CN102072711A - Radial runout non-contact detecting device for rotation shaft system - Google Patents
Radial runout non-contact detecting device for rotation shaft system Download PDFInfo
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- CN102072711A CN102072711A CN 201010545112 CN201010545112A CN102072711A CN 102072711 A CN102072711 A CN 102072711A CN 201010545112 CN201010545112 CN 201010545112 CN 201010545112 A CN201010545112 A CN 201010545112A CN 102072711 A CN102072711 A CN 102072711A
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Abstract
A radial runout non-contact detecting device for a rotation shaft system belongs to the non-contact detecting device in the field of photoelectric detection technology. The invention solves the technical problems that the radial runout non-contact detecting device for a rotation shaft system is provided. The technical scheme comprises a first and a second element brackets, a first and a second indicator gratings, a first and a second receiving pipe circuit boards, a first and a second receiving pipes, a first and a second luminotrons, a first and a second luminotron circuit boards, a grating disc, a round holding bracket, a pressing cover, a main shaft, a first and second steel balls, a cylindrical holding bracket, a shaft sleeve, a base and a fixing platform. The first and the second element brackets are symmetrically arranged at both sides of the shaft system; the grating disc is fixedly connected with the main shaft and extends in the groove of the element brackets; the luminotrons, the receiving pipes, indicator gratings arranged on the element brackets are aligned at the gratings of the grating disc; the main shaft rotates to drive the grating disc for rotating; electrooptical signals are received in the receiving pipes; and the relative variation of two signal phases is the radial runout amount of the shaft system.
Description
Technical field
The invention belongs to a kind of rotary axis diameter run-out non-contact detection device that relates in the photoelectric detection technology field.
Background technology
The size of rotary axis diameter run-out has been represented the running accuracy of this system, so its detection accuracy is very important.
The prior art the most approaching with the present invention is the inductance amesdial that middle commercial weight instrument incorporated company produces, as shown in Figure 1.Comprise pedestal 1, axle sleeve 2, cylindrical shape retainer 3, first steel ball 4, main shaft 5, first screw 6, gland 7, annular retainer 8, second steel ball 9, stationary platform 10, second screw 11, the 3rd screw 12, mini-inductance measurement instrument probe 13.
The subject matter that this inductance amesdial exists is: this kind test is the contact test, detected mismachining tolerance influences testing result, so it is very high to detected requirement on machining accuracy, increase difficulty of processing and processing cost, simultaneously because this detection is a contact detection, the probe of inductance amesdial stays cut on detected, be damage to detection faces.
Summary of the invention
In order to overcome the defective that prior art exists, engagement shaft system surface when the objective of the invention is to detect the radial beat eccentricity of rotary axis, detected difficulty of processing and cost have been deducted, adopt non-contact method to detect simultaneously, do not injure detected surface, improve the accuracy that detects, a kind of rotary axis diameter run-out of ad hoc meter non-contact detection device.
The technical problem to be solved in the present invention is: a kind of rotary axis diameter run-out non-contact detection device is provided.The technical scheme of technical solution problem comprises the 4th screw 14 as shown in Figure 2, the first components and parts frame 15, first indication grating 16, the first receiving tube wiring board 17, the 5th screw 18, first receiving tube 19, first luminotron 20, the first luminotron wiring board 21, the 6th screw 22, ring gasket 23, trim ring 24, grating dish 25, the second luminotron wiring board 26, the 7th screw 27, the second receiving tube wiring board 28, the 8th screw 29, second receiving tube 30, second indication grating 31, second luminotron 32, the 9th screw 33, the second components and parts frame 34, the 3rd screw 35, annular retainer 36, gland 37, first screw 38, main shaft 39, first steel ball 40, cylindrical shape retainer 41, second steel ball 42, axle sleeve 43, pedestal 44, second screw 45, stationary platform 46.
