CN103791815A - Aero-engine rotor air floatation assembling method and device based on inductance measurement - Google Patents
Aero-engine rotor air floatation assembling method and device based on inductance measurement Download PDFInfo
- Publication number
- CN103791815A CN103791815A CN201410052106.6A CN201410052106A CN103791815A CN 103791815 A CN103791815 A CN 103791815A CN 201410052106 A CN201410052106 A CN 201410052106A CN 103791815 A CN103791815 A CN 103791815A
- Authority
- CN
- China
- Prior art keywords
- face
- rotor
- air
- assembling
- radially
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
Images
Abstract
The invention discloses an aero-engine rotor air floatation assembling method and device based on inductance measurement, and belongs to the machine assembling technology. The measuring method and device are based on an air flotation rotating shaft system to determine a rotary benchmark. The method comprises the steps that the angle positioning of a rotary table is determined according to a circular grating; the radial error of a radial assembling face and the inclined error of an axial assembling face of rotors are extracted based on a four-measuring-head measuring device, and the influence weight of the rotors on the assembled rotor coaxiality is obtained; all the required rotors are measured and assembled respectively, and the influence weight of the rotors on the assembled rotor coaxiality is obtained; vector optimization is carried out on the weights of the rotors, and the assembling angles of the rotors are obtained. The method and device can effectively solve the problem that the rotors of an aero-engine are low in coaxiality after being assembled, and have the advantages of being high in coaxiality after the rotors are assembled, reducing vibration, being easy to mount, being high in flexibility, and improving the engine performance.
Description
Technical field
The invention belongs to mechanical assembly technique, relate generally to a kind of aeroengine rotor air supporting assembly method and device based on inductance measurement.
Background technology
Aeromotor assembling is the final tache in aeromotor manufacture process, is also one of of paramount importance manufacture link.Under existing Aeroengine Design scheme and process technology level conditions, the quality of assembling and work efficiency have material impact for quality, performance and the production efficiency of engine.So will improve as much as possible the right alignment of rotor after installing in assembling process, and then reduce the vibration of aeromotor, improve the performance of aeromotor.But, in reality is produced, the assembling of aeromotor is complete manual setting, the height of assembly precision and whether stablize the assembler's that places one's entire reliance upon operating experience and technical merit, lack a kind of method that high speed effectively instructs aeroengine rotor assembling, and then raising efficiency of assembling, reduce aeromotor vibration, improve the performance of aeromotor.
Along with aeromotor assembling measuring technology more and more comes into one's own, aeromotor assembling measuring technology more and more comes into one's own, and becomes the focus of research.Increasing researchist has carried out deep discussion for aeroengine rotor, and Rools-Royce proposes a kind of scheme (System and method for improving the damage tolerance of a rotor assembly.European Patent Publication No: EP2525049A2), main by each sub-test macro being obtained to the stress signal of the each position of rotor, main system is analyzed the signal of each subsystem collection, damage the impact of parameter analysis on assembling from the appearance of each rotor, and then improved the assembling of aeroengine rotor.The problem that the method exists is: do not analyze the geometric sense aspect of rotor to the impact of assembling, cannot improve the impact of geometric sense on assembling.
Xi'an Communications University proposes a kind of method for testing assembly performance of rotor of aircraft engine (a kind of method for testing assembly performance of rotor of aircraft engine.Publication number: CN101799354A).First the method adopts vibrator exciting aeroengine rotor, utilizes vibration transducer and signal acquiring system software to obtain the impulse response signal of the aeroengine rotor of a multicarrier coupling; Then the impulse response signal of the aeroengine rotor to obtained a multicarrier coupling adopts dual-tree complex wavelet transform method to analyze, and obtains the impulse response subsignal of the aeroengine rotor of eight single carriers; Finally the impulse response subsignal of the aeroengine rotor to eight obtained single carriers extracts average assembly performance index, if the average assembly performance desired value of gained is more than or equal to 10, judge that this aeroengine rotor assembling is qualified, if the mean value of gained is less than 10, judge defective, the rebuilding of need to doing over again.The problem that the method exists is: to aeroengine rotor, assembling is not instructed.
