CN204439357U - Radial hydrodynamic journal liquid polymers reliability test bench - Google Patents

Radial hydrodynamic journal liquid polymers reliability test bench Download PDF

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Publication number
CN204439357U
CN204439357U CN201520171255.4U CN201520171255U CN204439357U CN 204439357 U CN204439357 U CN 204439357U CN 201520171255 U CN201520171255 U CN 201520171255U CN 204439357 U CN204439357 U CN 204439357U
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China
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negative sense
charger
servo
flat plate
loading
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CN201520171255.4U
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Chinese (zh)
Inventor
许彬彬
谭壮
杨兆军
李国发
朱晓翠
田海龙
何佳龙
王松
杜大伟
杨超
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Jilin University
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Jilin University
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Abstract

The utility model discloses a kind of radial hydrodynamic journal liquid polymers reliability test bench, comprise testing table supporting, radial hydrodynamic journal liquid polymers servicing unit, Z forward charger, Z negative sense charger, Y forward charger, Y negative sense charger and automaton.The utility model adopts four cover hydraulic loading devices to simulate dynamic and static pressure load to radial hydrodynamic journal liquid polymers and can realize loading within the scope of its radial 360 °, tested radial hydrodynamic journal liquid polymers are carried out to the fail-test of Reality simulation operating mode, and carry out real-time failure data acquisition.For the reliability assessment in later stage, Reliability modeling and reliability prediction provide practical basic data, substantially reduce data acquisition time.

Description

Radial hydrodynamic journal liquid polymers reliability test bench
Technical field
The utility model belongs to component of machine fail-test technical field, particularly relates to a kind ofly to simulate actual dynamic and static pressure load and the radial hydrodynamic journal liquid polymers reliability test bench that can load within the scope of radial 360 °.
Background technology
Along with machine is towards the development in efficient, accurate direction, friction is little, bearing capacity large, precision advantages of higher because having for hydrostatic bearing, receives increasing attention.Hydrostatic bearing is divided into hydrodynamic journal liquid polymers and aerostatic bearing according to the difference of medium.Hydrodynamic journal liquid polymers are the pressure oil relying on supply, mineralization pressure oil film in bearing clearance, axle journal and bearing is made to be in fully liquid Frotteurism, its usually by oil supply system, flow controller and bearing three part form, wherein radial hydrodynamic journal liquid polymers have wide range of applications, such as, machine tool chief axis in certain model heavy horizontal lathe selective headstock adopts two radial hydrodynamic journal liquid polymers to support, for bearing the part or all of inertial force of the machine tool element such as radial cutting force, main shaft and workpiece.Therefore radial hydrodynamic journal liquid polymers reliability test bench is researched and developed, incipient fault and the weak links of reliability of radial hydrodynamic journal liquid polymers is exposed by fail-test, propose and implement innovative approach targetedly to improve radial hydrodynamic journal liquid polymers reliability level, adopting the reliability of the product of radial hydrodynamic journal liquid polymers to have very important practical significance for the benefit and raising increasing radial hydrodynamic journal liquid polymers related components manufacturing enterprise.
The duty of radial hydrodynamic journal liquid polymers is comparatively serious by the impact of temperature and charge oil pressure.Because the domestic research radial hydrodynamic journal liquid polymers being comprised to the hydraulic technique of its oil supply system is started late, therefore domesticly at present also complete reliability consideration is not carried out to radial hydrodynamic journal liquid polymers, current only testing table, also just to adopting the product of radial hydrodynamic journal liquid polymers to carry out inertia load test etc., is almost in blank for the reliability test of radial hydrodynamic journal liquid polymers is domestic specially.The utility model only bears this actual applying working condition of radial pressure according to radial hydrodynamic journal liquid polymers, proposes a kind ofly to have the actual dynamic and static pressure load of simulation and the radial hydrodynamic journal liquid polymers reliability test bench that can load within the scope of radial 360 °.
Summary of the invention
Technical problem to be solved in the utility model overcomes current reliability test can not carry out the fail-test simulating actual condition problem to radial hydrodynamic journal liquid polymers.The utility model provides a kind ofly has the actual dynamic and static pressure load of simulation and the radial hydrodynamic journal liquid polymers reliability test bench that can load within the scope of radial 360 °.
The utility model comprises testing table supporting, radial hydrodynamic journal liquid polymers servicing unit, Z forward charger, Z negative sense charger, Y forward charger, Y negative sense charger and automaton.
One, testing table supporting
Described testing table supporting is ground black iron, described Horizon iron level is placed, T-slot distributes along the X direction, for supporting and fixing be arranged in X-direction radial hydrodynamic journal liquid polymers servicing unit, be arranged in Y-direction Y forward charger, be arranged in Y-direction Y negative sense charger, be arranged in Z-direction Z forward charger, be arranged in Z-direction Z negative sense load right column and be arranged in Z-direction Z negative sense load left column.
Two, radial hydrodynamic journal liquid polymers servicing unit
Described radial hydrodynamic journal liquid polymers servicing unit is made up of supporting upright post, slip column, bearing block support plate, thrust bearing cover, rear radial hydrodynamic journal liquid polymers base, main shaft, servomotor, servomotor mount pad, front end support plate, pressure transducer, clock gauge, spring fitting device support plate, spring fitting device, loading unit, front radial hydrodynamic journal liquid polymers base and temperature sensor.
The top of described supporting upright post is divided into rectangular structure, its end face has two threaded holes, the bottom of supporting upright post is divided into rectangular flat plate structure, and dull and stereotyped two sides, front and back respectively have two U-shaped mouths, and four T-shaped bolts can be fixed on ground black iron through U-shaped mouth.The structure of described slip column is similar to supporting upright post, top is divided into rectangular structure, its end face has two threaded holes, the T-slot that side (side near loading joint) has twice parallel, the bottom of slip column is divided into rectangular flat plate structure, dull and stereotyped two sides, front and back respectively have two U-shaped mouths, and four T-shaped bolts can be fixed on ground black iron through U-shaped mouth.Described bearing block support plate is rectangular flat plate structure, the T-slot that upper surface has twice parallel, and both sides respectively have two counter sinks, through counter sink, both sides is separately fixed at the end face of supporting upright post by bolt.
Described thrust bearing cover is for supporting and thrust bearing on positioning spindle thus realize axial location to main shaft, respectively there are two through holes at two ends, thrust bearing cover bottom surface, and thrust metal can be fixed on bearing block support plate through through hole by four T-shaped bolts.Described front end support plate is rectangular flat plate structure, the T-slot that upper surface has twice parallel, and the two ends of upper surface respectively have two counter sinks, through counter sink, two ends is separately fixed at the end face of supporting upright post and the end face of slip column by four bolts.Described servomotor mount pad entirety is L shape structure, and its upper part flat board has four through holes for fixing servomotor, has a motor axis hole in the middle of four through holes.The upper part of servomotor mount pad is dull and stereotyped is welded with two reinforcements with bottom panel junction, respectively there are two through holes at the two ends of the upper surface of the bottom panel of servomotor mount pad, and servomotor mount pad can be fixed on the support plate of front end through through hole by four T-shaped bolts.Servomotor is connected with main shaft by shaft coupling, thus drive shaft is rotated.
Described pressure transducer is connected to each oil-in place of radial hydrodynamic journal liquid polymers by T-valve, the quantity of required pressure transducer equals front radial hydrodynamic journal liquid polymers oil-in quantity m and rear radial hydrodynamic journal liquid polymers oil-in quantity n sum, for detecting and monitor the charge oil pressure of radial hydrodynamic journal liquid polymers.Described temperature sensor is arranged on front radial hydrodynamic journal liquid polymers base, in like manner same mounting temperature sensor on rear radial hydrodynamic journal liquid polymers base, for detecting and monitor the temperature of radial hydrodynamic journal liquid polymers.Described clock gauge is placed in respectively near the rear of front radial hydrodynamic journal liquid polymers base and the front of rear radial hydrodynamic journal liquid polymers base, beats for the circle detecting and monitor main shaft.
Described spring fitting device is made up of upper flat plate, spring that lower flat board is identical with two, upper and lower writing board shape, size dimension are identical and be rectangle structure part, the lower surface of upper flat plate is welded with two crotches, lower dull and stereotyped upper surface is welded with two crotches equally, the middle position of lower dull and stereotyped two crotches has two circular holes, two springs are connected with a crotch of lower dull and stereotyped opposite position with a crotch of upper flat plate respectively, namely two springs are placed in upper and lower dull and stereotyped middle, and perpendicular to planar surface.Consult figure, described spring fitting device support plate entirety becomes L shape, the first half is a rectangular flat plate, respectively there are two circular holes dull and stereotyped both sides, the latter half is similarly a rectangular flat plate, and respectively there is a U-shaped mouth dull and stereotyped both sides, and spring fixed support plate can be fixed on slip column through U-shaped mouth by two T-shaped bolts to be had on the side of T-slot, unclamp T-shaped bolt, spring fixed support plate can move in z-direction along the T-slot of slip column.
Described loading unit is made up of loading unit shell, two identical bearing (ball) covers, two identical deep groove ball bearings and two identical O-ring seals.The main body of described loading unit shell is cylindrical, respectively welds a rectangular flat plate in the axis equal-height position both sides, front end of its periphery.Loading unit shell has cylindrical cavity, and cylindrical cavity is coaxial with the periphery of loading unit shell.Described bearing (ball) cover bottom surface is disc-shaped structure, and medial surface has the edge of a circle projection, and there is a through hole at the center of bearing (ball) cover bottom surface, and the periphery circumference of bearing (ball) cover has six equidistributed through holes.The inner ring of deep groove ball bearing and main shaft match to merge and utilize the shaft shoulder of main shaft to carry out axial location, match with loading unit shell cylindrical cavity in deep groove ball bearing outer ring, and the edge utilizing bearing (ball) cover medial surface one to enclose projection positions outer ring.Through six through holes of bearing (ball) cover circumference, bearing (ball) cover is arranged on the two ends of loading unit shell by six bolts, main shaft is through the through hole in the middle of bearing (ball) cover, and two O-ring seals to be arranged on respectively in the seal groove on the face of cylinder of two bearing (ball) cover through holes and to contact with main shaft thus realize the sealing to deep groove ball bearing.
