CN202916093U - Cylindrical roller bearing retainer dynamic performance test device - Google Patents

Cylindrical roller bearing retainer dynamic performance test device Download PDF

Info

Publication number
CN202916093U
CN202916093U CN 201220464262 CN201220464262U CN202916093U CN 202916093 U CN202916093 U CN 202916093U CN 201220464262 CN201220464262 CN 201220464262 CN 201220464262 U CN201220464262 U CN 201220464262U CN 202916093 U CN202916093 U CN 202916093U
Authority
CN
China
Prior art keywords
test
bearing
main shaft
roller bearing
dynamic performance
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.)
Expired - Fee Related
Application number
CN 201220464262
Other languages
Chinese (zh)
Inventor
邓四二
杨海生
刘苏亚
孙朝阳
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Henan University of Science and Technology
Original Assignee
Henan University of Science and Technology
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Henan University of Science and Technology filed Critical Henan University of Science and Technology
Priority to CN 201220464262 priority Critical patent/CN202916093U/en
Application granted granted Critical
Publication of CN202916093U publication Critical patent/CN202916093U/en
Anticipated expiration legal-status Critical
Expired - Fee Related legal-status Critical Current

Links

Images

Landscapes

  • Testing Of Devices, Machine Parts, Or Other Structures Thereof (AREA)

Abstract

The utility model provides a cylindrical roller bearing retainer dynamic performance test device which comprises a test subject, an electric main shaft, a frequency converter, a hydraulic loading system, a computer monitoring system and a data acquisition system. The electric main shaft and the hydraulic loading system are respectively connected with the test subject. The frequency converter is connected with the electric main shaft. The electric main shaft provides power for the test subject. The hydraulic loading system provides a test load for the test subject. After the loading of the hydraulic loading system, a signal measured by a measuring device on the test subject and test parameters of the electric main shaft and the frequency converter are respectively input into the data acquisition system. A signal output end of the data acquisition system is input into the computer monitoring system. A control signal of the computer monitoring system is input into the frequency converter. The rotation speed of the electric main shaft is controlled by the frequency converter. According to the utility model, an eddy current displacement sensor is used; the cylindrical roller bearing retainer dynamic performance test device has the advantages of good reliability, wide measuring range, high sensitivity, high resolution, fast response effect and strong anti-interference ability and is not affected by greasy dirt and other mediums; the test subject uses a closed box body structure, which can effectively prevent impurities from entering the box body.