Luoxin Precision Parts (shanghai) Co., Ltd. proposes a kind of right alignment equipment (a kind of axiality measuring apparatus of measuring.Publication number: CN202024752U).This device comprises a pair of transmission main shaft being rotated by synchronizing linkage synchro control being arranged on apparatus subject, and this transmission main shaft the inner respectively correspondence is provided with measuring head and positioning reference plane; Between described measuring head, top, position has transducer probe assembly.It mainly solves the right alignment of existing precision component, the measurement of beating.The problem that the method exists is: only measure the right alignment of measured piece, do not solve the rear poor problem of right alignment of rotor assembling.
Liming Aeroplane Engine (Group) Co., Ltd., Shenyang City proposes a kind of gap measuring method (non-contact measuring method for leaf apex radial clearance of engine rotor.Publication number: CN102175135A).The method adopts capacitance measurement technology, and measuring process is as follows, first assembles measuring system, calibration sensor, determines the relation between blade tip radial play and voltage, then sensor is fixed on blade, finally measures engine rotor blade tip radial play.The problem that the method exists is: do not consider in rotor assembling process the impact after axially installed surface is on rotor assembling.
The tested object of aeromotor assembling is stators and rotor, and under the condition meeting the demands in component processing precision, final inspection is by the Determines after coordinating is installed, and the index of evaluation is mainly the right alignment parameter of rotor after assembling.Engine rotation produces high pressure, and its rotor is made up of multiple single parts of combining, ideal when the revolving shaft of each parts and the dead in line of whole engine.High Rotation Speed speed when high-performance enginer work is greater than 10000rpm, single part axially or radial beat will inevitably cause turbine disk misalignment engine rotation axis, under such condition, can produce very large centrifugal force, the imbalance that causes rotor to rotate, cause engine luggine, thereby guarantee that the right alignment after each parts assembling is the Focal point and difficult point of installing.
One does not use the Model Mounting of right alignment optimization method, axially and radially the beating because machining precision restriction exists of all parts, eccentric, inclination equal error.If directly assembled randomly, just may form the bending situation that is similar to " banana ", upper component has been accumulated bias or the droop error of all parts below, causes the beat of the rear entirety of assembling and tilts huge, cause the non-constant of engine rotor right alignment, be difficult to meet request for utilization.
At present, domestic engine assembly still adopts traditional assembly method, tests manually as main take clock gauge.According to assembled in sequence engine from top to bottom, to assemble parts and measure afterwards, the entirety of guaranteeing at every turn to increase after parts can meet the threshold condition of right alignment, and then another parts are upwards installed.All using previous parts as benchmark, finally require overall right alignment within the specific limits at every turn.This method expends a large amount of time, and the possibility of doing over again is large, efficiency and one-time success rate that very impact is installed, and once successfully assembling needs 4 to 5 days conventionally.And, because be not optimum assembling position, conventionally need dismounting 4 to 5 times, also need workman to assemble with rich experiences, each assembling all needs to experience hot-working and cold working.So current aeromotor assembly method installation effectiveness is low, be difficult for installing, and after assembling, right alignment is poor, affects engine performance.
Summary of the invention
The deficiency existing for above-mentioned prior art, a kind of aeroengine rotor air supporting assembly method and device based on inductance measurement proposed, to solve the low problem of right alignment after aeroengine rotor assembling, reach right alignment after rotor assembling high, reduce vibration, be easy to install, flexibility ratio is high, the object of improving engine performance.
