermal Error brought; In addition, this design also makes replacing light source bulb easier than light illumination integral structure.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, concrete structure and the principle of work of displacement scanning system are as follows: lifting table drives lifting support plate and the nanometer displacement platform be located thereon and adjustable inclination objective table to scan from bottom to up along the guide shaft of linear bearing structure, after searching out the position that on adjustable inclination objective table, tested nanometer channel or step upper and lower surface interference fringe occur, lifting table is adjusted to the position before groove or the appearance of step lower surface interference fringe, locking lifting table, nanometer displacement platform drives adjustable inclination objective table to scan from bottom to up.Lifting table use four be bolted to marmorean " on [" column, lifting support plate be bolted on lifting table by six.Nanometer displacement platform is bolted on lifting support plate by four, and adjustable inclination objective table is fixed on nanometer displacement platform by card extender.
A kind of metering type micro-nano bench height measurement mechanism that the utility model provides, concrete structure and the principle of work of metering system are as follows: the measuring beam on the laser interferometer left side is imported and exported coaxial with interference objective in the micro-gauge head of white light, when nanometer displacement platform scans up and down, laser interferometer can monitor its shift value, displacement is traceable to the definition of rice.Interfere head to be directly fixed to bottom lifting support plate, reference mirror glue glues two the reference beam hole sites bonding to and interfere head.Measuring catoptron is installed in tilt adjustment structure, and tilt adjustment structure is bolted on the card extender bottom adjustable inclination objective table.Tilt adjustment structure adopts flexible hinge structure, the angle of inclination of adjustable X, Y both direction, when interfering head to be installed for the first time, utilizes this structural adjustment to measure mirror tilt angle, makes measuring beam be in optimum position.
The foregoing is only preferred embodiment of the present utility model, not in order to limit the utility model, all do in the utility model flesh and blood any amendment, equivalent to replace and simple modifications etc., all should be included within protection domain of the present utility model.
Claims (8)
1. a metering type micro-nano bench height measurement mechanism, comprise support system (1) and be arranged on the micro-gauge head of white light (2), displacement scanning system (3) and the metering system (4) in support system, it is characterized in that, support system comprises base plate (11) and is fixed in " [" shape column (12) on base plate;
The micro-gauge head of white light comprises light source module (22), lighting module (23), CCD module (24), pipe mirror module (25) and interference objective module (26), light source module is connected by the first optical fiber (27) with lighting module, CCD module and pipe mirror module and be all threaded connection between interference objective module and lighting module, by bayonet socket clamping between pipe mirror module and lighting module;
Displacement scanning system comprises and being arranged on " lifting table (31) of [" shape column inwall, the lifting support plate (32) being fixed in lifting table sidewall and the nanometer displacement platform (33) be arranged on lifting support plate and adjustable inclination objective table (34), adjustable inclination objective table is fixed in above nanometer displacement platform, and lifting support plate is by linear bearing structure (35) and " [" shape column is slidably connected;
Metering system comprises the laser interferometer be fixed in bottom lifting support plate, reference mirror (42) and measurement catoptron (43), wherein laser interferometer comprises and interferes head (41) and LASER Light Source (422), interferes head to be connected with LASER Light Source by the second optical fiber (421); Interfere and head offers measuring beam and import and export (411) and reference beam imports and exports (412), reference mirror is fixed in interference head surface and perpendicular to reference beam; Displacement scanning system bottom is connected with tilt adjustment structure (37), measures catoptron and to be fixed on tilt adjustment structure bottom face and perpendicular to measuring beam.
2. metering type micro-nano bench height measurement mechanism according to claim 1, is characterized in that, base plate and " be provided with arc surface base (13) between [" shape column.
3. metering type micro-nano bench height measurement mechanism according to claim 2, it is characterized in that, " left and right sides of [" shape column and the back side are all provided with wiring casing (121), wiring casing offer the panel beating wire casing (122) passed through for the first optical fiber.
4. metering type micro-nano bench height measurement mechanism according to claim 1, is characterized in that, lifting support plate is provided with floor (321) and lower floor (322), the structure and lifting support plate is formed in one.
5. metering type micro-nano bench height measurement mechanism according to claim 1, is characterized in that, be provided with card extender (38) between adjustable inclination objective table and nanometer displacement platform; Offer through hole in the middle part of nanometer displacement platform, tilt adjustment structure is bolted card extender bottom and by the through hole of nanometer displacement platform.
6. metering type micro-nano bench height measurement mechanism according to claim 1, is characterized in that, tilt adjustment structure adopts flexible hinge structure.
7. metering type micro-nano bench height measurement mechanism according to claim 1, it is characterized in that, nanometer displacement platform is parallel with optical axis with the direction of scanning of lifting table, and nanometer displacement platform and lifting table all vertically placement/horizontal positioned.
8. metering type micro-nano bench height measurement mechanism according to claim 1, it is characterized in that, linear bearing structure comprises the identical slide assemblies of two groups of structures, often organize slide assemblies to include guide shaft seat (351) and be fixed in the guide shaft (352) on guide shaft seat top, guide shaft bottom is fixedly connected with guide shaft seat by two supporting semicircle locking members (353), and top extends upwardly to stretches out lifting support plate and through the bearing (354) be fixed in above lifting support plate.
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Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104567693A (en) * | 2015-01-09 | 2015-04-29 | 中国计量科学研究院 | Measuring type micro-nano step height measuring device |
| CN107144237A (en) * | 2017-06-13 | 2017-09-08 | 杭州齐跃科技有限公司 | Heavy caliber interferometer measuration system and algorithm based on three-dimensional splicing |
| CN110030952A (en) * | 2019-05-16 | 2019-07-19 | 苏州慧利仪器有限责任公司 | Vertical crystal bar laser interference detection device |
| CN110160450A (en) * | 2019-05-13 | 2019-08-23 | 天津大学 | The method for fast measuring of big step height based on white light interference spectrum |
| CN113432625A (en) * | 2021-07-09 | 2021-09-24 | 安徽创谱仪器科技有限公司 | Calibration system and calibration method of hydrostatic level |
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2015
- 2015-01-09 CN CN201520016874.6U patent/CN204346373U/en active Active
Cited By (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104567693A (en) * | 2015-01-09 | 2015-04-29 | 中国计量科学研究院 | Measuring type micro-nano step height measuring device |
| CN107144237A (en) * | 2017-06-13 | 2017-09-08 | 杭州齐跃科技有限公司 | Heavy caliber interferometer measuration system and algorithm based on three-dimensional splicing |
| CN107144237B (en) * | 2017-06-13 | 2019-06-14 | 杭州齐跃科技有限公司 | Heavy caliber interferometer measuration system and algorithm based on three-dimensional splicing |
| CN110160450A (en) * | 2019-05-13 | 2019-08-23 | 天津大学 | The method for fast measuring of big step height based on white light interference spectrum |
| CN110030952A (en) * | 2019-05-16 | 2019-07-19 | 苏州慧利仪器有限责任公司 | Vertical crystal bar laser interference detection device |
| CN110030952B (en) * | 2019-05-16 | 2020-10-27 | 苏州慧利仪器有限责任公司 | Vertical crystal bar laser interference detection equipment |
| CN113432625A (en) * | 2021-07-09 | 2021-09-24 | 安徽创谱仪器科技有限公司 | Calibration system and calibration method of hydrostatic level |
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