Description

The cylinder roller bearing retainer dynamic performance test apparatus
Technical field
The utility model relates to a kind of tester for testing, specifically a kind of cylinder roller bearing retainer dynamic performance test apparatus.
Background technology
Cylinder roller bearing is widely used in the mechanical systems such as variator, motor, instrument and meter, household electrical appliance.As very crucial parts of this class bearing, the dynamic property of retainer and reliability can have influence on the serviceability of whole bearing.Unreasonable when the retainer structural design, manufacturing accuracy is not high and operation conditions when bad, can cause the dynamic performance indexs such as retainer barycenter dynamic trajectory, the rate of skidding, pitch angle and angle of skew extremely unstable, can cause retainer fracture even bearing failure when serious.Therefore, monitoring retainer dynamic property seems extremely important in analyzing the bearing dynamic perfromance.
Because retainer has very high uncertainty in motion process, be difficult to the retainer under the motion state is tested, therefore, research to retainer Dynamic performance examination aspect is less, mostly launch from theoretical aspect, and do not have enough test figure theoretical analysis result to verify, greatly limited the flow of research of cylinder roller bearing retainer.
The utility model content
For the problem that is difficult in the prior art cylinder roller bearing retainer under the motion state is tested, the utility model provides a kind of cylinder roller bearing retainer dynamic performance test apparatus.
For addressing the above problem, the technical solution adopted in the utility model is: a kind of cylinder roller bearing retainer dynamic performance test apparatus, comprise trial body, the electricity main shaft, frequency converter, hydraulic loading system, computer supervisory control system and data acquisition system (DAS), the electricity main shaft is connected with trial body with hydraulic loading system and is connected, frequency converter is connected with electric main shaft, the electricity main shaft provides power for trial body, hydraulic loading system provides test load for trial body, the signal that measurement mechanism on the hydraulic loading system post loading test main body is measured and the test parameters of electric main shaft and frequency converter input to respectively data acquisition system (DAS), data acquisition system (DAS) signal output part input computer supervisory control system, the control signal input converter of computer supervisory control system is by the rotating speed of the electric main shaft of frequency converter realization control;
Described hydraulic loading system is arranged on the trial body, formed by axial charging assembly and radial loaded assembly, trial body comprises testing table base, left upper cover, load bearings, measurement mechanism, spring bearing, test axle system and upper right lid, described test axle is to comprise test axle, end cap, lining, fuel-feeding nozzle and test bearing, described test bearing is cylinder roller bearing, the test bearing inner ring is installed on the test axle, locked by set nut, the test bearing outer ring is installed in the lining, compressed by end cap, fuel-feeding nozzle is installed in the test axle; Load bearings and spring bearing are installed in respectively the two ends of test axle, and axially the loaded load of charging assembly and radial loaded assembly acts on respectively on the load bearings, and left upper cover and upper right lid are arranged on the top of trial body, make trial body form enclosed construction;
Described measurement mechanism is arranged on a side of test bearing, measurement mechanism comprises temperature sensor I, displacement transducer, displacement transducer mounting bracket and for detection of the speed pickup of test bearing retainer rotating speed, the temperature sensor I is arranged on the test bearing outer ring, displacement transducer is installed in radially reaching on the axial plane of displacement transducer mounting bracket, and the displacement sensor end is arranged on the test bearing outer ring.
The utility model, described speed pickup is comprised of the magnetic patch that is symmetricly set on test bearing retainer both sides, Hall element and Hall element mounting bracket, two magnetic patch are separated by 180 °, Hall element is fixed by the Hall element mounting bracket, and the signal that is used for reception retainer both sides magnetic patch calculates the rotating speed of retainer.