The object of the present invention is achieved like this:
An aeroengine rotor air supporting assembly method based on inductance measurement, this measuring method step is as follows:
Measured rotor is positioned over to aligning to be adjusted on the worktable that inclines fixing; Contact measuring the telescopic inductance sensor of axial datum clamp face and the axial datum clamp face of measured rotor, incline for adjusting; Measure the lever inductance sensor of datum clamp face radially and contact with datum clamp face radially, for aligning; Air-float turntable adjusts the worktable that inclines to drive measured rotor at the uniform velocity to rotate with the speed of 6~10r/min through aligning, the telescopic inductance sensor of measuring axial datum clamp face carries out equal interval sampling on the axial datum clamp face of measured rotor, measures the radially lever inductance sensor of datum clamp face and carry out equal interval sampling on the radially datum clamp face of measured rotor; Sampling number should meet 1000~2000 points of every circle; Sampled data on the radially datum clamp face of measured rotor, by Least Square Circle matching, is assessed to offset, the axial datum clamp face up-sampling data of measured rotor, by least square plane matching, are assessed to tilt quantity; According to the size of offset and angle, regulate aligning to adjust the aligning knob of the worktable that inclines; According to the size of tilt quantity and angle, regulate aligning to adjust the tune of worktable of the inclining knob that inclines, until aligning adjusts size that the worktable that inclines meets radial reference face offset within the scope of 0~3 μ m, axially the size of reference field tilt quantity is 0~2 " in scope; Axially install and measure the telescopic inductance sensor of face and the axially face of installing and measuring of measured rotor contacts by measuring, measurement radially installs and measures the lever inductance sensor of face and the radially face of installing and measuring of measured rotor contacts; Air-float turntable at the uniform velocity rotates with the speed of 6~10r/min, measure the telescopic inductance sensor that axially installs and measures face measured rotor axially install and measure equal interval sampling on face, the lever inductance sensor of measuring the face that radially installs and measures is is radially installing and measuring equal interval sampling on face respectively; Sampling number should meet 1000~2000 points of every circle; By measure the lever inductance sensor that radially installs and measures face in the data of the face that radially the installs and measures up-sampling of measured rotor by Least Square Circle matching and assess concentricity; By measure the telescopic inductance sensor that axially installs and measures face in the data of the face that axially the installs and measures up-sampling of measured rotor by least square plane matching and assess verticality; Combined axis, to radius and this measured rotor and final difference in height of assembling rotor of the face of installing and measuring, obtains this rotor to assembling the weights that affect of rear rotor coaxial degree; Measure respectively the required whole rotors of assembling, obtain each rotor to assembling the weights that affect of rear rotor coaxial degree; Adopt genetic algorithm to carry out vector optimization the weights of each rotor, obtain the angle of assembling of each rotor, the account form that affects weights of rotor coaxial degree is:
in formula: C represents that measured rotor radially installs and measures the concentricity of face,
represent radially to install and measure the eccentric angle in the face matching center of circle, H represents measured rotor and final difference in height of assembling rotor, R represents the radius of the face that axially installs and measures, P represents that measured rotor axially installs and measures the verticality of face, and θ represents the angle at the fit Plane peak place of the face that axially installs and measures.
A kind of structure of the aeroengine rotor air supporting assembling device based on inductance measurement is that air floating shaft system is nested on pedestal center, described air floating shaft system is by air-floating main shaft, worktable, platen on air-bearing shafts, air-bearing shafts pressing disc, grating ruler reading head and grating scale form, described worktable is configured on air-bearing shafts on platen upper end, on air-bearing shafts, platen is configured on air-floating main shaft upper end, air-floating main shaft is configured on air-bearing shafts pressing disc upper end, grating scale is nested on air-bearing shafts pressing disc outer shroud, grating ruler reading head fits over pedestal center lower inside admittedly, and be positioned at grating scale outside, aligning adjusts the worktable that inclines to be configured on air floating shaft system center, three-jaw fluid-pressure chuck is configured in aligning tune and inclines on worktable center.Left column and right column are symmetrically distributed in the both sides of air floating shaft system and are packed on pedestal.On left column, be set with to removable adjusting successively from top to bottom upper left mast web member and lower-left mast web member, the horizontal measuring staff level in upper left is nested on the mast web member of upper left, and the horizontal measuring staff in upper lever formula inductance sensor and upper left is connected; The horizontal measuring staff level in lower-left is nested on the mast web member of lower-left, and the horizontal measuring staff of lower lever inductance sensor and upper left is connected.On right column, be set with to removable adjusting successively from top to bottom upper right mast web member and bottom right mast web member, the horizontal measuring staff level in upper right is nested on the mast web member of upper right, and the horizontal measuring staff of upper telescopic inductance sensor and upper right is connected; The horizontal measuring staff level in bottom right is nested on the mast web member of bottom right, and the horizontal measuring staff of lower telescopic inductance sensor and bottom right is connected.