The inner hole sleeve that the cylindrical shape retainer 41 of first steel ball 40 is housed is contained on the main shaft 39, the outside suit axle sleeve 43 of cylindrical shape retainer 41, annular retainer 36 inner hole sleeves that second steel ball 42 is housed are contained in the bottom of main shaft 39, gland 37 at annular retainer 36 below with its picking-up, and be fixed on the main shaft 39, thereby form tested rotary axis with first screw 38.The 3rd screw 35 is fixed on tested rotary axis on the pedestal 44 by axle sleeve 43, and second screw 45 is fixed on pedestal 44 on the stationary platform 46, and axle sleeve 43 is maintained static, and main shaft 39 can freely rotate; Grating dish 25 and main shaft 39 be coaxial to be installed on the shoulder of main shaft 39, loads onto ring gasket 23 above the grating dish 25, pushes down with trim ring 24 on ring gasket 23, uses screw-thread securing between trim ring 24 and the main shaft 39, and grating dish 25 is fixed tightly on the main shaft 39; The first components and parts frame 15 and the second components and parts frame 34 are with respect to the both sides that are installed in axle system of main shaft 39 diameter symmetries, described diameter symmetry is meant the line of centres of the first components and parts frame 15 and the second components and parts frame, 34 both width, axle center by main shaft 39, the slot opening of these two framves is relative, and two fixing positions of components and parts frame can make grating dish 25 put in the components and parts frame and install in the groove of receiving tube and luminotron; All leave center pit on groove top arm on the first components and parts frame 15 and the second components and parts frame 34 and the underarm, this two hole is coaxial; Adjust the position of first and second components and parts, make the groove upper arm of the first components and parts frame 15 and center pit on the underarm and the grating center-aligned on the grating dish 25, make the groove upper arm of the second components and parts frame 34 and center pit on the underarm and the grating center-aligned on the grating dish 25; The first element device frame, 15 usefulness the 4th screw 14 is fixed on the stationary platform 46, and the second components and parts frame, 34 usefulness the 9th screw 33 is fixed on the stationary platform 46; First indication grating 16 sticks with glue on the lower surface of the top arm center pit of the first components and parts frame 15, first receiving tube 19 is welded on the first receiving tube wiring board 17, first receiving tube 19 is installed in the top arm center pit of the first components and parts frame 15, with the 5th screw 18 the first receiving tube wiring board 17 is fixed on the first components and parts frame 15, first luminotron 20 is welded on the first luminotron wiring board 21, first luminotron 20 is installed in the underarm center pit of the first components and parts frame 15, with the 6th screw 22 the first luminotron wiring board 21 is fixed on the first components and parts frame 15, second indication grating 31 sticks with glue on the lower surface of the top arm center pit of the second components and parts frame 34, second receiving tube 30 is welded on the second receiving tube wiring board 28, second receiving tube 30 is installed in the top arm center pit of the second components and parts frame 34, with the 8th screw 29 the second receiving tube wiring board 28 is fixed on the second components and parts frame 34, second luminotron 32 is welded on the second luminotron wiring board 26, second luminotron 32 is installed in the second components and parts frame, the 34 underarm center pits, the second luminotron wiring board 26 is fixed on the second components and parts frame 34 with the 7th screw 27.
Principle of work explanation: when main shaft 39 rotations, drive grating dish 25 and main shaft 39 relative first indication gratings 16 and second indication grating, 31 coaxial rotation, first indication grating 16 and second indication grating, 31 same-phases are installed, grating on the grating dish 25 that rotates and the first static indication grating 16 and the grating on second indication grating 31 produce the striped that light and shade replaces respectively, the continuous light that this striped makes first luminotron 20 and second luminotron 32 send respectively becomes the interrupted light that light and shade replaces, and is received by first receiving tube 19 and second receiving tube 30 respectively.When main shaft 39 drove grating dish 25 with main shaft 39 coaxial rotations, if the radial beat eccentricity of main shaft 39 is 0 o'clock, the phase relation of the photosignal that receives in first receiving tube 19 and second receiving tube 30 showed indeclinable phase relation on phasometer; Main shaft 39 rotates a circle, when if the radial beat eccentricity of main shaft 39 is e, the center rolling momentum of grating dish 25 also is e, first receiving tube 19 and second receiving tube 30 are arranged on the diameter two ends of grating dish 25, the change amount signal that receives at first receiving tube 19 and second receiving tube, 30 places is e, measure the phase differential maximal value a of the photosignal that first receiving tube 19 and second receiving tube 30 receive with phasometer, this phase differential is that the offset of twice grating dish 25 brings, if the grating ruling radius of grating dish 25 is R, the grid stroke logarithm is m, then the line cycle is 2 π R/m, and a line periodic phase difference is 360 °, then 2e=2 π Ra/m/360 °
So Ra/m/360 ° of e=π (1)
Obtaining axle by (1) formula is radial beat eccentricity.