The utility model, described axial charging assembly is the closed assembly that has a style of one's own, be installed between testing table base and the left upper cover with the seam form, axially charging assembly comprises loading pipeline, hand-hydraulic cylinder, tensimeter, pressure transducer I and mounting bracket, the hand-hydraulic cylinder links to each other with the loading pipeline, load pipeline and be provided with pressure transducer and tensimeter, pressure transducer is fixed on the mounting bracket.
The utility model, described radial loaded assembly and left upper cover are integrated.
The utility model, described trial body is driven by elastic coupling by electric main shaft, is that the test bearing of 60~120mm is tested to internal diameter.
The utility model, described load bearings and spring bearing are deep groove ball bearing.
The utility model, described test unit also comprises the equipment lubrication system, the equipment lubrication system comprises the fuel tank I, the fuel tank II, oil feed pump, surplus valve, dump pump, return oil filter, the fuel feeding oil filter, refrigeratory, temperature sensor II and pressure transducer II, pipeline I one end is communicated with the fuel tank I, the pipeline I other end passes through oil feed pump successively, surplus valve and fuel feeding oil filter are communicated with the fuel tank II, the fuel tank II is communicated with the pipeline II, be provided with temperature sensor II and pressure transducer II on the pipeline II, the pipeline II is connected to come the lubrication experiment bearing with supplying oil burner nozzle, test axle in sealing is in the casing, scavenge pipe is housed, one end of scavenge pipe is communicated with the fuel tank I, is disposed with return oil filter and dump pump on the scavenge pipe;
The utility model, described displacement transducer are eddy current displacement sensor.
The utility model, the interior supporting erecting tools that is provided with of described test axle system.
The utility model, described Hall element is encapsulated in the end cap.
The beneficial effects of the utility model are:
1, this device is by arranging trial body, the electricity main shaft, frequency converter, hydraulic loading system, computer supervisory control system and data acquisition system (DAS), the electricity main shaft is connected with trial body with hydraulic loading system and is connected, frequency converter is connected with electric main shaft, the electricity main shaft provides power for trial body, hydraulic loading system provides test load for trial body, the signal that measurement mechanism on the hydraulic loading system post loading test main body is measured and the test parameters of electric main shaft and frequency converter input to respectively data acquisition system (DAS), data acquisition system (DAS) signal output part input computer supervisory control system, the control signal input converter of computer supervisory control system, by the rotating speed of the electric main shaft of frequency converter realization control, this test unit good reliability, measurement range is wide, highly sensitive, resolution is high, fast response time; Secondly, in trial body, test bearing is installed in the centre of test axle, load bearings and spring bearing are installed respectively in both sides, axially, radial load at first puts on load bearings, be delivered on the test axle by load bearings, and then be applied to test bearing, avoid load to directly act on test bearing and affected the performance test results; Measurement mechanism is arranged on a side of test bearing, comprise temperature sensor, displacement transducer and speed pickup, structure is installed rationally, can not only survey the retainer rotating speed, can also survey the dynamic properties such as retainer barycenter dynamic trajectory, the rate of skidding, pitch angle and angle of skew, contain the whole dynamic properties of retainer, and accuracy of detection is high, retainer barycenter displacement measurement precision can reach 0.001mm, makes measurement more reliable;
2, this test unit trial body is driven by elastic coupling by high-frequency motor spindle, can be that the test bearing of 60~120mm is tested to internal diameter, and trial body is enclosed construction, can avoid impurity to enter casing.
Description of drawings
Fig. 1 the utility model principle of work block diagram;
Fig. 2 the utility model trial body structural drawing;
Fig. 3 the utility model test axle is sketch;
Fig. 4 the utility model test bearing scheme of installation;
Fig. 5 the utility model eddy current displacement sensor scheme of installation;
Fig. 6 the utility model retainer speed measuring device-Hall element scheme of installation;