Compared with prior art, feature of the present invention is:
The present invention can obtain the right alignment weights of each rotor by measuring the concentricity of each rotor and verticality, again the right alignment weights of each rotor are carried out to vector optimization, just can obtain instructing setting angle, save 40% set-up time and expense, 98% one-step installation success ratio, measurable installation progress, improve engine stabilization, reduce engine luggine, save motor fuel consumption, reduce CO2 discharge, reduce engine noise and pollute.
Accompanying drawing explanation:
Fig. 1 is four gauge head measurement mechanism structural representations
Fig. 2 is floating shaft structure schematic diagram
Piece number in figure: 1-pedestal, 2-air floating shaft system, 2a-air-floating main shaft, 2b-worktable, platen on 2c-air-bearing shafts, 2d-air-bearing shafts pressing disc, 2e-grating ruler reading head, 2f-grating scale, 3-aligning is adjusted the worktable that inclines, 4-three-jaw fluid-pressure chuck, 5a-left column, 5b-right column, the horizontal measuring staff in 6a-lower-left, the horizontal measuring staff in 6b-bottom right, the horizontal measuring staff in 6c-upper left, the horizontal measuring staff in 6d-upper right, 7a-lower-left mast web member, 7b-bottom right mast web member, 7c-upper left mast web member, 7d-upper right mast web member, lever inductance sensor under 8a-, 8b-upper lever formula inductance sensor, telescopic inductance sensor under 9a-, the upper telescopic inductance sensor of 9b-.
Embodiment
Below in conjunction with accompanying drawing, the present invention is described in further detail:
Aeroengine rotor air supporting assembly method and a device based on inductance measurement, described method and apparatus is: three-jaw fluid-pressure chuck 4 is configured in aligning tune and inclines on worktable 3 centers.Left column 5a and right column 5b are symmetrically distributed in the both sides of air floating shaft system 2 and are packed on pedestal 1.On left column 5a, be set with to removable adjusting successively from top to bottom upper left mast web member 7c and lower-left mast web member 7a, it is upper that upper left horizontal measuring staff 6c level is nested in upper left mast web member 7c, and the horizontal measuring staff 6c in upper lever formula inductance sensor 8b and upper left is connected; It is upper that lower-left horizontal measuring staff 6a level is nested in lower-left mast web member 7a, and the horizontal measuring staff 6a in lower lever inductance sensor 8a and lower-left is connected.On right column 5b, be set with to removable adjusting successively from top to bottom upper right mast web member 7d and bottom right mast web member 7b, it is upper that upper right horizontal measuring staff 6d level is nested in upper right mast web member 7d, and upper telescopic inductance sensor 9b and the horizontal measuring staff 6d in upper right are connected; It is upper that bottom right horizontal measuring staff 6b level is nested in bottom right mast web member 7b, and lower telescopic inductance sensor 9a and the horizontal measuring staff 6b in bottom right are connected.Air floating shaft system 2 is nested on pedestal 1 center, described air floating shaft system 2 is by air-floating main shaft 2a, worktable 2b, platen 2c on air-bearing shafts, air-bearing shafts pressing disc 2d, grating ruler reading head 2e and grating scale 2f form, described worktable 2b is configured on air-bearing shafts on platen 2c upper end, on air-bearing shafts, platen 2c is configured on air-floating main shaft 2a upper end, air-floating main shaft 2a is configured on air-bearing shafts pressing disc 2d upper end, grating scale 2f is nested on air-bearing shafts pressing disc 2d outer shroud, grating ruler reading head 2e is configured in pedestal 1 center lower inside, and be positioned at grating scale 2f outside, air floating shaft system 2 drives measured rotor at the uniform velocity to rotate with the speed of 6~10r/min, lower telescopic inductance sensor 9a carries out equal interval sampling on the axial datum clamp face of measured rotor, lower lever inductance sensor 8a carries out equal interval sampling on the radially datum clamp face of measured rotor, sampling number should meet 1000~2000 points of every circle, sampled data on the radially datum clamp face of measured rotor is passed through to Least Square Circle matching, assess offset, the axial datum clamp face up-sampling data of measured rotor are passed through to least square plane matching, assess tilt quantity, aligning adjusts the worktable 3 that inclines to be configured on air floating shaft system 2 centers, according to the size of offset and angle, regulate