The rectangular flat plate of loading unit both sides is through spring fitting device, namely the upper flat plate of two sleeve spring stationary installations contacts with the rectangular flat plate of loading unit both sides (the X-direction length of spring fitting device upper flat plate is greater than the rectangular flat plate X-direction width of loading unit both sides) respectively, bolt is utilized to pass two circular holes of two circular holes dull and stereotyped under spring fitting device and spring fitting device support plate the first half side thus be fixed on by spring fitting device on spring fitting device support plate, the T-slot of spring fitting device support plate along slip column is moved to correct position in z-direction and fix, realize being applied with a precompression to loading unit, thus realize the loading unit when main shaft rotates and effectively limited with the rotation of main shaft, be convenient to Y forward charger, Y negative sense charger, Z forward charger and Z negative sense charger load it, and before the power of loading is delivered to, on rear radial hydrodynamic journal liquid polymers.
Three, Z forward charger
Described Z forward charger forms by connecting base, firm banking, fixed bar, electrohydraulic servo valve, servo-cylinder, elastic device, pull pressure sensor, loading joint, connecting link, oscillating bearing base, mounting seat, loaded seat and displacement transducer.
Described servo-cylinder selects single piston or double-piston rod-type hydraulic jack, for single-piston rod formula servo-cylinder in embodiment of the present utility model, single-piston rod stretches out from the upper end of servo-cylinder, has four threaded holes, for fixing electrohydraulic servo valve in the middle of servo-cylinder upper surface.
Described electrohydraulic servo valve is arranged on the upper surface of servo-cylinder by four bolts.
Described connection base is a rectangular flat plate structural member, the T-slot that its upper surface has twice parallel, and respectively there are two through holes both sides, and connection base can be fixed on ground black iron through through hole by four T-shaped bolts.Described firm banking entirety is L shape structure, top is divided into rectangular flat plate structure, flat board there are four circular holes become two row two column distributions, lower part is similarly rectangular flat plate structure, respectively there are two U-shaped mouths dull and stereotyped both sides, firm banking can be fixed on connection base through U-shaped mouth by four T-shaped bolts, respectively there are two reinforcements firm banking upper part rectangular flat plate and both sides, lower part rectangular flat plate junction.Described mounting seat is a rectangular flat plate structure, it has the T-slot that twice are parallel, and twice T-slot center section has four counter sinks to become two row two column distributions, mounting seat can be fixed on firm banking through counter sink by four bolts.
Described loaded seat is the box typed structure part being adopted the rear end open be welded by four block length square plates, the base plate of loaded seat is provided with four through holes, for installing four T-shaped bolts, loaded seat is fixed in mounting seat, namely being fixed on mounting seat has on the end face of T-slot, unclamp T-shaped bolt, loaded seat can move along the T-slot in mounting seat at single-piston rod moving direction, loaded seat lower wall panels has a through hole for passing fixed bar.
Described fixed bar is a multidiameter, and namely its medium axle diameter is greater than the two ends diameter of axle, and the two ends of fixed bar are furnished with screw thread, and one end is connected with the lower surface threaded hole of servo-cylinder, and one end through the lower wall panels through hole of loaded seat, and is fixed by nut screwing clamping.
Described displacement transducer shell is fixed by screws on the cylinder body of servo-cylinder, and its inner core is connected with the piston rod upper end of servo-cylinder, and when piston rod moves, the inner core of displacement transducer is also along with movement, realizes measurement and the feedback of displacement.
Described elastic device is made up of the nut that the identical bolt of lower end web joint, upper end web joint, sleeve that two structures are identical, two specifications is identical with two specifications.Wherein, upper end web joint is identical with lower end connecting board structure, and be a rectangular flat plate, its center position is provided with tapped through hole, respectively there is a through hole both sides of tapped through hole, and the external diameter of the sleeve that two structures are identical is greater than the diameter of two side through hole on lower end web joint and upper end web joint.The bolt that two specifications are identical inserts in the through hole of lower end web joint and web joint both sides, upper end, on two bolts of the identical sleeve set of two structures between lower end web joint and upper end web joint, finally by nut, sleeve identical to upper end web joint, two structures and lower end web joint are fixed together again.The upper end of the threaded hole on the web joint of lower end and servo-cylinder piston rod is threaded connection, and the threaded hole on the web joint of upper end is threaded with the lower end of studs.Elastic device can absorption portion displacement but can transmitting force.The upper end of studs is threaded with pull pressure sensor (the utility model is for JHZTC, column casing type), the upper end of pull pressure sensor is threaded with the lower end of another studs, and the threaded upper ends of this studs is threaded with oscillating bearing base lower end.
Described oscillating bearing base is cylindrical structural part, and its inner chamber is similarly cylindrical structural and coaxial with periphery, and oscillating bearing base upper surface opening, lower surface are closed, and lower surface has a threaded hole.The inner chamber of oscillating bearing base coordinates with oscillating bearing outer ring, oscillating bearing inner ring and connecting link lower end interference fit.Described connecting link is multidiameter structure, and namely medium axle diameter is greater than the two ends diameter of axle, and shaft shoulder place, lower end contacts with oscillating bearing inner ring and realizes axial location, and upper end is furnished with screw thread and is connected with loading joint screw thread.The upper surface of described loading joint is an arc surface, arc-shaped surface is with one deck high damping high-abrasive material, arc radius is identical with the radius of the loading unit shell of loading unit thus ensure that the arc surface loading joint when loading fully contacts with loading unit, make loaded power through the axis of main shaft, the lower end loading joint is rectangular structure, and there is a threaded hole its lower surface middle.
Described Z forward charger is when implementing to load to loading unit, should ensure to load joint fully contact with loading unit and ensure that the piston rod of servo-cylinder and connecting link are coaxial and orthogonal with the axes intersect of loading unit as far as possible, namely orthogonal thus realize the loading of Z-direction forward with the axes intersect of main shaft.When Z forward charger does not load loading unit, the distance of loading joint disengaging loading unit is a value between 0.1mm to 0.5mm.
Four, Y forward charger and Y negative sense charger
Described Y forward charger is identical with the structure of Y negative sense charger.Y forward charger is loaded joint, Y forward connecting link, Y forward oscillating bearing base, Y forward mounting seat, Y forward loaded seat and Y positive-displacement sensor formed by Y forward left column, Y forward loading supporting base, Y forward right column, Y forward fixed bar, Y forward electrohydraulic servo valve, Y forward servo-cylinder, Y forward elastic device, Y forward pull pressure sensor, Y forward.
The Y negative sense left column of Y forward left column and Y negative sense charger, the Y negative sense that Y forward loads supporting base and Y negative sense charger loads supporting base, the Y negative sense right column of Y forward right column and Y negative sense charger, the Y negative sense fixed bar of Y forward fixed bar and Y negative sense charger, the Y negative sense electrohydraulic servo valve of Y forward electrohydraulic servo valve and Y negative sense charger, the Y negative sense servo-cylinder of Y forward servo-cylinder and Y negative sense charger, the Y negative sense elastic device of Y forward elastic device and Y negative sense charger, the Y negative sense pull pressure sensor of Y forward pull pressure sensor and Y negative sense charger, the Y negative sense that Y forward loads joint and Y negative sense charger loads joint, the Y negative sense connecting link of Y forward connecting link and Y negative sense charger, the Y negative sense oscillating bearing base of Y forward oscillating bearing base and Y negative sense charger, the Y negative sense mounting seat of Y forward mounting seat and Y negative sense charger, Y forward loaded seat is identical with the Y negative sense loaded seat of Y negative sense charger and the Y negative sense displacement sensor structure of Y positive-displacement sensor and Y negative sense charger.
Described Y negative sense charger is loaded joint, Y negative sense connecting link, Y negative sense oscillating bearing base, Y negative sense mounting seat, Y negative sense loaded seat and Y negative sense displacement transducer formed by Y negative sense left column, Y negative sense loading supporting base, Y negative sense right column, Y negative sense fixed bar, Y negative sense electrohydraulic servo valve, Y negative sense servo-cylinder, Y negative sense elastic device, Y negative sense pull pressure sensor, Y negative sense.
Described Y negative sense left column top is divided into rectangular structure, the T-slot that right lateral surface has twice parallel, Y negative sense left column bottom is divided into a rectangular flat plate, and dull and stereotyped left and right sides respectively have two U-shaped mouths, and four T-shaped bolts can be fixed on ground black iron through U-shaped mouth.Described Y negative sense right column top is divided into rectangular structure, the T-slot that left-hand face has twice parallel, Y negative sense right column bottom is divided into rectangular flat plate structure, and dull and stereotyped left and right sides respectively have two U-shaped mouths, and four T-shaped bolts can be fixed on ground black iron through U-shaped mouth.Consult figure, described Y negative sense loads supporting base entirety and becomes I-shaped, intermediate portion is divided into rectangle structure, and have four circular holes to become two row two column distributions, for fixing Y negative sense mounting seat, the left surface of Y negative sense loading supporting base and right flank are all rectangle structure and respectively there are two U-shaped mouths both sides up and down, T-shaped bolt Y negative sense loading supporting base both sides can be separately fixed at Y negative sense left column through U-shaped mouth and Y negative sense right column has on the surface of T-slot, unclamp T-shaped bolt, Y negative sense loads supporting base and can move in z-direction along the T-slot of Y negative sense left column and Y negative sense right column.
The fixed bar of Y negative sense fixed bar and Z forward charger, the electrohydraulic servo valve of Y negative sense electrohydraulic servo valve and Z forward charger, the servo-cylinder of Y negative sense servo-cylinder and Z forward charger, the elastic device of Y negative sense elastic device and Z forward charger, the pull pressure sensor of Y negative sense pull pressure sensor and Z forward charger, Y negative sense loads the loading joint of joint and Z forward charger, the connecting link of Y negative sense connecting link and Z forward charger, the oscillating bearing base of Y negative sense oscillating bearing base and Z forward charger, the mounting seat of Y negative sense mounting seat and Z forward charger, Y negative sense loaded seat is identical with the loaded seat of Z forward charger and the displacement sensor structure of Y negative sense displacement transducer and Z forward charger.
Described Y forward charger is when implementing to load to loading unit, should ensure that Y forward loads joint and fully contacts with loading unit and ensure that the piston rod of Y forward servo-cylinder is coaxial with Y forward connecting link and mutually vertical with the axes intersect of loading unit as far as possible, namely mutual vertical thus realize the loading of Y-direction forward with the axes intersect of main shaft.When Y forward charger does not load loading unit, the distance that Y forward loads joint disengaging loading unit is 0.1mm to 0.5mm.