Fig. 7 the utility model axial loading device structural drawing;
Fig. 8 the utility model lubrication system works schematic diagram;
Fig. 9 the utility model lubricating system oil temperature control principle drawing;
Reference numeral: 1, the testing table base, 2, axial charging assembly, 3, left upper cover, 4, the radial loaded assembly, 5, load bearings, 6, measurement mechanism, 7, spring bearing, 8, test axle system (in the double dot dash line frame), 9, upper right lid, 10, the fuel tank I, 11, the fuel tank II, 12, oil feed pump, 13, surplus valve, 14, dump pump, 15, return oil filter, 16, the fuel feeding oil filter, 17, refrigeratory, 18, the temperature sensor II, 19, the pressure transducer II, 20, scavenge pipe, 21, the pipeline I, 22, the pipeline II, 2-1, load pipeline, 2-2, the hand-hydraulic cylinder, 2-3, tensimeter, 2-4, the pressure transducer I, 2-5, mounting bracket, 6-1, the temperature sensor I, 6-2, displacement transducer, 6-3, the displacement transducer mounting bracket, 6-4, the Hall element mounting bracket, 6-5, Hall element, 6-21, eddy current displacement sensor, 6-31, the eddy current displacement sensor mounting bracket, 8-1, the test axle, 8-2, end cap, 8-3, lining, 8-4, set nut, 8-5, fuel-feeding nozzle, 8-6, test bearing, 8-7, erecting tools.
Embodiment
Below in conjunction with specific embodiment the utility model is further elaborated.
As shown in the figure, a kind of cylinder roller bearing retainer dynamic performance test apparatus, it is characterized in that: comprise trial body, the electricity main shaft, frequency converter, hydraulic loading system, computer supervisory control system and data acquisition system (DAS), the electricity main shaft is connected with trial body with hydraulic loading system and is connected, frequency converter is connected with electric main shaft, the electricity main shaft provides power for trial body, hydraulic loading system provides test load for trial body, the signal that measurement mechanism on the hydraulic loading system post loading test main body is measured and the test parameters of electric main shaft and frequency converter input to respectively data acquisition system (DAS), data acquisition system (DAS) signal output part input computer supervisory control system, the control signal input converter of computer supervisory control system is by the rotating speed of the electric main shaft of frequency converter realization control;
Described hydraulic loading system is arranged on the trial body, formed by axial charging assembly 2 and radial loaded assembly 4, trial body comprises testing table base 1, left upper cover 3, load bearings 5, measurement mechanism 6, spring bearing 7, the test axle is 8 and upper right lid 9, described test axle is 8 to comprise test axle 8-1, end cap 8-2, lining 8-3, fuel-feeding nozzle 8-5 and test bearing 8-6, described test bearing 8-6 is cylinder roller bearing, test bearing 8-6 inner ring is installed on the test axle 8-1, locked by set nut 8-4, test bearing 8-6 outer ring is installed in the lining 8-3, compressed by end cap 8-2, fuel-feeding nozzle 8-5 is installed in the test axle 8-1; Load bearings 5 and spring bearing 7 are installed in respectively the two ends of test axle 8-1, axially the loaded load of charging assembly 2 and radial loaded assembly 4 acts on respectively on the load bearings 5, left upper cover 3 and upper right lid 9 are arranged on the top of trial body, make trial body form enclosed construction;
Described measurement mechanism 6 is arranged on the side of test bearing 8-6, measurement mechanism 6 comprises temperature sensor I 6-1, displacement transducer 6-2, displacement transducer mounting bracket 6-3 and for detection of the speed pickup of test bearing 8-6 retainer rotating speed, temperature sensor I 6-1 is arranged on the test bearing 8-6 outer ring, displacement transducer 6-2 is installed in radially reaching on the axial plane of displacement transducer mounting bracket 6-3, and displacement transducer 6-2 measuring junction is arranged on the test bearing 8-6 outer ring;
Described speed pickup is comprised of the magnetic patch that is symmetricly set on test bearing 8-6 retainer both sides, Hall element 6-5 and Hall element mounting bracket 6-4, two magnetic patch are separated by 180 °, Hall element 6-5 fixes by Hall element mounting bracket 6-4, and the signal that is used for reception retainer both sides magnetic patch calculates the rotating speed of retainer;