aligning to adjust to incline worktable 3 until the size that meets radial reference face offset within the scope of 0~3 μ m, according to the size of tilt quantity and angle, regulate aligning to adjust to incline worktable 3 until the size that meets axial reference field tilt quantity 0~2 " in scope, upper right mast web member 7d is vertically nested in the upside of right column 5b, upper right horizontal measuring staff 6d level is nested on the mast web member 7d of upper right, upper telescopic inductance sensor 9b and the horizontal measuring staff 6d in upper right are connected, upper telescopic inductance sensor 9b is contacted with the axially face of installing and measuring of measured rotor, upper left mast web member 7c is vertically nested in the upside of left column 5a, upper left horizontal measuring staff 6c level is nested on the mast web member 7c of upper left, the horizontal measuring staff 6c in upper lever formula inductance sensor 8b and upper left is connected, upper lever formula inductance sensor 8b contacts with the radially face of installing and measuring of measured rotor, air floating shaft system 2 at the uniform velocity rotates with the speed of 6~10r/min, and upper telescopic inductance sensor 9b axially installs and measures equal interval sampling on face measured rotor, and upper lever formula inductance sensor 8b radially installs and measures equal interval sampling on face measured rotor, sampling number should meet 1000~2000 points of every circle, by upper lever formula inductance sensor 8b in the data of the face that radially the installs and measures up-sampling of measured rotor by Least Square Circle matching and assess concentricity, by upper telescopic inductance sensor 9b in the data of the face that axially the installs and measures up-sampling of measured rotor by least square plane matching and assess verticality, combined axis, to radius and this measured rotor and final difference in height of assembling rotor of the face of installing and measuring, obtains this rotor to assembling the weights that affect of rear rotor coaxial degree, measure respectively the required whole rotors of assembling, obtain each rotor to assembling the weights that affect of rear rotor coaxial degree, adopt genetic algorithm to carry out vector optimization the weights of each rotor, obtain the angle of assembling of each rotor, the account form that affects weights of rotor coaxial degree is:
in formula: C represents that measured rotor radially installs and measures the concentricity of face,
represent radially to install and measure the eccentric angle in the face matching center of circle, H represents measured rotor and final difference in height of assembling rotor, R represents the radius of the face that axially installs and measures, P represents that measured rotor axially installs and measures the verticality of face, and θ represents the angle at the fit Plane peak place of the face that axially installs and measures.
Claims (2)
1. the aeroengine rotor air supporting assembly method based on inductance measurement, is characterized in that this measuring method is: measured rotor is positioned over to aligning and adjusts on the worktable that inclines fixing; Contact measuring the telescopic inductance sensor of axial datum clamp face and the axial datum clamp face of measured rotor, incline for adjusting; Measure the lever inductance sensor of datum clamp face radially and contact with datum clamp face radially, for aligning; Air-float turntable adjusts the worktable that inclines to drive measured rotor at the uniform velocity to rotate with the speed of 6~10r/min through aligning, the telescopic inductance sensor of measuring axial datum clamp face carries out equal interval sampling on the axial datum clamp face of measured rotor, measures the radially lever inductance sensor of datum clamp face and carry out equal interval sampling on the radially datum clamp face of measured rotor; Sampling number should meet 1000~2000 points of every circle; Sampled data on the radially datum clamp face of measured rotor, by Least Square Circle matching, is assessed to offset, the axial datum clamp face up-sampling data of measured rotor, by least square plane matching, are assessed to tilt quantity; According to the size of offset and angle, regulate aligning to adjust the aligning knob of the worktable that inclines; According to the size of tilt quantity and angle, regulate aligning to adjust the tune of worktable of the inclining knob that inclines, until aligning adjusts size that the worktable that inclines meets radial reference face offset within the scope of 0~3 μ m, axially the size of reference field tilt quantity is 0~2 " in scope; Axially install and measure the telescopic