Described Y negative sense charger is when implementing to load to loading unit, should ensure that Y negative sense loads joint and fully contacts with loading unit and ensure that the piston rod of Y negative sense servo-cylinder is coaxial with Y negative sense connecting link and mutually vertical with the axes intersect of loading unit as far as possible, namely mutual vertical thus realize the loading of Y-direction negative sense with the axes intersect of main shaft.When Y negative sense charger does not load loading unit, the distance that Y negative sense loads joint disengaging loading unit is 0.1mm to 0.5mm.
Five, Z negative sense charger
Described Z negative sense charger loads right column by Z negative sense, Z negative sense loads crossbeam, Z negative sense loads left column, Z negative sense firm banking, Z negative sense fixed bar, Z negative sense electrohydraulic servo valve, Z negative sense servo-cylinder, Z negative sense elastic device, Z negative sense pull pressure sensor, Z negative sense load joint, Z negative sense connecting link, Z negative sense oscillating bearing base, Z negative sense mounting seat, Z negative sense loaded seat and Z negative sense displacement transducer and form.
Described Z negative sense loads right column top and is divided into rectangular structure, its end face has two threaded holes, the bottom that Z negative sense loads right column is divided into rectangular flat plate structure, and before and after dull and stereotyped, respectively there are two U-shaped mouths both sides, and four T-shaped bolts can be fixed on ground black iron through U-shaped mouth.The structure that described Z negative sense loads left column is identical with the structure that Z negative sense loads right column.It is rectangular flat plate structure that described Z negative sense loads crossbeam, the T-slot that dull and stereotyped below has twice parallel, Z negative sense holder can be fixed on Z negative sense by T-shaped bolt loads on crossbeam, unclamp T-shaped bolt, Z negative sense firm banking can move in the Y direction along the T-slot of Z negative sense loading crossbeam, respectively there are two counter sinks the both sides that Z negative sense loads crossbeam, and the two ends that Z negative sense can be loaded crossbeam by four bolts are separately fixed on Z negative sense loading right column and Z negative sense loading left column.
The firm banking of Z negative sense firm banking and Z forward charger, the fixed bar of Z negative sense fixed bar and Z forward charger, the electrohydraulic servo valve of Z negative sense electrohydraulic servo valve and Z forward charger, the servo-cylinder of Z negative sense servo-cylinder and Z forward charger, the elastic device of Z negative sense elastic device and Z forward charger, the pull pressure sensor of Z negative sense pull pressure sensor and Z forward charger, Z negative sense loads the loading joint of joint and Z forward charger, the connecting link of Z negative sense connecting link and Z forward charger, the oscillating bearing base of Z negative sense oscillating bearing base and Z forward charger, the mounting seat of Z negative sense mounting seat and Z forward charger, Z negative sense loaded seat is identical with the loaded seat of Z forward charger and the displacement sensor structure of Z negative sense displacement transducer and Z forward charger.
Described Z negative sense charger is when implementing to load to loading unit, should ensure that Z negative sense loads joint and fully contacts with loading unit and ensure that the piston rod of Z negative sense servo-cylinder is coaxial with Z negative sense connecting link and mutually vertical with the axes intersect of loading unit as far as possible, namely mutual vertical thus realize the loading of Z-direction negative sense with the axes intersect of main shaft.When Z negative sense charger does not load loading unit, the distance that Z negative sense loads joint disengaging loading unit is 0.1mm to 0.5mm.
Y forward charger, Z forward charger, when Y negative sense charger and Z negative sense charger load loading unit, the power that each device should be made as far as possible to load and main-shaft axis meet at a bit, by the various combination of above-mentioned four chargers, can realize moving arbitrarily within the scope of radial 360 ° radial hydrodynamic journal liquid polymers, the loading of static pressure load, thus reach both can to the fail-test under the general service condition of radial hydrodynamic journal liquid polymers i.e. random loading within the scope of its radial 360 °, also namely can load within the scope of its radial predetermined angular the fail-test under the specific service condition of radial hydrodynamic journal liquid polymers.
Six, automaton
Described automaton comprises upper industrial computer, the next programmable controller PLC, the next Y-direction servo controller (Y forward servo controller and Y negative sense servo controller each a set of), the next Z-direction servo controller (Z forward servo controller and Z negative sense servo controller each a set of), the next motor servo controller.
The RS-232C port of described programmable controller PLC is connected with the RS-232C port electric wire of upper industrial computer, the output terminal of programmable controller PLC is connected with cooler and two solenoid directional control valves respectively, for parameters such as the start and stop of controlled cooling model machine, the temperature of chilled water, for hydraulic power unit provides chilled water, control the start and stop of radial hydrodynamic journal liquid polymers oil supply system and the start and stop of loading hydraulic power unit by controlling solenoid directional control valve thus realize providing hydraulic oil to hydraulic loading device.The input port of programmable controller PLC is respectively with temperature sensor (two overlap), (m+n overlaps pressure transducer, the i.e. radial hydrodynamic journal liquid polymers oil-in in front end quantity m and rear end radial direction hydrodynamic journal liquid polymers oil-in quantity n sum) and the output port electric wire of radial hydrodynamic journal liquid polymers oil supply system be connected, for the working status parameter of feedback temperature parameter, pressure parameter and radial hydrodynamic journal liquid polymers oil supply system.
The RS-232C port of described Y-direction servo controller is connected with the RS-232C port electric wire of upper industrial computer, Y-direction servo controller and upper industrial computer carry out communication, the signal output part of Y-direction servo controller is connected with the signal input part electric wire of electrohydraulic servo valve and Y forward electrohydraulic servo valve and Y negative sense electrohydraulic servo valve, realize load cylinder and Y forward servo-cylinder and Y negative sense servo-cylinder by control electrohydraulic servo valve to move loading unit, the loading of static pressure load, in loading procedure, by displacement transducer and Y positive-displacement sensor and Y negative sense displacement transducer and pull pressure sensor and Y forward pull pressure sensor and Y negative sense pull pressure sensor, the displacement detected and pressure signal are passed to Y-direction servo controller through signal amplifier, realize closed-loop control.
Described Z-direction servo controller is the same with Y-direction servo controller principle, up direction carries out communication by RS-232C and upper industrial computer, the servo-cylinder that down direction realizes load cylinder and Z negative sense servo-cylinder and Z forward charger by the electrohydraulic servo valve controlling electrohydraulic servo valve and Z negative sense electrohydraulic servo valve and Z forward charger moves loading unit, the loading of static pressure load, in loading procedure, by displacement transducer and the displacement transducer of Z negative sense displacement transducer and Z forward charger and the pull pressure sensor 31 of pull pressure sensor and Z negative sense pull pressure sensor and Z forward charger, the displacement detected and pressure signal are passed to Z-direction servo controller through signal amplifier, realize closed-loop control.
The RS-232C port of described motor servo controller is connected with the RS-232C port electric wire of upper industrial computer, the output terminal of motor servo controller is connected with the signal input part electric wire of servomotor, control the rotating speed of servomotor, simultaneously the scrambler of servomotor inside again by signal feedback to motor servo controller, realize closed-loop control.
Upper industrial computer control inerface is worked out by VB, the rotating speed of selected servomotor on control inerface, the temperature parameter of cooler, selected Y positive dirction, Y negative direction, Z positive dirction, the pressure size that Z negative direction loads, frequency, waveform and load time etc. (do not need the direction loaded, above-mentioned relative parameters setting is 0) after, with the next programmable controller PLC, two Y-direction servo controllers, two Z-direction servo controllers and motor servo controller carry out serial communication by RS-232C, the first output current of the next programmable controller PLC controls the radial hydrodynamic journal liquid polymers oil supply system of solenoid directional control valve action launching, restart servomotor, last controlled cooling model machine cools to loading hydraulic power unit, output current controls electromagnetic switch valve events again, by load cylinder and Y forward servo-cylinder, Y negative sense servo-cylinder, the servo-cylinder of Z negative sense servo-cylinder and Z forward charger moves loading unit, the loading of static pressure load.The in real time working status parameter of the pressure of the temperature parameter of display cooler, radial hydrodynamic journal liquid polymers oil-in, temperature, oil supply system and the dynamic and static pressure load parameter that loads on the control inerface of upper industrial computer, the numerical value and the circle recording the main shaft that clock gauge is measured is beated.
Compared with prior art the beneficial effects of the utility model are:
1. the utility model adopts four cover hydraulic loading devices to simulate dynamic and static pressure load to radial hydrodynamic journal liquid polymers and can realize loading within the scope of its radial 360 °, tested radial hydrodynamic journal liquid polymers are carried out to the fail-test of Reality simulation operating mode, and carry out real-time failure data acquisition.For the reliability assessment in later stage, Reliability modeling and reliability prediction provide practical basic data, substantially reduce data acquisition time.
2. the utility model both can carry out the i.e. random loading arbitrarily within the scope of its radial 360 ° of general fail-test to radial hydrodynamic journal liquid polymers, also namely the fail-test that radial hydrodynamic journal liquid polymers carry out under specific service condition can be loaded in the angular range of its radial regulation, embody this pilot system and there is abundant utility function.
3. the utility model have employed cylindrical loading unit and carries out it flexible fixing, thus the loading achieved under main shaft rotation status loaded load is effectively delivered on radial hydrodynamic journal liquid polymers.
4. loading unit of the present utility model is placed on the position in the middle of the forward and backward radial hydrodynamic journal liquid polymers of main shaft, can do contrast test to underproof forward and backward radial hydrodynamic journal liquid polymers, the performance test for the radial hydrodynamic journal liquid polymers of new research and development has great significance.
5, the utility model adopts the simulation that Z forward charger, Z negative sense charger, Y forward load, Y negative sense charger realizes dynamic and static pressure load, and can according to actual condition regulate four direction load the size of dynamic force, frequency and test period.
6, the utility model accommodation is wider, fail-test can be carried out for the radial hydrodynamic journal liquid polymers of different model, only need change forward and backward radial hydrodynamic journal liquid polymers base, main shaft, loading joint just can to test the testing and monitoring that it carries out reliability load test and performance parameter, embody dirigibility and the versatility of this pilot system.
7, the automaton in the utility model by displacement transducer and the pull pressure sensor dynamic and static pressure load Real-Time Monitoring to simulation, and realizes monitoring in real time and closed-loop control and feedback, improves the precision of simulated pressure load.Simultaneously by load sound state pressure load parameter display on the man machine operation interface of upper industrial computer.