Described axial charging assembly 2 is the closed assembly that has a style of one's own, be installed between testing table base 1 and the left upper cover 3 with the seam form, axially charging assembly 2 comprises loading pipeline 2-1, hand-hydraulic cylinder 2-2, tensimeter 2-3, pressure transducer I 2-4 and mounting bracket 2-5, hand-hydraulic cylinder 2-2 links to each other with loading pipeline 2-1, load pipeline 2-1 and be provided with pressure transducer 2-4 and tensimeter 2-3, pressure transducer 2-4 is fixed on the mounting bracket 2-5;
Described axial charging assembly 4 is integrated with left upper cover 3;
Described trial body is driven by elastic coupling by electric main shaft, is that the test bearing of 60~120mm is tested to internal diameter;
Described load bearings 5 and spring bearing 7 are deep groove ball bearing;
Described test unit also comprises the equipment lubrication system, the equipment lubrication system comprises fuel tank I 10, fuel tank II 11, oil feed pump 12, surplus valve 13, dump pump 14, return oil filter 15, fuel feeding oil filter 16, refrigeratory 17, temperature sensor II 18 and pressure transducer II 19, pipeline I 21 1 ends are communicated with fuel tank I 10, pipeline I 21 other ends are successively by oil feed pump 12, surplus valve 13 and fuel feeding oil filter 16 are communicated with fuel tank II 11, fuel tank II 11 is communicated with pipeline II 22, be provided with temperature sensor II 18 and pressure transducer II 19 on the pipeline II 22, pipeline II 22 is connected to come lubrication experiment bearing 8-6 with supplying oil burner nozzle 8-5, test axle in sealing is in 8 casings, scavenge pipe 20 is housed, one end of scavenge pipe 20 is communicated with fuel tank I 10, is disposed with return oil filter 15 and dump pump 14 on the scavenge pipe 20;
Described displacement transducer 6-2 is eddy current displacement sensor 6-21;
Described test axle is the 8 interior supporting erecting tools 8-7 that are provided with;
Described Hall element 6-5 is encapsulated among the end cap 8-2.
As shown in Figure 1, this test unit comprises trial body, electric main shaft, frequency converter, equipment lubrication system, hydraulic loading system, electric control system, computer supervisory control system and data acquisition system (DAS).Trial body can be simulated different tests operating mode (rotating speed) by frequency converter, electric main shaft and electric control system; Hydraulic loading system provides test load for test bearing, the real work load of simulation test bearing; The equipment lubrication system provides lubricated for test bearing and block bearing, and by to the heating of fuel tank lubricating oil, thereby to the test bearing heating, the working temperature of simulation test bearing, native system also possesses the function of carrying out cooling and lubricating for block bearing; Computer supervisory control system can monitor process of the test, normally carries out with warranty test; The record of test parameters and processing are finished by data acquisition system (DAS);
This test unit trial body structure as shown in Figure 2, trial body is driven by elastic coupling by high-frequency motor spindle, can be that the test bearing of 60~120mm is tested to internal diameter, test unit base 1 is fixed in the earth, axially charging assembly 2 is used for applying axial load, eliminates end-play to the impact of test; Left upper cover 3 and upper right lid 9 are positioned at trial body top, make trial body form enclosed construction, avoid impurity to enter casing; Radial loaded assembly 4 applies radial load for test bearing; The bearing temperature that measurement mechanism 6 is used under the surveying work state, and retainer is axial, radial displacement; Spring bearing 7 is in the 8(double dot dash line frame for the test axle) provide support;
This test unit test axle be sketch as shown in Figure 3, the bearing at two ends, the left and right sides is respectively load bearings 5, spring bearing 7, the type of load bearings and spring bearing is deep groove ball bearing; Axially, radial load at first puts on load bearings 5, is delivered on the test axle 8-1 by load bearings 5, and then is applied to test bearing 8-6, middle bearing is test bearing 8-6, test bearing 8-6 type is angular contact ball bearing;