inductance sensor of face and the axially face of installing and measuring of measured rotor contacts by measuring, measurement radially installs and measures the lever inductance sensor of face and the radially face of installing and measuring of measured rotor contacts; Air-float turntable at the uniform velocity rotates with the speed of 6~10r/min, measure the telescopic inductance sensor that axially installs and measures face measured rotor axially install and measure equal interval sampling on face, the lever inductance sensor of measuring the face that radially installs and measures is is radially installing and measuring equal interval sampling on face respectively; Sampling number should meet 1000~2000 points of every circle; By measure the lever inductance sensor that radially installs and measures face in the data of the face that radially the installs and measures up-sampling of measured rotor by Least Square Circle matching and assess concentricity; By measure the telescopic inductance sensor that axially installs and measures face in the data of the face that axially the installs and measures up-sampling of measured rotor by least square plane matching and assess verticality; Combined axis, to radius and this measured rotor and final difference in height of assembling rotor of the face of installing and measuring, obtains this rotor to assembling the weights that affect of rear rotor coaxial degree; Measure respectively the required whole rotors of assembling, obtain each rotor to assembling the weights that affect of rear rotor coaxial degree; Adopt genetic algorithm to carry out vector optimization the weights of each rotor, obtain the angle of assembling of each rotor, the account form that affects weights of rotor coaxial degree is:
in formula: C represents that measured rotor radially installs and measures the concentricity of face,
represent radially to install and measure the eccentric angle in the face matching center of circle, H represents measured rotor and final difference in height of assembling rotor, R represents the radius of the face that axially installs and measures, P represents that measured rotor axially installs and measures the verticality of face, and θ represents the angle at the fit Plane peak place of the face that axially installs and measures.
2. the aeroengine rotor air supporting assembling device based on inductance measurement is characterized in that air floating shaft system (2) is nested on pedestal (1) center, described air floating shaft system (2) is by air-floating main shaft (2a), worktable (2b), platen on air-bearing shafts (2c), air-bearing shafts pressing disc (2d), grating ruler reading head (2e) and grating scale (2f) form, described worktable (2b) is configured on platen on air-bearing shafts (2c) upper end, platen on air-bearing shafts (2c) is configured on air-floating main shaft (2a) upper end, air-floating main shaft (2a) is configured on air-bearing shafts pressing disc (2d) upper end, grating scale (2f) is nested on air-bearing shafts pressing disc (2d) outer shroud, grating ruler reading head (2e) fits over pedestal (1) center lower inside admittedly, and be positioned at grating scale (2f) outside, aligning adjusts the worktable (3) that inclines to be configured on air floating shaft system (2) center, three-jaw fluid-pressure chuck (4) is configured in aligning tune and inclines on worktable (3) center, left column (5a) and right column (5b) are symmetrically distributed in the both sides of air floating shaft system (2) and are packed on pedestal (1), on left column (5a), removable adjusting ground is set with upper left mast web member (7c) and lower-left mast web member (7a) successively from top to bottom, it is upper that the horizontal measuring staff in upper left (6c) level is nested in upper left mast web member (7c), and upper lever formula inductance sensor (8b) is connected with upper left horizontal measuring staff (6c), it is upper that the horizontal measuring staff in lower-left (6a) level is nested in lower-left mast web member (7a), and lower lever inductance sensor (8a) is connected with upper left horizontal measuring staff (6a), on right column (5b), removable adjusting ground is set with upper right mast web member (7d) and bottom right mast web member (7b) successively from top to bottom, it is upper that the horizontal measuring staff in upper right (6d) level is nested in upper right mast web member (7d), and upper telescopic inductance sensor (9b) is connected with upper right horizontal measuring staff (6d), it is upper that the horizontal measuring staff in bottom right (6b) level is nested in bottom right mast web member (7b), and lower telescopic inductance sensor (9a) is connected with bottom right horizontal measuring staff (6b).