Description of drawings:
Fig. 1 is the structural representation of prior art;
Fig. 2 is a structural representation of the present invention.
Embodiment:
The present invention implements by structure shown in Figure 2.Wherein annular retainer 36, gland 37, first screw 38, main shaft 39, first steel ball 40, cylindrical shape retainer 41, second steel ball 42, axle sleeve 43 are tested rotary axis.
The 4th screw 14, the 5th screw 18, the 6th screw 22, the 7th screw 27, the 8th screw 29, the 9th screw 33, the 3rd screw 35, pedestal 44, second screw 45, stationary platform 46 all adopts Q235, the first components and parts frame 15, ring gasket 23, trim ring 24, the second components and parts frame 34 all adopts steel No. 45, first indication grating 16, grating dish 25, the pedestal of second indication grating 31 all adopts K9 glass, the first receiving tube wiring board 17, the first luminotron wiring board 21, the second luminotron wiring board 26, the second receiving tube wiring board 28 all adopts plastic plate, first receiving tube 19, first luminotron 20, second receiving tube 30, second luminotron 32 is produced for Honeywell company, luminotron model SEP8505, receiving tube model SDP8405.
The inner hole sleeve that the cylindrical shape retainer 41 of first steel ball 40 is housed is contained on the main shaft 39, the outside suit axle sleeve 43 of cylindrical shape retainer 41, annular retainer 36 inner hole sleeves that second steel ball 42 is housed are contained in the bottom of main shaft 39, gland 37 at annular retainer 36 below with its picking-up, be fixed on the main shaft 39 with first screw 38, thereby form tested rotary axis.The 3rd screw 35 is fixed on tested rotary axis on the pedestal 44 by axle sleeve 43, and second screw 45 is fixed on pedestal 44 on the stationary platform 46, and axle sleeve 43 is maintained static, and main shaft 39 can freely rotate; Grating dish 25 and main shaft 39 be coaxial to be installed on the shoulder of main shaft 39, loads onto ring gasket 23 above the grating dish 25, pushes down with trim ring 24 on ring gasket 23, uses screw-thread securing between trim ring 24 and the main shaft 39, and grating dish 25 is fixed tightly on the main shaft 39; The first components and parts frame 15 and the second components and parts frame 34 are with respect to the both sides that are installed in axle system of main shaft 39 diameter symmetries, described diameter symmetry is meant the line of centres of the first components and parts frame 15 and the second components and parts frame, 34 both width, axle center by main shaft 39, the slot opening of these two framves is relative, the first components and parts frame, 15 usefulness the 4th screw 14 is fixed on the stationary platform 46, and the second components and parts frame, 34 usefulness the 9th screw 33 is fixed on the stationary platform 46; Two fixing positions of components and parts frame can make grating dish 25 put in the element frame and install in the groove of receiving tube and luminotron; All leave center pit on groove top arm on the first components and parts frame 15 and the second components and parts frame 34 and the underarm, this two hole is coaxial, on the lower surface of the top arm center pit of the first components and parts frame 15; First indication grating 16 sticks with glue on the lower surface of the top arm center pit of the first components and parts frame 15, first receiving tube 19 is welded on the first receiving tube wiring board 17, first receiving tube 19 is installed in the top arm center pit of the first components and parts frame 15, with the 5th screw 18 the first receiving tube wiring board 17 is fixed on the first components and parts frame 15, first luminotron 20 is welded on the first luminotron wiring board 21, first luminotron 20 is installed in the underarm center pit of the first components and parts frame 15, with the 6th screw 22 the first luminotron wiring board 21 is fixed on the first components and parts frame 15, second indication grating 31 sticks with glue on the lower surface of the top arm center pit of the second components and parts frame 34, second receiving tube 30 is welded on the second receiving tube wiring board 28, second receiving tube 30 is installed in the top arm center pit of the second components and parts frame 34, with the 8th screw 29 the second receiving tube wiring board 28 is fixed on the second components and parts frame 34, second luminotron 32 is welded on the second luminotron wiring board 26, second luminotron 32 is installed in the second components and parts frame, the 34 underarm center pits, the second luminotron wiring board 26 is fixed on the second components and parts frame 34 with the 7th screw 27.