8, in the utility model, automaton combines in the unified control of host computer, can realize carrying out status monitoring and detection to radial hydrodynamic journal liquid polymers by pressure transducer and temperature sensor simultaneously, and the main shaft circle measured by clock gauge is beated records of values in the VB software of control system.
Accompanying drawing explanation
Fig. 1 is axonometric projection graph of the present utility model.
Fig. 2 is the axonometric projection graph of radial hydrodynamic journal liquid polymers servicing unit of the present utility model.
Fig. 3 is the partial enlarged drawing of radial hydrodynamic journal liquid polymers servicing unit front end of the present utility model.
Fig. 4 is the axonometric projection graph of spring fitting device support plate of the present utility model.
Fig. 5 is the axonometric projection graph of Z forward charger of the present utility model.
Fig. 6 is the axonometric projection graph of Y negative sense charger of the present utility model.
Fig. 7 is the axonometric projection graph that Y negative sense of the present utility model loads supporting base.
Fig. 8 is the structural principle block diagram of the utility model automaton.
In figure: 1-Y forward charger, the radial hydrodynamic journal liquid polymers servicing unit of 2-, 3-Z forward charger, 4-Y negative sense charger, 5-ground black iron, 6-Z negative sense loads right column, 7-Z negative sense loads crossbeam, 8-Z negative sense loads left column, 9-supporting upright post, 10-slip column, 11-bearing block support plate, 12-thrust bearing cover, radial hydrodynamic journal liquid polymers base after 13-, 14-main shaft, 15-servomotor, 16-servomotor mount pad, 17-front end support plate, 18-pressure transducer, 19-clock gauge, 20-spring fitting device support plate, 21-spring fitting device, 22-loading unit, radial hydrodynamic journal liquid polymers base before 23-, 24-temperature sensor, 25-connects base, 26-firm banking, 27-fixed bar, 28-electrohydraulic servo valve, 29-servo-cylinder, 30-elastic device, 31-pull pressure sensor, 32-loads joint, 33-connecting link, 34-oscillating bearing base, 35-mounting seat, 36-loaded seat, 37-displacement transducer, 38-Y negative sense left column, 39-Y negative sense loads supporting base, 40-Y negative sense right column.
Embodiment
Consult shown in Fig. 1, the utility model comprises testing table supporting, radial hydrodynamic journal liquid polymers servicing unit, Z forward charger, Z negative sense charger, Y forward charger, Y negative sense charger and automaton;
The positive negative direction of X, Y, Z described in the utility model is see shown in Fig. 1 coordinate system, and in coordinate system, the direction of arrow indication is the forward of corresponding coordinate axle, otherwise is negative sense.
One, testing table supporting
Consult shown in Fig. 1, described testing table supporting is ground black iron 5, described ground black iron 5 horizontal positioned, T-slot distributes along the X direction, for supporting and fixing be arranged in X-direction radial hydrodynamic journal liquid polymers servicing unit 2, be arranged in Y-direction Y forward charger 1, be arranged in Y-direction Y negative sense charger 4, be arranged in Z-direction Z forward charger 3, be arranged in Z-direction Z negative sense load right column 6 and be arranged in Z-direction Z negative sense load left column 8.
Two, radial hydrodynamic journal liquid polymers servicing unit
Consult shown in Fig. 1, Fig. 2 and Fig. 3, described radial hydrodynamic journal liquid polymers servicing unit 2 is made up of supporting upright post 9, slip column 10, bearing block support plate 11, thrust bearing cover 12, rear radial hydrodynamic journal liquid polymers base 13, main shaft 14, servomotor 15, servomotor mount pad 16, front end support plate 17, pressure transducer 18, clock gauge 19, spring fitting device support plate 20, spring fitting device 21, loading unit 22, front radial hydrodynamic journal liquid polymers base 23 and temperature sensor 24.
Consult shown in Fig. 2, the top of described supporting upright post 9 is divided into rectangular structure, and its end face has two threaded holes, and the bottom of supporting upright post 9 is divided into rectangular flat plate structure, dull and stereotyped two sides, front and back respectively have two U-shaped mouths, and four T-shaped bolts can be fixed on ground black iron 5 through U-shaped mouth.The structure of described slip column 10 is similar to supporting upright post 9, top is divided into rectangular structure, its end face has two threaded holes, the T-slot that side (side near loading joint 22) has twice parallel, the bottom of slip column 10 is divided into rectangular flat plate structure, dull and stereotyped two sides, front and back respectively have two U-shaped mouths, and four T-shaped bolts can be fixed on ground black iron 5 through U-shaped mouth.Described bearing block support plate 11 is rectangular flat plate structure, the T-slot that upper surface has twice parallel, and both sides respectively have two counter sinks, through counter sink, both sides is separately fixed at the end face of supporting upright post 9 by bolt.
Described thrust bearing cover 12 is for supporting and thrust bearing on positioning spindle thus realize axial location to main shaft, respectively there are two through holes at two ends, thrust bearing cover 12 bottom surface, and thrust metal 12 can be fixed on bearing block support plate 11 through through hole by four T-shaped bolts.Described front end support plate 17 is rectangular flat plate structure, the T-slot that upper surface has twice parallel, the two ends of upper surface respectively have two counter sinks, through counter sink, two ends are separately fixed at the end face of supporting upright post 9 and the end face of slip column 10 by four bolts.Described servomotor mount pad 16 entirety is L shape structure, and its upper part flat board has four through holes for having a motor axis hole in the middle of fixing servomotor 15, four through holes.The upper part of servomotor mount pad 16 is dull and stereotyped is welded with two reinforcements with bottom panel junction, respectively there are two through holes at the two ends of the upper surface of the bottom panel of servomotor mount pad 16, and servomotor mount pad 16 can be fixed on front end support plate 17 through through hole by four T-shaped bolts.Servomotor 15 is connected with main shaft 14 by shaft coupling, thus drive shaft 14 is rotated.
Described pressure transducer 18(the utility model is for the PS604 type pressure transducer of Yi Ke Electronics Co., Ltd.) each oil-in place of radial hydrodynamic journal liquid polymers is connected to by T-valve, the quantity of required pressure transducer 18 equals front radial hydrodynamic journal liquid polymers oil-in quantity m and rear radial hydrodynamic journal liquid polymers oil-in quantity n sum, for detecting and monitor the charge oil pressure of radial hydrodynamic journal liquid polymers.Described temperature sensor 24(the utility model is for WZP201 type temperature sensor) be arranged on front radial hydrodynamic journal liquid polymers base 23, in like manner same mounting temperature sensor 24 on rear radial hydrodynamic journal liquid polymers base 13, for detecting and monitor the temperature of radial hydrodynamic journal liquid polymers.Described clock gauge 19(the utility model is for three rich 2046S types) be placed in respectively near the rear of front radial hydrodynamic journal liquid polymers base 23 and the front of rear radial hydrodynamic journal liquid polymers base 13, beat for the circle detecting and monitor main shaft 14.
Described spring fitting device 21 is made up of upper flat plate, spring that lower flat board is identical with two, upper and lower writing board shape, size dimension are identical and be rectangle structure part, the lower surface of upper flat plate is welded with two crotches, lower dull and stereotyped upper surface is welded with two crotches equally, the middle position of lower dull and stereotyped two crotches has two circular holes, two springs are connected with a crotch of lower dull and stereotyped opposite position with a crotch of upper flat plate respectively, namely two springs are placed in upper and lower dull and stereotyped middle, and perpendicular to planar surface.Consult Fig. 4, described spring fitting device support plate 20 entirety becomes L shape, the first half is a rectangular flat plate, respectively there are two circular holes dull and stereotyped both sides, the latter half is similarly a rectangular flat plate, and respectively there is a U-shaped mouth dull and stereotyped both sides, and spring fixed support plate 20 can be fixed on slip column 10 through U-shaped mouth by two T-shaped bolts to be had on the side of T-slot, unclamp T-shaped bolt, spring fixed support plate 20 can move in z-direction along the T-slot of slip column 10.
Described loading unit 22 is made up of loading unit shell, two identical bearing (ball) covers, two identical deep groove ball bearings and two identical O-ring seals.The main body of described loading unit shell is cylindrical, respectively welds a rectangular flat plate in the axis equal-height position both sides, front end of its periphery.Loading unit shell has cylindrical cavity, and cylindrical cavity is coaxial with the periphery of loading unit shell.Described bearing (ball) cover bottom surface is disc-shaped structure, and medial surface has the edge of a circle projection, and there is a through hole at the center of bearing (ball) cover bottom surface, and the periphery circumference of bearing (ball) cover has six equidistributed through holes.The inner ring of deep groove ball bearing and main shaft 14 match to merge and utilize the shaft shoulder of main shaft 14 to carry out axial location, match with loading unit shell cylindrical cavity in deep groove ball bearing outer ring, and the edge utilizing bearing (ball) cover medial surface one to enclose projection positions outer ring.Through six through holes of bearing (ball) cover circumference, bearing (ball) cover is arranged on the two ends of loading unit shell by six bolts, main shaft 14 is through the through hole in the middle of bearing (ball) cover, and two O-ring seals to be arranged on respectively in the seal groove on the face of cylinder of two bearing (ball) cover through holes and to contact with main shaft 14 thus realize the sealing to deep groove ball bearing.
The rectangular flat plate of loading unit 22 both sides is through spring fitting device 21, namely the upper flat plate of two sleeve spring stationary installations 21 contacts with the rectangular flat plate of loading unit 22 both sides (the X-direction length of spring fitting device 21 upper flat plate is greater than the rectangular flat plate X-direction width of loading unit 22 both sides) respectively, bolt is utilized to pass two circular holes of two dull and stereotyped circular holes of spring fitting device 21 times and spring fitting device support plate 20 the first half side thus be fixed on spring fitting device support plate 20 by spring fitting device 21, the T-slot of spring fitting device support plate 20 along slip column 10 is moved to correct position in z-direction and fix, realize being applied with a precompression to loading unit 22, thus realize the loading unit 22 when main shaft 14 rotates and effectively limited with the rotation of main shaft 14, be convenient to Y forward charger 1, Y negative sense charger 4, Z forward charger 3 and Z negative sense charger load it, and before the power of loading is delivered to, on rear radial hydrodynamic journal liquid polymers.