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201410052106.6A CN103791815B (en) | 2014-02-14 | 2014-02-14 | Aero-engine rotor air floatation assembling method and device based on inductance measurement |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201410052106.6A CN103791815B (en) | 2014-02-14 | 2014-02-14 | Aero-engine rotor air floatation assembling method and device based on inductance measurement |
Publications (2)
Publication Number | Publication Date |
---|---|
CN103791815A true CN103791815A (en) | 2014-05-14 |
CN103791815B CN103791815B (en) | 2015-06-17 |
Family
ID=50667706
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN201410052106.6A Expired - Fee Related CN103791815B (en) | 2014-02-14 | 2014-02-14 | Aero-engine rotor air floatation assembling method and device based on inductance measurement |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN103791815B (en) |
Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107144212A (en) * | 2017-06-22 | 2017-09-08 | 西安爱生技术集团公司 | A kind of unmanned vehicle engine collar dimensions, geometric error detection means |
CN110608668A (en) * | 2019-09-25 | 2019-12-24 | 哈尔滨工业大学 | Three-point weighing-based aeroengine rotor assembly measuring device and double-target optimization method |
CN110608665A (en) * | 2019-09-25 | 2019-12-24 | 哈尔滨工业大学 | Four-point weighing-based aeroengine rotor assembly measuring device and double-target optimization method |
CN110608666A (en) * | 2019-09-25 | 2019-12-24 | 哈尔滨工业大学 | Aero-engine rotor assembly measuring device based on four-point weighing and three-target optimization method |
CN110608667A (en) * | 2019-09-25 | 2019-12-24 | 哈尔滨工业大学 | Three-point weighing-based aeroengine rotor assembly measuring device and three-target optimization method |
CN110906862A (en) * | 2019-12-02 | 2020-03-24 | 哈尔滨工业大学 | Geometric morphology and quality characteristic integrated measuring device for large-scale high-speed rotation equipment |
CN115077920A (en) * | 2022-06-21 | 2022-09-20 | 大连理工大学 | Multistage turbine part assembly deformation test equipment |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1635589A (en) * | 2004-10-22 | 2005-07-06 | 中国工程物理研究院应用电子学研究所 | A concentric assembly method and device for regulating same |
US7111407B2 (en) * | 2004-11-30 | 2006-09-26 | Tennessee Valley Authority | Vertical shaft alignment tool |
CN101799345A (en) * | 2010-03-02 | 2010-08-11 | 厦门大学 | Laser pressure sensor |
CN102401619A (en) * | 2011-11-22 | 2012-04-04 | 江苏太平洋精锻科技股份有限公司 | Radial runout detecting device of combining gear tooth part of automobile |
-
2014
- 2014-02-14 CN CN201410052106.6A patent/CN103791815B/en not_active Expired - Fee Related
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1635589A (en) * | 2004-10-22 | 2005-07-06 | 中国工程物理研究院应用电子学研究所 | A concentric assembly method and device for regulating same |
US7111407B2 (en) * | 2004-11-30 | 2006-09-26 | Tennessee Valley Authority | Vertical shaft alignment tool |
CN101799345A (en) * | 2010-03-02 | 2010-08-11 | 厦门大学 | Laser pressure sensor |
CN102401619A (en) * | 2011-11-22 | 2012-04-04 | 江苏太平洋精锻科技股份有限公司 | Radial runout detecting device of combining gear tooth part of automobile |
Cited By (12)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107144212A (en) * | 2017-06-22 | 2017-09-08 | 西安爱生技术集团公司 | A kind of unmanned vehicle engine collar dimensions, geometric error detection means |
CN110608668A (en) * | 2019-09-25 | 2019-12-24 | 哈尔滨工业大学 | Three-point weighing-based aeroengine rotor assembly measuring device and double-target optimization method |
CN110608665A (en) * | 2019-09-25 | 2019-12-24 | 哈尔滨工业大学 | Four-point weighing-based aeroengine rotor assembly measuring device and double-target optimization method |
CN110608666A (en) * | 2019-09-25 | 2019-12-24 | 哈尔滨工业大学 | Aero-engine rotor assembly measuring device based on four-point weighing and three-target optimization method |
CN110608667A (en) * | 2019-09-25 | 2019-12-24 | 哈尔滨工业大学 | Three-point weighing-based aeroengine rotor assembly measuring device and three-target optimization method |
CN110608665B (en) * | 2019-09-25 | 2020-08-07 | 哈尔滨工业大学 | Four-point weighing-based aeroengine rotor assembly measuring device and double-target optimization method |
CN110608666B (en) * | 2019-09-25 | 2020-08-07 | 哈尔滨工业大学 | Aero-engine rotor assembly measuring device based on four-point weighing and three-target optimization method |