Claims (1)
1. the non-contact detection device of a rotary axis diameter run-out comprises the 3rd screw (35), annular retainer (36), first screw (38), main shaft (39), first steel ball (40), cylindrical shape retainer (41), second steel ball (42), axle sleeve (43), pedestal (44), second screw (45), stationary platform (46); It is characterized in that also comprising the 4th screw (14), the first components and parts frame (15), first indication grating (16), the first receiving tube wiring board (17), the 5th screw (18), first receiving tube (19), first luminotron (20), the first luminotron wiring board (21), the 6th screw (22), ring gasket (23), trim ring (24), grating dish (25), the second luminotron wiring board (26), the 7th screw (27), the second receiving tube wiring board (28), the 8th screw (29), second receiving tube (30), second indication grating (31), second luminotron (32), the 9th screw (33), the second components and parts frame (34), gland (37); The inner hole sleeve that the cylindrical shape retainer (41) of first steel ball (40) is housed is contained on the main shaft (39), the outside suit axle sleeve (43) of cylindrical shape retainer (41), annular retainer (36) inner hole sleeve that second steel ball (42) is housed is contained in the bottom of main shaft (39), gland (37) at annular retainer (36) below with its picking-up, and be fixed on the main shaft (39) with first screw (38), form tested rotary axis; The 3rd screw (35) is fixed on tested rotary axis on the pedestal (44) by axle sleeve (43), and second screw (45) is fixed on pedestal (44) on the stationary platform (46), and axle sleeve (43) is maintained static, and main shaft (39) freely rotates; Grating dish (25) and main shaft (39) be coaxial to be installed on the shoulder of main shaft (39), load onto ring gasket (23) above the grating dish (25), on ring gasket (23), push down with trim ring (24), use screw-thread securing between trim ring (24) and the main shaft (39), grating dish (25) is fixed tightly on the main shaft (39); The first components and parts frame (15) and the second components and parts frame (34) are with respect to the both sides that are installed in axle system of main shaft (39) diameter symmetry, described diameter symmetry is meant the axle center of the line of centres of the first components and parts frame (15) and second both width of components and parts frame (34) by main shaft (39), the slot opening of these two framves is relative, and two fixing positions of components and parts frame can make grating dish (25) put in the components and parts frame and install in the groove of receiving tube and luminotron; All leave center pit on groove top arm on the first components and parts frame (15) and the second components and parts frame (34) and the underarm, this two hole is coaxial; Adjust the position of first and second components and parts, make the groove upper arm of the first components and parts frame (15) and the grating center-aligned on center pit on the underarm and the grating dish (25), make the groove upper arm of the second components and parts frame (34) and the grating center-aligned on center pit on the underarm and the grating dish (25); The first element device frame (15) is fixed on the stationary platform (46) with the 4th screw (14), and the second components and parts frame (34) is fixed on the stationary platform (46) with the 9th screw (33); First indication grating (16) sticks with glue on the lower surface of the top arm center pit of the first components and parts frame (15), first receiving tube (19) is welded on the first receiving tube wiring board (17), first receiving tube (19) is installed in the top arm center pit of the first components and parts frame (15), with the 5th screw (18) the first receiving tube wiring board (17) is fixed on the first components and parts frame (15), first luminotron (20) is welded on the first luminotron wiring board (21), first luminotron (20) is installed in the underarm center pit of the first components and parts frame (15), with the 6th screw (22) the first luminotron wiring board (21) is fixed on the first components and parts frame (15), second indication grating (31) sticks with glue on the lower surface of the top arm center pit of the second components and parts frame (34), second receiving tube (30) is welded on the second receiving tube wiring board (28), second receiving tube (30) is installed in the top arm center pit of the second components and parts frame (34), with the 8th screw (29) the second receiving tube wiring board (28) is fixed on the second components and parts frame (34), second luminotron (32) is welded on the second luminotron wiring board (26), second luminotron (32) is installed in second components and parts frame (34) the underarm center pit, the second luminotron wiring board (26) is fixed on the second components and parts frame (34) with the 7th screw (27).