This test unit test bearing scheme of installation as shown in Figure 4, test bearing 8-6 inner ring is installed on the test axle 8-1, is locked by set nut 8-4; Test bearing 8-6 is installed in the lining 8-3, compressed by end cap 8-2, the relative position of test bearing 8-6 Internal and external cycle guarantees by the seam of lining 8-3, during test, realize rotary actuation by test axle 8-1 motoring ring test bearing 8-6 inner ring, test bearing 8-6 outer ring is relatively static; Temperature sensor I 6-1 leans against on the test bearing 8-6 outer ring and realizes temperature survey; Fuel-feeding nozzle 8-5 is installed on provides ring lower lubricated in the test axle 8-1; Displacement transducer 6-2 is installed in radially reaching on the axial plane of displacement transducer mounting bracket 6-3, realizes the measurement to test bearing 8-6 retainer barycenter dynamic trajectory and pitch angle and angle of skew; During installation, because test bearing 8-6 is the separated type bearing, specialized designs is supporting erecting tools is to realize the correct installation of test bearing 8-6 and relevant original paper;
The eddy current displacement sensor scheme of installation as shown in Figure 5, the motion of retainer in X-Y plane radially measured by 2 orthogonal eddy current displacement sensor 6-21, at axial location, pitch angle and barycenter axial displacement that other 3 eddy current displacement sensor 6-21 are used for measuring retainer have been installed, because eddy current displacement sensor 6-21 induction area is large, in measuring process, should avoid non-measurement thing to appear in the measurement range of sensor, in order to avoid affect picking up of measuring-signal, cause the signal quality that detects undesirable, in addition, when using together, a plurality of sensors should avoid the too close of installation of sensors, and when measured material does not have enough sizes, width is less than 2 times of the sensor probe diameter, thickness is during less than 1mm, the curve of the reaction that obtains is false, false, for ease of the installation adjustment of eddy current displacement sensor 6-21, eddy current displacement sensor mounting bracket 6-31 is slit into two halves along the thick dashed line position after machining;
This test unit retainer speed measuring device-Hall element scheme of installation as shown in Figure 6, the interval 180 on the reference field of test bearing 8-6 retainer
Figure 201220464262X100002DEST_PATH_IMAGE002
Symmetry is inlayed two
Figure DEST_PATH_IMAGE004
The magnetic patch of 3mm, be that Hall element is encapsulated in as shown in Figure 6 the workpiece with magneto sensor, test bearing 8-6 outer ring is pushed down in one side end face of this workpiece, limit test bearing 8-6 on suitable measuring position, the Hall element mounting bracket 6-4 that the measure portion of Hall element 6-5 places brass to make, three transmission lines are then drawn by adjacent groove;
This test unit axial loading device structure as shown in Figure 7, it is 8 axial float for the Elimination test axle, must be 8 axially to load to testing axle before the test, the axial loading of test bearing, radial loaded, adopt the diaphragm type oil cylinder to apply operating load, hydraulic loading system hand-hydraulic cylinder 2-2 sends pressure oil into respectively axial loading, radial loaded pressure-loaded pipeline 2-1, produce displacement by rubber membrane distortion, piston, axial, radial load be applied to respectively the axial loading cover of load bearings and radially on the lining, and then be delivered on the test bearing;
This test unit lubrication system works principle as shown in Figure 8, the native system principle of work is: oil feed pump 12 is sent into fuel tank II 11 with the oil of fuel tank I 10 through surplus valve 13, fuel feeding oil filter 16, pass through again pipeline, by supplying oil burner nozzle 8-5 lubrication test bearing 8-6, test axle in sealing is in 8 casings, and scavenge pipe is housed, and by dump pump 14 oil is withdrawn into fuel tank I 10, in order to protect dump pump, be provided with refrigeratory 17 and return oil filter 15 at pipeline; Also be provided with temperature sensor II 18 and pressure transducer II 19 in the pipeline simultaneously, this lubricating system oil temperature control principle as shown in Figure 9;
This lubricating system oil temperature control principle as shown in Figure 9, adopt computing machine or manually provide parameter to the Intelligent PID Control instrument, the break-make of Intelligent Instrument control solid-state relay, make heating element work, temperature sensor is measured temperature signal and is fed back to Intelligent Instrument and carry out PID and regulate, thereby forms the closed-loop control to temperature;
Data acquisition system (DAS) is used for recording and the Processing Test data, the experimental data that observation interface can show comprises: test bearing retainer barycenter radial displacement figure, retainer pitch angle, retainer angle of skew, the retainer rate of skidding, the user can be in observation interface window entering spindle rotating speed and test duration, and records as required desired data.