Three, Z forward charger
Consult shown in Fig. 1 and Fig. 5, described Z forward charger 3 is made up of connection base 25, firm banking 26, fixed bar 27, electrohydraulic servo valve 28, servo-cylinder 29, elastic device 30, pull pressure sensor 31, loading joint 32, connecting link 33, oscillating bearing base 34, mounting seat 35, loaded seat 36 and displacement transducer 37.
Described servo-cylinder 29 selects single piston or double-piston rod-type hydraulic jack, for single-piston rod formula servo-cylinder in embodiment of the present utility model, single-piston rod stretches out from the upper end of servo-cylinder 29, four threaded holes are had, for fixing electrohydraulic servo valve 28 in the middle of servo-cylinder 29 upper surface.
Described electrohydraulic servo valve 28(the utility model is for the G761-3005B type servo-valve of MOOG company of the U.S.) upper surface of servo-cylinder 29 is arranged on by four bolts.
Described connection base 25 is a rectangular flat plate structural member, the T-slot that its upper surface has twice parallel, and respectively there are two through holes both sides, and connection base 25 can be fixed on ground black iron 5 through through hole by four T-shaped bolts.Described firm banking 26 entirety is L shape structure, top is divided into rectangular flat plate structure, flat board there are four circular holes become two row two column distributions, lower part is similarly rectangular flat plate structure, respectively there are two U-shaped mouths dull and stereotyped both sides, firm banking 26 can be fixed on connection base 25 through U-shaped mouth by four T-shaped bolts, respectively there are two reinforcements firm banking 26 upper part rectangular flat plate and both sides, lower part rectangular flat plate junction.Described mounting seat 35 is a rectangular flat plate structure, it has the T-slot that twice are parallel, and twice T-slot center section has four counter sinks to become two row two column distributions, mounting seat 35 can be fixed on firm banking 26 through counter sink by four bolts.
Described loaded seat 36 is by four block length square plates (i.e. left wallboard, right wallboard, lower wall panels and base plate) adopt the box typed structure part of the rear end open be welded, the base plate of loaded seat 36 is provided with four through holes, for installing four T-shaped bolts, loaded seat 36 is fixed in mounting seat 35, namely being fixed on mounting seat 35 has on the end face of T-slot, unclamp T-shaped bolt, loaded seat 36 can move along the T-slot in mounting seat 35 at single-piston rod moving direction, loaded seat 36 lower wall panels there is a through hole for passing fixed bar 27.
Described fixed bar 27 is multidiameters, namely its medium axle diameter is greater than the two ends diameter of axle, and the two ends of fixed bar 27 are furnished with screw thread, and one end is connected with the lower surface threaded hole of servo-cylinder 29, one end through the lower wall panels through hole of loaded seat 36, and is fixed by nut screwing clamping.
Described displacement transducer 37(the utility model is for LVDT type displacement transducer) shell is fixed by screws on the cylinder body of servo-cylinder 29, its inner core is connected with the piston rod upper end of servo-cylinder 29, when piston rod moves, the inner core of displacement transducer 37 is also along with movement, realizes measurement and the feedback of displacement.
Described elastic device 30 is made up of the nut that the identical bolt of lower end web joint, upper end web joint, sleeve that two structures are identical, two specifications is identical with two specifications.Wherein, upper end web joint is identical with lower end connecting board structure, and be a rectangular flat plate, its center position is provided with tapped through hole, respectively there is a through hole both sides of tapped through hole, and the external diameter of the sleeve that two structures are identical is greater than the diameter of two side through hole on lower end web joint and upper end web joint.The bolt that two specifications are identical inserts in the through hole of lower end web joint and web joint both sides, upper end, on two bolts of the identical sleeve set of two structures between lower end web joint and upper end web joint, finally by nut, sleeve identical to upper end web joint, two structures and lower end web joint are fixed together again.The upper end of the threaded hole on the web joint of lower end and servo-cylinder 29 piston rod is threaded connection, and the threaded hole on the web joint of upper end is threaded with the lower end of studs.Elastic device 30 can absorption portion displacement but can transmitting force (natural frequency of elastic device should be greater than load excited frequency more than two times).The upper end of studs with pull pressure sensor 31(the utility model for JHZTC1,2 column casing types) be threaded, the upper end of pull pressure sensor 31 is threaded with the lower end of another studs, and the threaded upper ends of this studs is threaded with oscillating bearing base 34 lower end.
Described oscillating bearing base 34 is cylindrical structural part, and its inner chamber is similarly cylindrical structural and coaxial with periphery, and oscillating bearing base 34 upper surface open, lower surface are closed, and lower surface has a threaded hole.The inner chamber of oscillating bearing base 34 coordinates with oscillating bearing outer ring, oscillating bearing inner ring and connecting link 33 lower end interference fit.Described connecting link 33 is multidiameter structure, and namely medium axle diameter is greater than the two ends diameter of axle, and shaft shoulder place, lower end contacts with oscillating bearing inner ring and realizes axial location, and upper end is furnished with screw thread and is threaded with loading joint 32.The upper surface of described loading joint 32 is an arc surface, arc-shaped surface is with one deck high damping high-abrasive material, arc radius is identical with the radius of the loading unit shell of loading unit 22 thus ensure that the arc surface loading joint 32 when loading fully contacts with loading unit 22, make loaded power through the axis of main shaft 14, the lower end loading joint 32 is rectangular structure, and there is a threaded hole its lower surface middle.
Described Z forward charger 3 is when implementing to load to loading unit 22, should ensure to load joint 32 fully contact with loading unit 22 and ensure that the piston rod of servo-cylinder 29 and connecting link 33 are coaxial and orthogonal with the axes intersect of loading unit 22 as far as possible, namely orthogonal thus realize the loading of Z-direction forward with the axes intersect of main shaft 14.When Z forward charger 3 does not load loading unit 22, loading distance that joint 32 departs from loading unit 22 is a value between 0.1mm to 0.5mm.
Four, Y forward charger and Y negative sense charger
Consult shown in Fig. 1 and Fig. 6, described Y forward charger 1 is identical with the structure of Y negative sense charger 4.Y forward charger 1 is loaded joint, Y forward connecting link, Y forward oscillating bearing base, Y forward mounting seat, Y forward loaded seat and Y positive-displacement sensor formed by Y forward left column, Y forward loading supporting base, Y forward right column, Y forward fixed bar, Y forward electrohydraulic servo valve, Y forward servo-cylinder, Y forward elastic device, Y forward pull pressure sensor, Y forward.
The Y negative sense left column 38 of Y forward left column and Y negative sense charger 4, the Y negative sense that Y forward loads supporting base and Y negative sense charger 4 loads supporting base 39, the Y negative sense right column 40 of Y forward right column and Y negative sense charger 4, the Y negative sense fixed bar of Y forward fixed bar and Y negative sense charger 4, the Y negative sense electrohydraulic servo valve of Y forward electrohydraulic servo valve and Y negative sense charger 4, the Y negative sense servo-cylinder of Y forward servo-cylinder and Y negative sense charger 4, the Y negative sense elastic device of Y forward elastic device and Y negative sense charger 4, the Y negative sense pull pressure sensor of Y forward pull pressure sensor and Y negative sense charger 4, the Y negative sense that Y forward loads joint and Y negative sense charger 4 loads joint, the Y negative sense connecting link of Y forward connecting link and Y negative sense charger 4, the Y negative sense oscillating bearing base of Y forward oscillating bearing base and Y negative sense charger 4, the Y negative sense mounting seat of Y forward mounting seat and Y negative sense charger 4, Y forward loaded seat is identical with the Y negative sense loaded seat of Y negative sense charger 4 and the Y negative sense displacement sensor structure of Y positive-displacement sensor and Y negative sense charger 4.
Described Y negative sense charger 4 is loaded joint, Y negative sense connecting link, Y negative sense oscillating bearing base, Y negative sense mounting seat, Y negative sense loaded seat and Y negative sense displacement transducer formed by Y negative sense left column 38, Y negative sense loading supporting base 39, Y negative sense right column 40, Y negative sense fixed bar, Y negative sense electrohydraulic servo valve, Y negative sense servo-cylinder, Y negative sense elastic device, Y negative sense pull pressure sensor, Y negative sense.
Described Y negative sense left column 38 top is divided into rectangular structure, the T-slot that right lateral surface has twice parallel, Y negative sense left column 38 bottom is divided into a rectangular flat plate, and dull and stereotyped left and right sides respectively have two U-shaped mouths, and four T-shaped bolts can be fixed on ground black iron 5 through U-shaped mouth.Described Y negative sense right column 40 top is divided into rectangular structure, the T-slot that left-hand face has twice parallel, Y negative sense right column 40 bottom is divided into rectangular flat plate structure, and dull and stereotyped left and right sides respectively have two U-shaped mouths, and four T-shaped bolts can be fixed on ground black iron 5 through U-shaped mouth.Consult Fig. 7, described Y negative sense loads supporting base 39 entirety and becomes I-shaped, intermediate portion is divided into rectangle structure, and have four circular holes to become two row two column distributions, for fixing Y negative sense mounting seat, the left surface of Y negative sense loading supporting base 39 and right flank are all rectangle structure and respectively there are two U-shaped mouths both sides up and down, T-shaped bolt Y negative sense loading supporting base 39 both sides can be separately fixed at Y negative sense left column 38 through U-shaped mouth and Y negative sense right column 40 has on the surface of T-slot, unclamp T-shaped bolt, Y negative sense loads supporting base 39 and can move in z-direction along the T-slot of Y negative sense left column 38 and Y negative sense right column 40.
The fixed bar 27 of Y negative sense fixed bar and Z forward charger 3, the electrohydraulic servo valve 28 of Y negative sense electrohydraulic servo valve and Z forward charger 3, the servo-cylinder 29 of Y negative sense servo-cylinder and Z forward charger 3, the elastic device 30 of Y negative sense elastic device and Z forward charger 3, the pull pressure sensor 31 of Y negative sense pull pressure sensor and Z forward charger 3, Y negative sense loads the loading joint 32 of joint and Z forward charger 3, the connecting link 33 of Y negative sense connecting link and Z forward charger 3, the oscillating bearing base 34 of Y negative sense oscillating bearing base and Z forward charger 3, the mounting seat 35 of Y negative sense mounting seat and Z forward charger 3, Y negative sense loaded seat is identical with the loaded seat 36 of Z forward charger 3 and displacement transducer 37 structure of Y negative sense displacement transducer and Z forward charger 3.