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CN2010105451127A CN102072711B (en) | 2010-11-16 | 2010-11-16 | Radial runout non-contact detecting device for rotation shaft system |
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CN2010105451127A CN102072711B (en) | 2010-11-16 | 2010-11-16 | Radial runout non-contact detecting device for rotation shaft system |
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CN102072711B CN102072711B (en) | 2012-04-11 |
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Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
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CN102322802A (en) * | 2011-06-14 | 2012-01-18 | 上海出入境检验检疫局机电产品检测技术中心 | Measuring device for minute displacement of non-contact type rotating object |
CN102489548A (en) * | 2011-12-28 | 2012-06-13 | 长春汇凯科技有限公司 | Multichannel shaft part run-out high-speed measurement device |
ES2415776R1 (en) * | 2011-12-23 | 2013-10-11 | Univ Catalunya Politecnica | System and method of measuring the transverse displacement of a rotating physical axis |
CN103542826A (en) * | 2013-11-01 | 2014-01-29 | 洛阳Lyc轴承有限公司 | Method for detecting radial movement of pocket holes of cylindrical roller bearing holder |
CN108168461A (en) * | 2018-01-11 | 2018-06-15 | 哈尔滨工业大学 | A kind of Errors in Radial Rotation Error of Spindle measuring device and method based on diffraction grating |
CN112692427A (en) * | 2020-12-31 | 2021-04-23 | 大族激光科技产业集团股份有限公司 | Device capable of detecting rotation concentricity of circular workpiece |
CN117705000A (en) * | 2024-02-01 | 2024-03-15 | 天津市产品质量监督检测技术研究院 | Ball roundness detection device |
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CN1995775A (en) * | 2006-11-30 | 2007-07-11 | 南京航空航天大学 | Method for actively inhibiting pulsation of machine tool main shaft and device therefor |
CN101608887A (en) * | 2009-07-21 | 2009-12-23 | 河南省西峡汽车水泵股份有限公司 | Detection method and appliance special for detecting that a kind of water seal installed surface is beated to the water pump body axis hole |
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CN2218190Y (en) * | 1995-03-21 | 1996-01-24 | 北京第三纺织机械厂 | Out of roundness detector for bearing roller |
JP2000304529A (en) * | 1999-04-22 | 2000-11-02 | Ricoh Co Ltd | Probe device and shape measuring device |
CN1995775A (en) * | 2006-11-30 | 2007-07-11 | 南京航空航天大学 | Method for actively inhibiting pulsation of machine tool main shaft and device therefor |
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Cited By (12)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102322802A (en) * | 2011-06-14 | 2012-01-18 | 上海出入境检验检疫局机电产品检测技术中心 | Measuring device for minute displacement of non-contact type rotating object |
CN102322802B (en) * | 2011-06-14 | 2013-07-31 | 上海出入境检验检疫局机电产品检测技术中心 | Measuring method for minute displacement of non-contact type rotating object |
ES2415776R1 (en) * | 2011-12-23 | 2013-10-11 | Univ Catalunya Politecnica | System and method of measuring the transverse displacement of a rotating physical axis |
CN102489548A (en) * | 2011-12-28 | 2012-06-13 | 长春汇凯科技有限公司 | Multichannel shaft part run-out high-speed measurement device |
CN102489548B (en) * | 2011-12-28 | 2014-04-30 | 长春汇凯科技有限公司 | Multichannel shaft part run-out high-speed measurement device |
CN103542826A (en) * | 2013-11-01 | 2014-01-29 | 洛阳Lyc轴承有限公司 | Method for detecting radial movement of pocket holes of cylindrical roller bearing holder |
CN108168461A (en) * | 2018-01-11 | 2018-06-15 | 哈尔滨工业大学 | A kind of Errors in Radial Rotation Error of Spindle measuring device and method based on diffraction grating |
CN108168461B (en) * | 2018-01-11 | 2019-10-25 | 哈尔滨工业大学 | A kind of Errors in Radial Rotation Error of Spindle measuring device and method based on diffraction grating |
CN112692427A (en) * | 2020-12-31 | 2021-04-23 | 大族激光科技产业集团股份有限公司 | Device capable of detecting rotation concentricity of circular workpiece |
CN112692427B (en) * | 2020-12-31 | 2023-08-29 | 大族激光科技产业集团股份有限公司 | Device capable of detecting rotation concentricity of round workpiece |
CN117705000A (en) * | 2024-02-01 | 2024-03-15 | 天津市产品质量监督检测技术研究院 | Ball roundness detection device |
CN117705000B (en) * | 2024-02-01 | 2024-05-03 | 天津市产品质量监督检测技术研究院 | Ball roundness detection device |
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