Claims (10)

1. cylinder roller bearing retainer dynamic performance test apparatus, it is characterized in that: comprise trial body, the electricity main shaft, frequency converter, hydraulic loading system, computer supervisory control system and data acquisition system (DAS), the electricity main shaft is connected with trial body with hydraulic loading system and is connected, frequency converter is connected with electric main shaft, the electricity main shaft provides power for trial body, hydraulic loading system provides test load for trial body, the signal that measurement mechanism on the hydraulic loading system post loading test main body is measured and the test parameters of electric main shaft and frequency converter input to respectively data acquisition system (DAS), data acquisition system (DAS) signal output part input computer supervisory control system, the control signal input converter of computer supervisory control system is by the rotating speed of the electric main shaft of frequency converter realization control;
Described hydraulic loading system is arranged on the trial body, formed by axial charging assembly (2) and radial loaded assembly (4), trial body comprises testing table base (1), left upper cover (3), load bearings (5), measurement mechanism (6), spring bearing (7), test axle system (8) and upper right lid (9), described test axle system (8) comprises test axle (8-1), end cap (8-2), lining (8-3), fuel-feeding nozzle (8-5) and test bearing (8-6), described test bearing (8-6) is cylinder roller bearing, test bearing (8-6) inner ring is installed on the test axle (8-1), locked by set nut (8-4), test bearing (8-6) outer ring is installed in the lining (8-3), compressed by end cap (8-2), fuel-feeding nozzle (8-5) is installed in the test axle (8-1); Load bearings (5) and spring bearing (7) are installed in respectively the two ends of test axle (8-1), axially the loaded load of charging assembly (2) and radial loaded assembly (4) acts on respectively on the load bearings (5), left upper cover (3) and upper right lid (9) are arranged on the top of trial body, make trial body form enclosed construction;
Described measurement mechanism (6) is arranged on a side of test bearing (8-6), measurement mechanism (6) comprises temperature sensor I (6-1), displacement transducer (6-2), displacement transducer mounting bracket (6-3) and for detection of the speed pickup of test bearing (8-6) retainer rotating speed, temperature sensor I (6-1) is arranged on test bearing (8-6) outer ring, displacement transducer (6-2) is installed in radially reaching on the axial plane of displacement transducer mounting bracket (6-3), and displacement transducer (6-2) measuring junction is arranged on test bearing (8-6) outer ring.
2. a kind of cylinder roller bearing retainer dynamic performance test apparatus as claimed in claim 1, it is characterized in that: described speed pickup is comprised of the magnetic patch that is symmetricly set on test bearing (8-6) retainer both sides, Hall element (6-5) and Hall element mounting bracket (6-4), two magnetic patch are separated by 180 °, Hall element (6-5) is fixing by Hall element mounting bracket (6-4), and the signal that is used for reception retainer both sides magnetic patch calculates the rotating speed of retainer.
3. a kind of cylinder roller bearing retainer dynamic performance test apparatus as claimed in claim 1, it is characterized in that: described axial charging assembly (2) is the closed assembly that has a style of one's own, be installed between testing table base (1) and the left upper cover (3) with the seam form, axially charging assembly (2) comprises loading pipeline (2-1), hand-hydraulic cylinder (2-2), tensimeter (2-3), pressure transducer I (2-4) and mounting bracket (2-5), hand-hydraulic cylinder (2-2) links to each other with loading pipeline (2-1), load pipeline (2-1) and be provided with pressure transducer (2-4) and tensimeter (2-3), pressure transducer (2-4) is fixed on the mounting bracket (2-5).
4. a kind of cylinder roller bearing retainer dynamic performance test apparatus as claimed in claim 1 is characterized in that: described radial loaded assembly (4) is integrated with left upper cover (3).
5. a kind of cylinder roller bearing retainer dynamic performance test apparatus as claimed in claim 1, it is characterized in that: described trial body is driven by elastic coupling by electric main shaft, is that the test bearing of 60~120mm is tested to internal diameter.
6. a kind of cylinder roller bearing retainer dynamic performance test apparatus as claimed in claim 1, it is characterized in that: described load bearings (5) and spring bearing (7) are deep groove ball bearing.
7. a kind of cylinder roller bearing retainer dynamic performance test apparatus as claimed in claim 1, it is characterized in that: described test unit also comprises the equipment lubrication system, the equipment lubrication system comprises fuel tank I (10), fuel tank II (11), oil feed pump (12), surplus valve (13), dump pump (14), return oil filter (15), fuel feeding oil filter (16), refrigeratory (17), temperature sensor II (18) and pressure transducer II (19), pipeline I (21) one ends are communicated with fuel tank I (10), pipeline I (21) other end is successively by oil feed pump (12), surplus valve (13) and fuel feeding oil filter (16) are communicated with fuel tank II (11), fuel tank II (11) is communicated with pipeline II (22), be provided with temperature sensor II (18) and pressure transducer II (19) on the pipeline II (22), pipeline II (22) is connected to come lubrication experiment bearing (8-6) with supplying oil burner nozzle (8-5), in test axle system (8) casing of sealing, scavenge pipe (20) is housed, one end of scavenge pipe (20) is communicated with fuel tank I (10), is disposed with return oil filter (15) and dump pump (14) on the scavenge pipe (20).
8. a kind of cylinder roller bearing retainer dynamic performance test apparatus as claimed in claim 1, it is characterized in that: described displacement transducer (6-2) is eddy current displacement sensor (6-21).
9. a kind of cylinder roller bearing retainer dynamic performance test apparatus as claimed in claim 1 is characterized in that: the supporting erecting tools (8-7) that is provided with in the described test axle system (8).
10. a kind of cylinder roller bearing retainer dynamic performance test apparatus as claimed in claim 2, it is characterized in that: described Hall element (6-5) is encapsulated in the end cap (8-2).
CN 201220464262 2012-09-13 2012-09-13 Cylindrical roller bearing retainer dynamic performance test device Expired - Fee Related CN202916093U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN 201220464262 CN202916093U (en) 2012-09-13 2012-09-13 Cylindrical roller bearing retainer dynamic performance test device