Described Y forward charger 1 is when implementing to load to loading unit 22, should ensure that Y forward loads joint and fully contacts with loading unit 22 and ensure that the piston rod of Y forward servo-cylinder is coaxial with Y forward connecting link and mutually vertical with the axes intersect of loading unit 22 as far as possible, namely mutual vertical thus realize the loading of Y-direction forward with the axes intersect of main shaft 14.When Y forward charger 1 does not load loading unit 22, the distance that Y forward loads joint disengaging loading unit 22 is 0.1mm to 0.5mm.
Described Y negative sense charger 4 is when implementing to load to loading unit 22, should ensure that Y negative sense loads joint and fully contacts with loading unit 22 and ensure that the piston rod of Y negative sense servo-cylinder is coaxial with Y negative sense connecting link and mutually vertical with the axes intersect of loading unit 22 as far as possible, namely mutual vertical thus realize the loading of Y-direction negative sense with the axes intersect of main shaft 14.When Y negative sense charger 4 does not load loading unit 22, the distance that Y negative sense loads joint disengaging loading unit 22 is 0.1mm to 0.5mm.
Five, Z negative sense charger
Consult shown in Fig. 1, described Z negative sense charger is loaded joint, Z negative sense connecting link, Z negative sense oscillating bearing base, Z negative sense mounting seat, Z negative sense loaded seat and Z negative sense displacement transducer formed by Z negative sense loading right column 6, Z negative sense loading crossbeam 7, Z negative sense loading left column 8, Z negative sense firm banking, Z negative sense fixed bar, Z negative sense electrohydraulic servo valve, Z negative sense servo-cylinder, Z negative sense elastic device, Z negative sense pull pressure sensor, Z negative sense.
Described Z negative sense loads right column 6 top and is divided into rectangular structure, its end face has two threaded holes, the bottom that Z negative sense loads right column 6 is divided into rectangular flat plate structure, and before and after dull and stereotyped, respectively there are two U-shaped mouths both sides, and four T-shaped bolts can be fixed on ground black iron 5 through U-shaped mouth.The structure that described Z negative sense loads left column 8 is identical with the structure that Z negative sense loads right column 6.It is rectangular flat plate structure that described Z negative sense loads crossbeam 7, the T-slot that dull and stereotyped below has twice parallel, Z negative sense holder can be fixed on Z negative sense by T-shaped bolt loads on crossbeam 7, unclamp T-shaped bolt, Z negative sense firm banking can move in the Y direction along the T-slot of Z negative sense loading crossbeam 7, respectively there are two counter sinks the both sides that Z negative sense loads crossbeam 7, and the two ends that Z negative sense can be loaded crossbeam 7 by four bolts are separately fixed on Z negative sense loading right column 6 and Z negative sense loading left column 8.
The firm banking 26 of Z negative sense firm banking and Z forward charger 3, the fixed bar 27 of Z negative sense fixed bar and Z forward charger 3, the electrohydraulic servo valve 28 of Z negative sense electrohydraulic servo valve and Z forward charger 3, the servo-cylinder 29 of Z negative sense servo-cylinder and Z forward charger 3, the elastic device 30 of Z negative sense elastic device and Z forward charger 3, the pull pressure sensor 31 of Z negative sense pull pressure sensor and Z forward charger 3, Z negative sense loads the loading joint 32 of joint and Z forward charger 3, the connecting link 33 of Z negative sense connecting link and Z forward charger 3, the oscillating bearing base 34 of Z negative sense oscillating bearing base and Z forward charger 3, the mounting seat 35 of Z negative sense mounting seat and Z forward charger 3, Z negative sense loaded seat is identical with the loaded seat 36 of Z forward charger 3 and displacement transducer 37 structure of Z negative sense displacement transducer and Z forward charger 3.
Described Z negative sense charger is when implementing to load to loading unit 22, should ensure that Z negative sense loads joint and fully contacts with loading unit 22 and ensure that the piston rod of Z negative sense servo-cylinder is coaxial with Z negative sense connecting link and mutually vertical with the axes intersect of loading unit 22 as far as possible, namely mutual vertical thus realize the loading of Z-direction negative sense with the axes intersect of main shaft 14.When Z negative sense charger does not load loading unit 22, the distance that Z negative sense loads joint disengaging loading unit 22 is 0.1mm to 0.5mm.
Y forward charger 1, Z forward charger 3, when Y negative sense charger 4 and Z negative sense charger load loading unit 22, the power that each device should be made as far as possible to load and main-shaft axis meet at a bit, by the various combination of above-mentioned four chargers, can realize moving arbitrarily within the scope of radial 360 ° radial hydrodynamic journal liquid polymers, the loading of static pressure load, thus reach both can to the fail-test under the general service condition of radial hydrodynamic journal liquid polymers i.e. random loading within the scope of its radial 360 °, also namely can load within the scope of its radial predetermined angular the fail-test under the specific service condition of radial hydrodynamic journal liquid polymers.
Six, automaton
Consult shown in Fig. 8, described automaton comprises upper industrial computer, the next programmable controller PLC, the next Y-direction servo controller (Y forward servo controller and Y negative sense servo controller each a set of), the next Z-direction servo controller (Z forward servo controller and Z negative sense servo controller each a set of), the next motor servo controller.
The RS-232C port of described programmable controller PLC is connected with the RS-232C port electric wire of upper industrial computer, the output terminal of programmable controller PLC is connected with cooler and two solenoid directional control valves respectively, for parameters such as the start and stop of controlled cooling model machine, the temperature of chilled water, for hydraulic power unit provides chilled water, control the start and stop of radial hydrodynamic journal liquid polymers oil supply system and the start and stop of loading hydraulic power unit by controlling solenoid directional control valve thus realize providing hydraulic oil to hydraulic loading device.The input port of programmable controller PLC overlaps with temperature sensor 24(two respectively), pressure transducer 18(m+n overlaps, the i.e. radial hydrodynamic journal liquid polymers oil-in in front end quantity m and rear end radial direction hydrodynamic journal liquid polymers oil-in quantity n sum) and the output port electric wire of radial hydrodynamic journal liquid polymers oil supply system be connected, for the working status parameter of feedback temperature parameter, pressure parameter and radial hydrodynamic journal liquid polymers oil supply system.
The RS-232C port of described Y-direction servo controller is connected with the RS-232C port electric wire of upper industrial computer, Y-direction servo controller and upper industrial computer carry out communication, the signal output part of Y-direction servo controller is connected with the signal input part electric wire of electrohydraulic servo valve and Y forward electrohydraulic servo valve and Y negative sense electrohydraulic servo valve, realize load cylinder and Y forward servo-cylinder and Y negative sense servo-cylinder by control electrohydraulic servo valve to move loading unit 22, the loading of static pressure load, in loading procedure, by displacement transducer and Y positive-displacement sensor and Y negative sense displacement transducer and pull pressure sensor and Y forward pull pressure sensor and Y negative sense pull pressure sensor, the displacement detected and pressure signal are passed to Y-direction servo controller through signal amplifier, realize closed-loop control.
Described Z-direction servo controller is the same with Y-direction servo controller principle, up direction carries out communication by RS-232C and upper industrial computer, servo-cylinder 29 pairs of loading units 22 that down direction realizes load cylinder and Z negative sense servo-cylinder and Z forward charger 3 by the electrohydraulic servo valve 28 controlling electrohydraulic servo valve and Z negative sense electrohydraulic servo valve and Z forward charger 3 move, the loading of static pressure load, in loading procedure, with the pull pressure sensor 31 of pull pressure sensor and Z negative sense pull pressure sensor and Z forward charger 3, the displacement detected and pressure signal are passed to Z-direction servo controller through signal amplifier by the displacement transducer 37 of displacement transducer and Z negative sense displacement transducer and Z forward charger 3, realize closed-loop control.
The RS-232C port of described motor servo controller is connected with the RS-232C port electric wire of upper industrial computer, the output terminal of motor servo controller is connected with the signal input part electric wire of servomotor 15, control the rotating speed of servomotor 15, simultaneously the scrambler of servomotor 15 inside again by signal feedback to motor servo controller, realize closed-loop control.
Upper industrial computer control inerface is worked out by VB, the rotating speed of selected servomotor 15 on control inerface, the temperature parameter of cooler, selected Y positive dirction, Y negative direction, Z positive dirction, the pressure size that Z negative direction loads, frequency, after waveform and load time etc. (do not need the direction loaded, above-mentioned relative parameters setting is 0), with the next programmable controller PLC, two Y-direction servo controllers, two Z-direction servo controllers and motor servo controller carry out serial communication by RS-232C, the first output current of the next programmable controller PLC controls the radial hydrodynamic journal liquid polymers oil supply system of solenoid directional control valve action launching, restart servomotor 15, last controlled cooling model machine cools to loading hydraulic power unit, output current controls electromagnetic switch valve events again, by load cylinder and Y forward servo-cylinder, Y negative sense servo-cylinder, servo-cylinder 29 pairs of loading units 22 of Z negative sense servo-cylinder and Z forward charger 3 move, the loading of static pressure load.The in real time working status parameter of the pressure of the temperature parameter of display cooler, radial hydrodynamic journal liquid polymers oil-in, temperature, oil supply system and the dynamic and static pressure load parameter that loads on the control inerface of upper industrial computer, the numerical value and the circle recording the main shaft 14 that clock gauge 19 is measured is beated.
Case study on implementation described in the utility model can understand for the ease of these those skilled in the art and apply the utility model, the utility model is a kind of case study on implementation or preferably technical scheme of optimization, therefore the utility model is not limited to the description implementing this kind of more specific technical scheme.Do not need through the equivalent structure change of creative work or various modification as charger changed into voice coil motor and vibrator etc. all in protection domain of the present utility model if relevant technician makes when adhering to the utility model basic technical scheme.