CN110608667B (en) * | 2019-09-25 | 2020-08-07 | 哈尔滨工业大学 | Three-point weighing-based aeroengine rotor assembly measuring device and three-target optimization method |
CN110608668B (en) * | 2019-09-25 | 2020-08-25 | 哈尔滨工业大学 | Three-point weighing-based aeroengine rotor assembly measuring device and double-target optimization method |
CN110906862A (en) * | 2019-12-02 | 2020-03-24 | 哈尔滨工业大学 | Geometric morphology and quality characteristic integrated measuring device for large-scale high-speed rotation equipment |
CN110906862B (en) * | 2019-12-02 | 2022-01-25 | 哈尔滨工业大学 | Geometric morphology and quality characteristic integrated measuring device for large-scale high-speed rotation equipment |
CN115077920A (en) * | 2022-06-21 | 2022-09-20 | 大连理工大学 | Multistage turbine part assembly deformation test equipment |
Also Published As
Publication number | Publication date |
---|---|
CN103791815B (en) | 2015-06-17 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN103791816B (en) | Aircraft engine rotor assembly method and device based on concentricity and perpendicularity measurement | |
CN103808251B (en) | Method and device for assembling aircraft engine rotors | |
CN103808252B (en) | Air floatation assembling method and device based on gantry structure for rotors of aero-engine | |
CN103791815B (en) | Aero-engine rotor air floatation assembling method and device based on inductance measurement | |
CN103790647A (en) | Hydraulic capturing and clamping type aircraft engine rotor assembling method and device based on inductance sensing | |
CN103899367A (en) | Aero-engine rotor stack-assembling method and device | |
CN103806958A (en) | Hydraulic grasping clamping type aircraft engine rotor assembly method and device based on inductosyn | |
CN103776365A (en) | Aero-engine multiaxis rotor assembling method and device based on radial and axial datum | |
CN103791819A (en) | Aero-engine rotor assembly method and device based on aligning and tilt adjusting rotary platform | |
CN103791814A (en) | Double-stand-column aero-engine rotor electric drive assembly method and device based on eddy current sensing | |
CN103790652A (en) | Aircraft engine rotor air floating assembling method and device based on optical-electricity encoder angle measuring | |
CN103790646A (en) | Aircraft engine rotor electric driving magnetic levitation assembling method and device based on optical-electricity encoder angle measuring | |
CN103776368B (en) | Gas and magnetism composite supporting type aero-engine rotor assembling method and device based on concentricity optimization | |
CN103791821B (en) | Based on radial error and the aeroengine rotor assembly method axially tilted and device | |
CN103791813B (en) | Pneumatic inward-clamped aero-engine rotor assembly method and device based on capacitance sensing measurement | |
CN103790648A (en) | Aircraft engine rotor assembling method and device based on multi-component concentricity optimizing | |
CN103791825B (en) | Assembly method and device for aero-engine rotors based on double-reference measuring | |
CN103790645A (en) | Method and device for assembling aero-engine rotors based on concentricity and perpendicularity evaluating and optimizing | |
CN103776367B (en) | Aero-engine multi-shaft rotor assembling method and device based on genetic algorithm optimization | |
CN103791820B (en) | Based on aeroengine rotor assembly method and the device of the stacking principle of vector | |
CN103791830A (en) | Aero-engine rotor assembly method and device based on capacitance measurement and circular grating angle measurement | |
CN103790644A (en) | Aircraft engine rotor assembling method and device based on space vector projection | |
CN103791812A (en) | Aero-engine rotor assembly method and device based on capacitance sensing and four-claw hydraulic chuck clamping | |
CN103791818B (en) | Hydraulic clamping type aircraft engine rotor assembly method and device based on concentricity measurement | |
CN103791822B (en) | Stacking assembly method and device for aero-engine rotors based on space multi-vector optimization |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C06 | Publication | ||
PB01 | Publication | ||
C10 | Entry into substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20150617 Termination date: 20220214 |
|
CF01 | Termination of patent right due to non-payment of annual fee |