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN 201220464262 CN202916093U (en) 2012-09-13 2012-09-13 Cylindrical roller bearing retainer dynamic performance test device

Publications (1)

Publication Number Publication Date
CN202916093U true CN202916093U (en) 2013-05-01

Family

ID=48164398

Family Applications (1)

Application Number Title Priority Date Filing Date
CN 201220464262 Expired - Fee Related CN202916093U (en) 2012-09-13 2012-09-13 Cylindrical roller bearing retainer dynamic performance test device

Country Status (1)

Country Link
CN (1) CN202916093U (en)

Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102866013A (en) * 2012-09-13 2013-01-09 河南科技大学 Dynamic performance testing device for cylindrical roller bearing retainer
CN105021400A (en) * 2015-07-07 2015-11-04 武汉理工大学 Intermediate bearing with hydraulic loading device used for ship cardan shaft system test stand
CN109115496A (en) * 2018-09-03 2019-01-01 重庆长江轴承股份有限公司 A kind of automobile speed variator bearing static strength and resistance to vibration detection device

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102866013A (en) * 2012-09-13 2013-01-09 河南科技大学 Dynamic performance testing device for cylindrical roller bearing retainer
CN105021400A (en) * 2015-07-07 2015-11-04 武汉理工大学 Intermediate bearing with hydraulic loading device used for ship cardan shaft system test stand
CN105021400B (en) * 2015-07-07 2018-03-16 武汉理工大学 The intermediate bearing with hydraulic loading device system test-bed for ship propulsive shafting
CN109115496A (en) * 2018-09-03 2019-01-01 重庆长江轴承股份有限公司 A kind of automobile speed variator bearing static strength and resistance to vibration detection device

Similar Documents

Publication Publication Date Title
CN102854014A (en) Dynamic performance test device for angular contact ball bearing retainer
CN102866013A (en) Dynamic performance testing device for cylindrical roller bearing retainer
CN106769039B (en) A kind of mounting assembly suitable for the monitoring of rolling bearing rotary part
CN202793794U (en) Dynamic performance testing device for angular contact ball bearing retainer
CN108519268B (en) Device and method for detecting abrasion particles under lubricating condition
CN106092576A (en) Multifunction bearing pilot system
CN109520735A (en) Loading ability of bearing loses test macro
CN105547697B (en) A kind of ultrahigh speed rolling bearing performance tester
CN104330223A (en) Mechanical sealing property testing device and method for measuring axial force and temperature of sealed end surfaces
CN106840673B (en) Marine diesel slides base bearing pyroelectric signal caliberating device and scaling method
CN103868693A (en) Mechanical main shaft system thermal analysis comprehensive test experimental facility
CN106768748B (en) Built-in machine tool spindle axial dynamic stiffness testing device and testing method
CN202916093U (en) Cylindrical roller bearing retainer dynamic performance test device
CN203337382U (en) Bearing precision performance testing device
CN104236907A (en) Rolling bearing friction moment and stiffness measuring device and method
CN111272424B (en) Water-lubricated bearing on-line monitoring test platform and bearing characteristic test analysis method
CN110231171B (en) Hydrostatic pressure gyration test bench
CN204214608U (en) A kind of mechanical sealing performance tester can measuring axial force and temperature between seal face
CN110108488A (en) Rolling bearing retainer skidding research experiment system
CN106404412A (en) Device for measuring the eccentric position of the aero-engine bearing holder
CN108534940A (en) A kind of measuring device and measuring method of the rotor axial power of double-screw compressor
CN105067106B (en) A kind of intershaft bearing vibration signals collecting method
CN203798563U (en) Assembly structure of test system for journal bearing
CN102735422A (en) Device for studying gap flow field of shielding sleeve of shielding motor
CN106950137A (en) Tangential fretting abrasion test device and test method

Legal Events

Date Code Title Description
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: 20130501

Termination date: 20140913

EXPY Termination of patent right or utility model