Claims (2)

1. a radial hydrodynamic journal liquid polymers reliability test bench, is characterized in that: it comprises testing table supporting, radial hydrodynamic journal liquid polymers servicing unit, Z forward charger, Z negative sense charger, Y forward charger, Y negative sense charger and automaton;
Described testing table supporting is ground black iron (5), described ground black iron (5) horizontal positioned, T-slot distributes along the X direction, for supporting and fixing be arranged in X-direction radial hydrodynamic journal liquid polymers servicing unit (2), be arranged in Y-direction Y forward charger (1), be arranged in Y-direction Y negative sense charger (4), be arranged in Z-direction Z forward charger (3), be arranged in Z-direction Z negative sense load right column (6) and be arranged in Z-direction Z negative sense load left column (8);
Described radial hydrodynamic journal liquid polymers servicing unit (2) is by supporting upright post (9), slip column (10), bearing block support plate (11), thrust bearing cover (12), rear radial hydrodynamic journal liquid polymers base (13), main shaft (14), servomotor (15), servomotor mount pad (16), front end support plate (17), pressure transducer (18), clock gauge (19), spring fitting device support plate (20), spring fitting device (21), loading unit (22), front radial hydrodynamic journal liquid polymers base (23) and temperature sensor (24) composition,
The top of described supporting upright post (9) is divided into rectangular structure, its end face has two threaded holes, the bottom of supporting upright post (9) is divided into rectangular flat plate structure, and dull and stereotyped two sides, front and back respectively have two U-shaped mouths, and four T-shaped bolts are fixed on ground black iron (5) through U-shaped mouth; Described slip column (10) top is divided into rectangular structure, its end face has two threaded holes, side is namely near the T-slot that the side of loading unit (22) has twice parallel, the bottom of slip column (10) is divided into rectangular flat plate structure, dull and stereotyped two sides, front and back respectively have two U-shaped mouths, and four T-shaped bolts are fixed on ground black iron (5) through U-shaped mouth; Described bearing block support plate (11) is rectangular flat plate structure, the T-slot that upper surface has twice parallel, and both sides respectively have two counter sinks, through counter sink, both sides is separately fixed at the end face of supporting upright post (9) by bolt;
Respectively there are two through holes at thrust bearing cover (12) two ends, bottom surface, and thrust metal (12) is fixed on bearing block support plate (11) through through hole by four T-shaped bolts; Described front end support plate (17) is rectangular flat plate structure, the T-slot that upper surface has twice parallel, the two ends of upper surface respectively have two counter sinks, through counter sink, two ends are separately fixed at the end face of supporting upright post (9) and the end face of slip column (10) by four bolts; Described servomotor mount pad (16) entirety is L shape structure, and four bolts divide four dull and stereotyped through holes to be fixed on servomotor mount pad (16) by servomotor (15) through L shape structure upper, have a motor axis hole in the middle of four through holes; The upper part of servomotor mount pad (16) is dull and stereotyped is welded with two reinforcements with bottom panel junction, respectively there are two through holes at the two ends of the upper surface of the bottom panel of servomotor mount pad (16), and servomotor mount pad (16) is fixed on front end support plate (17) through through hole by four T-shaped bolts; Servomotor (15) is connected with main shaft (14) by shaft coupling, thus drive shaft (14) is rotated;
Described pressure transducer (18) is connected to each oil-in place of radial hydrodynamic journal liquid polymers by T-valve; Described temperature sensor (24) is arranged on front radial hydrodynamic journal liquid polymers base (23), in like manner at the upper mounting temperature sensor (24) of rear radial hydrodynamic journal liquid polymers base (13); Described clock gauge (19) is placed near the rear of front radial hydrodynamic journal liquid polymers base (23) and the front of rear radial hydrodynamic journal liquid polymers base (13) respectively;
Described spring fitting device (21) is made up of upper flat plate, spring that lower flat board is identical with two, the shape of upper flat plate and lower flat board, size dimension is identical and be rectangle structure part, the lower surface of upper flat plate is welded with two crotches, lower dull and stereotyped upper surface is welded with two crotches equally, the middle position of lower dull and stereotyped two crotches has two circular holes, two springs are connected with a crotch of lower dull and stereotyped opposite position with a crotch of upper flat plate respectively, namely two springs are placed in upper and lower dull and stereotyped middle, and perpendicular to planar surface; Described spring fitting device support plate (20) entirety becomes L shape, the first half is a rectangular flat plate, respectively there are two circular holes dull and stereotyped both sides, the latter half is similarly a rectangular flat plate, respectively there is a U-shaped mouth dull and stereotyped both sides, and spring fixed support plate (20) is fixed on slip column (10) through U-shaped mouth by two T-shaped bolts to be had on the side of T-slot;
The rectangular flat plate of loading unit (22) both sides is through spring fitting device (21), namely the upper flat plate of two sleeve spring stationary installations (21) contacts with the rectangular flat plate of loading unit (22) both sides respectively, bolt through two circular holes dull and stereotyped under spring fitting device (21) and spring fitting device support plate (20) the first half side two circular holes thus spring fitting device (21) is fixed on spring fitting device support plate (20), spring fitting device support plate (20) is fixed in the T-slot of slip column (10);
Described Z forward charger (3) is made up of connection base (25), firm banking (26), fixed bar (27), electrohydraulic servo valve (28), servo-cylinder (29), elastic device (30), pull pressure sensor (31), loading joint (32), connecting link (33), oscillating bearing base (34), mounting seat (35), loaded seat (36) and displacement transducer (37); Described servo-cylinder (29) selects single piston or double-piston rod-type hydraulic jack, and electrohydraulic servo valve (28) is bolted to the upper surface of servo-cylinder (29) by four; Described connection base (25) is a rectangular flat plate structural member, the T-slot that its upper surface has twice parallel, and respectively there are two through holes both sides, and four T-shaped bolts will connect base (25) through through hole and be fixed on ground black iron (5); Described firm banking (26) entirety is L shape structure, top is divided into rectangular flat plate structure, flat board there are four circular holes become two row two column distributions, lower part is similarly rectangular flat plate structure, respectively there are two U-shaped mouths dull and stereotyped both sides, be fixed in connection base (25) by firm banking (26) through U-shaped mouth by T-shaped bolt, respectively there are two reinforcements firm banking (26) upper part rectangular flat plate and both sides, lower part rectangular flat plate junction; Described mounting seat (35) is a rectangular flat plate structure, it there is the T-slot that twice are parallel, twice T-slot center section has four counter sinks to become two row two column distributions, is fixed on firm banking (26) by four bolts through counter sink by mounting seat (35); Described loaded seat (36) is the box typed structure part being adopted the rear end open be welded by four block length square plates, the base plate of loaded seat (36) is provided with four through holes, by four T-shaped bolts, loaded seat (36) is fixed in mounting seat (35); Described fixed bar (27) is a multidiameter, and the two ends of fixed bar (27) are furnished with screw thread, and one end is connected with the lower surface threaded hole of servo-cylinder (29), and one end through the lower wall panels through hole of loaded seat (36), and is fixed by nut screwing clamping; Described displacement transducer (37) shell is fixed by screws on the cylinder body of servo-cylinder (29), and its inner core is connected with the piston rod upper end of servo-cylinder (29); Described elastic device (30) is made up of the nut that the identical bolt of lower end web joint, upper end web joint, sleeve that two structures are identical, two specifications is identical with two specifications; Wherein, upper end web joint is identical with lower end connecting board structure, and be a rectangular flat plate, its center position is provided with tapped through hole, respectively there is a through hole both sides of tapped through hole, and the external diameter of the sleeve that two structures are identical is greater than the diameter of two side through hole on lower end web joint and upper end web joint; The bolt that two specifications are identical inserts in the through hole of lower end web joint and web joint both sides, upper end, on two bolts of the identical sleeve set of two structures between lower end web joint and upper end web joint, finally by nut, sleeve identical to upper end web joint, two structures and lower end web joint are fixed together again; The upper end of the threaded hole on the web joint of lower end and servo-cylinder (29) piston rod is threaded connection, and the threaded hole on the web joint of upper end is threaded with the lower end of studs; The upper end of studs is threaded with pull pressure sensor (31), and the upper end of pull pressure sensor (31) is threaded with the lower end of another studs, and the threaded upper ends of this studs is threaded with oscillating bearing base (34) lower end; Described oscillating bearing base (34) is cylindrical structural part, and its inner chamber is similarly cylindrical structural and coaxial with periphery, and oscillating bearing base (34) upper surface open, lower surface are closed, and lower surface has a threaded hole; The inner chamber of oscillating bearing base (34) coordinates with oscillating bearing outer ring, oscillating bearing inner ring and connecting link (33) lower end interference fit; Described connecting link (33) is multidiameter structure, and namely medium axle diameter is greater than the two ends diameter of axle, and shaft shoulder place, lower end contacts with oscillating bearing inner ring, and upper end is furnished with screw thread and is threaded with loading joint (32); The upper surface of described loading joint (32) is an arc surface, arc-shaped surface is with one deck high damping high-abrasive material, arc radius is identical with the radius of the loading unit shell of loading unit (22), and the lower end loading joint (32) is rectangular structure, and there is a threaded hole its lower surface middle;
Described Y forward charger (1) is identical with the structure of Y negative sense charger (4); Y forward charger (1) is loaded joint, Y forward connecting link, Y forward oscillating bearing base, Y forward mounting seat, Y forward loaded seat and Y positive-displacement sensor formed by Y forward left column, Y forward loading supporting base, Y forward right column, Y forward fixed bar, Y forward electrohydraulic servo valve, Y forward servo-cylinder, Y forward elastic device, Y forward pull pressure sensor, Y forward; Y forward left column is identical with Y negative sense left column (38) structure of Y negative sense charger (4), it is identical that Y forward loading supporting base and the Y negative sense of Y negative sense charger (4) load supporting base (39) structure, Y forward right column is identical with Y negative sense right column (40) structure of Y negative sense charger (4), Y forward fixed bar is identical with the Y negative sense fixed rod structure of Y negative sense charger (4), Y forward electrohydraulic servo valve is identical with the Y negative sense electro-hydraulic servo valve arrangement of Y negative sense charger (4), Y forward servo-cylinder is identical with the Y negative sense servo-cylinder structure of Y negative sense charger (4), Y forward elastic device is identical with the Y negative sense elastic device structure of Y negative sense charger (4), Y forward pull pressure sensor is identical with the Y negative sense pull pressure sensor structure of Y negative sense charger (4), it is identical that Y forward loading joint and the Y negative sense of Y negative sense charger (4) load joint design, Y forward connecting link is identical with the Y negative sense connecting link structure of Y negative sense charger (4), Y forward oscillating bearing base is identical with the Y negative sense oscillating bearing understructure of Y negative sense charger (4), Y forward mounting seat is identical with the Y negative sense mounting seat structure of Y negative sense charger (4), Y forward loaded seat is identical with the Y negative sense loaded seat structure of Y negative sense charger (4), Y positive-displacement sensor is identical with the Y negative sense displacement sensor structure of Y negative sense charger (4), described Y negative sense charger (4) is loaded joint, Y negative sense connecting link, Y negative sense oscillating bearing base, Y negative sense mounting seat, Y negative sense loaded seat and Y negative sense displacement transducer formed by Y negative sense left column (38), Y negative sense loading supporting base (39), Y negative sense right column (40), Y negative sense fixed bar, Y negative sense electrohydraulic servo valve, Y negative sense servo-cylinder, Y negative sense elastic device, Y negative sense pull pressure sensor, Y negative sense, described Y negative sense left column (38) top is divided into rectangular structure, the T-slot that right lateral surface has twice parallel, Y negative sense left column (38) bottom is divided into a rectangular flat plate, dull and stereotyped left and right sides respectively have two U-shaped mouths, and four T-shaped bolts can be fixed on ground black iron (5) through U-shaped mouth, described Y negative sense right column (40) top is divided into rectangular structure, the T-slot that left-hand face has twice parallel, Y negative sense right column (40) bottom is divided into rectangular flat plate structure, dull and stereotyped left and right sides respectively have two U-shaped mouths, and four T-shaped bolts are fixed on ground black iron (5) through U-shaped mouth, described Y negative sense loads supporting base (39) entirety and becomes I-shaped, intermediate portion is divided into rectangle structure, and have four circular holes to become two row two column distributions, Y negative sense mounting seat is fixed on Y negative sense and loads on supporting base (39), Y negative sense loads the left surface of supporting base (39) and right flank is all rectangle structure and up and down respectively there are two U-shaped mouths both sides, and Y negative sense to be loaded supporting base (39) both sides through U-shaped mouth and is separately fixed at Y negative sense left column (38) and Y negative sense right column (40) has on the surface of T-slot by T-shaped bolt, Y negative sense fixed bar is identical with fixed bar (27) structure of Z forward charger (3), Y negative sense electrohydraulic servo valve is identical with electrohydraulic servo valve (28) structure of Z forward charger (3), Y negative sense servo-cylinder is identical with servo-cylinder (29) structure of Z forward charger (3), Y negative sense elastic device is identical with elastic device (30) structure of Z forward charger (3), Y negative sense pull pressure sensor is identical with pull pressure sensor (31) structure of Z forward charger (3), it is identical with loading joint (32) structure of Z forward charger (3) that Y negative sense loads joint, Y negative sense connecting link is identical with connecting link (33) structure of Z forward charger (3), Y negative sense oscillating bearing base is identical with oscillating bearing base (34) structure of Z forward charger (3), Y negative sense mounting seat is identical with mounting seat (35) structure of Z forward charger (3), Y negative sense loaded seat is identical with loaded seat (36) structure of Z forward charger (3), Y negative sense displacement transducer is identical with displacement transducer (37) structure of Z forward charger (3),
Described Z negative sense charger loads right column (6) by Z negative sense, Z negative sense loads crossbeam (7), Z negative sense loads left column (8), Z negative sense firm banking, Z negative sense fixed bar, Z negative sense electrohydraulic servo valve, Z negative sense servo-cylinder, Z negative sense elastic device, Z negative sense pull pressure sensor, Z negative sense load joint, Z negative sense connecting link, Z negative sense oscillating bearing base, Z negative sense mounting seat, Z negative sense loaded seat and Z negative sense displacement transducer and form; Described Z negative sense loads right column (6) top and is divided into rectangular structure, its end face has two threaded holes, the bottom that Z negative sense loads right column (6) is divided into rectangular flat plate structure, before and after dull and stereotyped, respectively there are two U-shaped mouths both sides, and four T-shaped bolts can be fixed on ground black iron (5) through U-shaped mouth; The structure that described Z negative sense loads left column (8) is identical with the structure that Z negative sense loads right column (6); It is rectangular flat plate structure that described Z negative sense loads crossbeam (7), the T-slot that dull and stereotyped below has twice parallel, by T-shaped bolt, Z negative sense holder being fixed on Z negative sense loads on crossbeam (7), respectively there are two counter sinks the both sides that Z negative sense loads crossbeam (7), by four bolts, the two ends of Z negative sense loading crossbeam (7) are separately fixed at Z negative sense and load on right column (6) and Z negative sense loading left column (8);
Z negative sense firm banking is identical with firm banking (26) structure of Z forward charger (3), Z negative sense fixed bar is identical with fixed bar (27) structure of Z forward charger (3), Z negative sense electrohydraulic servo valve is identical with electrohydraulic servo valve (28) structure of Z forward charger (3), Z negative sense servo-cylinder is identical with servo-cylinder (29) structure of Z forward charger (3), Z negative sense elastic device is identical with elastic device (30) structure of Z forward charger (3), Z negative sense pull pressure sensor is identical with pull pressure sensor (31) structure of Z forward charger (3), it is identical with loading joint (32) structure of Z forward charger (3) that Z negative sense loads joint, Z negative sense connecting link is identical with connecting link (33) structure of Z forward charger (3), Z negative sense oscillating bearing base is identical with oscillating bearing base (34) structure of Z forward charger (3), Z negative sense mounting seat is identical with mounting seat (35) structure of Z forward charger (3), Z negative sense loaded seat is identical with loaded seat (36) structure of Z forward charger (3), Z negative sense displacement transducer is identical with displacement transducer (37) structure of Z forward charger (3),
Described automaton comprises upper industrial computer, the next programmable controller PLC, the next Y-direction servo controller, the next Z-direction servo controller, the next motor servo controller;
The RS-232C port of described programmable controller PLC is connected with the RS-232C port electric wire of upper industrial computer, and the output terminal of programmable controller PLC is connected with cooler and two solenoid directional control valves respectively; The input port of programmable controller PLC is connected with the output port electric wire of temperature sensor (24), pressure transducer (18) and radial hydrodynamic journal liquid polymers oil supply system respectively;
The RS-232C port of described Y-direction servo controller is connected with the RS-232C port electric wire of upper industrial computer, the signal output part of Y-direction servo controller is connected with the signal input part electric wire of electrohydraulic servo valve and Y forward electrohydraulic servo valve and Y negative sense electrohydraulic servo valve, displacement transducer and Y positive-displacement sensor are connected with the signal input part electric wire of signal amplifier with the signal output part of Y negative sense displacement transducer, pull pressure sensor and Y forward pull pressure sensor are connected with the signal input part electric wire of signal amplifier with the signal output part of Y negative sense pull pressure sensor, the signal output part of signal amplifier is connected with the signal input part electric wire of Y-direction servo controller,
The RS-232C port of described Z-direction servo controller is connected with the RS-232C port electric wire of upper industrial computer, the signal output part of Z-direction servo controller is connected with electrohydraulic servo valve (28) the input end electric wire of electrohydraulic servo valve and Z negative sense electrohydraulic servo valve and Z forward charger (3), displacement transducer and Z negative sense displacement transducer are connected with the signal input part electric wire of signal amplifier with the signal output part of displacement transducer (37) of Z forward charger (3), pull pressure sensor and Z negative sense pull pressure sensor are connected with the signal input part electric wire of signal amplifier with the signal output part of pull pressure sensor (31) of Z forward charger (3), the signal output part of signal amplifier is connected with the signal input part electric wire of Z-direction servo controller,
The RS-232C port of described motor servo controller is connected with the RS-232C port electric wire of upper industrial computer, the output terminal of motor servo controller is connected with the signal input part electric wire of servomotor (15), and the signal output part of scrambler of servomotor (15) inside is connected with the signal input part electric wire of motor servo controller.
2. the radial hydrodynamic journal liquid polymers reliability test bench of one according to claim 1, is characterized in that: described loading unit (22) is made up of loading unit shell, two identical bearing (ball) covers, two identical deep groove ball bearings and two identical O-ring seals; The main body of described loading unit shell is cylindrical, respectively welds a rectangular flat plate in the axis equal-height position both sides, front end of its periphery; Loading unit shell has cylindrical cavity, and cylindrical cavity is coaxial with the periphery of loading unit shell; Described bearing (ball) cover bottom surface is disc-shaped structure, and medial surface has the edge of a circle projection, and there is a through hole at the center of bearing (ball) cover bottom surface, and the periphery circumference of bearing (ball) cover has six equidistributed through holes; The inner ring of deep groove ball bearing contacts with the shaft shoulder of main shaft (14), matches with loading unit shell cylindrical cavity in deep groove ball bearing outer ring, and bearing (ball) cover medial surface one encloses protruding edge and contacts with deep groove ball bearing outer ring; Through six through holes of bearing (ball) cover circumference, bearing (ball) cover is arranged on the two ends of loading unit shell by six bolts, main shaft (14) is through the through hole in the middle of bearing (ball) cover, and two O-ring seals to be arranged on respectively in the seal groove on the face of cylinder of two bearing (ball) cover through holes and to contact with main shaft (14).
CN201520171255.4U 2015-03-26 2015-03-26 Radial hydrodynamic journal liquid polymers reliability test bench Withdrawn - After Issue CN204439357U (en)

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104677633A (en) * 2015-03-26 2015-06-03 吉林大学 Reliability test platform for radial hydrostatic bearing
CN108106845A (en) * 2017-11-28 2018-06-01 中国直升机设计研究所 A kind of rod end resilient bearing radial load load testing machine
WO2020073578A1 (en) * 2018-10-10 2020-04-16 中国矿业大学 Device for testing bearing performance of vertical shaft lifting spindle device
CN112284597A (en) * 2020-12-30 2021-01-29 南京拓和机电科技有限公司 Pressure detection device of static pressure support tilting pad bearing

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN104677633A (en) * 2015-03-26 2015-06-03 吉林大学 Reliability test platform for radial hydrostatic bearing
CN104677633B (en) * 2015-03-26 2017-03-29 吉林大学 Radial direction hydrodynamic journal liquid polymers reliability test bench
CN108106845A (en) * 2017-11-28 2018-06-01 中国直升机设计研究所 A kind of rod end resilient bearing radial load load testing machine
WO2020073578A1 (en) * 2018-10-10 2020-04-16 中国矿业大学 Device for testing bearing performance of vertical shaft lifting spindle device
CN112284597A (en) * 2020-12-30 2021-01-29 南京拓和机电科技有限公司 Pressure detection device of static pressure support tilting pad bearing
CN112284597B (en) * 2020-12-30 2021-03-26 南京拓和机电科技有限公司 Pressure detection device of static pressure support tilting pad bearing

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