SU1530969A2 - Machine for testing hydrodynamic sliding-contact bearing - Google Patents

Abstract

The invention relates to mechanical engineering and allows increasing the accuracy and expanding the range of test modes. A hydraulic distributor with a regulating device, kinematically connected with the shaft turning mechanism and hydraulically with the loading mechanism, is rigidly fixed on the frame. The output of the electronic control unit is additionally connected to the control device of the hydraulic distributor. During the tests, the change in the amplitude of the external dynamic load is carried out simultaneously with the change in the duration of its effect on the bearing according to the angle of rotation of the shaft by adjusting the size of the slit in the hydraulic distributor, through which the working fluid passes into the hydraulic cylinder. 1 hp f-ly, 5 ill.

Description

one

(61) 871018

(21) 4302446 / 31-27

(22) 08/31/87

(46) 12/23/89. Bksh.№ 47

(71) Institute of Mechanical Engineering Problems, Academy of Sciences of the Ukrainian SSR

(72) V „A.„ Logvin, A.P., Kudr sh and A.N.Gots

(53) 621.822 (088 „8)

(56) USSR Author's Certificate No. 871018, cl. G 01 M 13/04, 1981.

(54) MACHINE FOR THE REMOVAL OF A HYDRODYNAMIC SLIDE BEARING

(57) The invention relates to mechanical engineering and permits an increase in the accuracy and an extension of the range of test modes. A hydraulic distributor with a regulating device, kinematically connected with the shaft turning mechanism and hydraulically with the loading mechanism, is rigidly fixed on the frame. The output of the electronic control unit is additionally connected to the regulator 1 (CMM device of the hydraulic distributor. During the tests, the change in the external dynamics of the external discharge is carried out simultaneously with the change in the duration of its effect on the bearing according to the angle of rotation of the shaft through which the working fluid passes hydraulic cylinder. 1 Cp f-crystals, 5 ill.

(L

The invention relates to mechanical engineering, can be used when testing hydrodynamic sliding bearings and is an improvement of the machine according to the author. St. No. 871018.

The purpose of the invention is to improve the accuracy and expand the range of test modes.

Figure 1 shows a diagram of the machine; Fig. 2 is a functional machine control circuit; on FIG. 3 — adjustable hydrodistributor, longitudinal section; figure 4 - section aa on fig.Z; Fig. 5 is a loading diagram of a test bearing on the angle of rotation of the shaft associated with it on a known (dashed line) and proposed machines (continuous line),

The machine (figo) contains a frame, a device 2 rigidly fixed on it for fixing the tested bearing 3, an actuator 4 of a shaft 5 of a bearing 3, a loading mechanism consisting of a hydraulic impulse 6 of direct excitation with a regulating device 7 installed on it, and also 8 rotation of the shaft 9 of the loading mechanism relative to the shaft 5 of the bearing 3 and the electronic unit 10 for controlling and maintaining in the oil layer of the bearing 3 a predetermined maximum value of hydrodynamic pressure, the input of which is connected by means of a mercury current collection ika (N) with the shaft 5 in the pressure sensor 11, and output - with the control device 7 of the loading mechanism.

SP

with about; about

ABOUT)

with

 rvj

The loading mechanism also contains a hydraulic cylinder 12, rigidly mounted on the bed 1, a rod 13 and a connecting rod 14 pivotally connected to it.

In addition, the machine contains a control valve 15 rigidly mounted on the base 1, which is kinematically connected through the hydropulsator 6 to the shaft turning mechanism 8 and hydraulically connected to the hydropulsator 6 and hydraulic cylinder 12 via pipelines 16 and 17

18 unloading line with capacity

19dl working fluid. The output of the electronic control unit 10 is additionally connected to the control device 20 of the hydraulic distributor

15. The electronic unit 10 is an integral part of the automated control system, the functional diagram of which is depicted in FIG. 2, where the ICD is the test bearing, the DC is the pressure sensor 11, RU 1 and RU 2 are the hydraulic pulsation control devices 6 and the hydraulic distributor 15.

The electronic unit 10 is surrounded by a dashed line and includes: Y - signal amplifier, for example, voltage - and supplied by sensor 11 (DC), PD - peak detector for highlighting the maximum value of hydrodynamic pressure in the oil layer of the bearing 3 expressed in voltage U, CU is the unit for setting the pressure reference value or or or, with which the comparison should be made. K. Comparison unit for voltages U ,, and mdks of control signal generation to control devices 7 and 20 (RC-1, RU-2).

The valve 15 (Fig.1, 3 and 4) includes a housing 21 with a cover 22, in which the inlet 23, the working 24 and the outlet 25 of the window. In the housing 21, a spool 26 is rotatably mounted, kinematically through a hydropulsator 6 associated with a shaft rotation mechanism 8 and having an axial 27 and radial distribution 28 channels. Contacts are made between housing 21 and spool 26.

sleeving sleeve 29 fixed

fixed, and the sleeve 30, having the ability to rotate around its axis. At the contacting ends of the sleeve 29 and the sleeve 30 is made protrusions 31 and 32,

about Q

five

0

five

forming adjustable slots 33 and 34.

The regulating device 20 of the hydraulic distributor 15 includes a worm gear, the worm to 35 of which is fixed to the shaft 36 of the actuator of the regulating device 20 (FIG. 1) fixed to the housing 21, and the worm gear 37 is made with the hub 30. The regulating device of the hydraulic distributor 15 also has two limit switches 38 mounted on the housing 21 and electrically connected with the drive of the regulating device 20. The limit switches 38 can be installed in various positions around the perimeter of the sleeve 30 and have the possibility of contacting e projection (N) and, consequently, turning off the drive control device 20 (without interrupting its reverse), limiting thus the bearing during the test range 3 control the duration of action of the load angle of the shaft 5 rotation.

The machine works as follows

The actuator 4 is turned on, the rotation from which is transmitted to the shaft 5 and through the mechanism 8 to the shaft 9 of the hydropulsator 6 and the slide valve 26 of the hydraulic distributor .15. The pressure of the working fluid created with a certain amplitude of the pulsations in the hydropulsator 6 is transmitted through the pressure pipeline 16 to the hydraulic distributor 15, where the working fluid through the inlet port 23 enters the slot 33, which at each turn of the spool 26 is aligned with the distribution window 28 of the specified spool 26, thereby allowing the working fluid pulse to pass through the channel 27 and the working window 24 to the pressure pipe 17 and the hydraulic cylinder 12. Next, the load through the rod 13 and the connecting rod 14 is transferred to the bearing 3. When p is aligned the distribution port 28 of the spool 26 with the slot 34 also periodically provides for the passage of a working fluid pulse in the opposite direction through the working window 24 and channel 27, but already to the outlet port 25 and through the discharge pipe 18 to the tank 19. The period T (FIG. 5) of the pulses generated thus, the load N depends on the frequency of rotation of the drive shaft 4, as well as the duration of the angle of rotation of the shaft 5 on the size of the slit 33. To obtain a load with a different value, the size of the slit 33 is changed by rotation using the device 20 of the sleeve 30 o t is a relatively fixed sleeve 29.

The rotation mechanism 8 of the shaft 9 (spool 26) relative to the shaft 5 serves to bias the rotating sensor 11 relative to the onset of the external dynamic load. Therefore, the sensor 1I will register in each case the complete distribution of the hydrodynamic pressure distribution in the oil layer 15, the switches 38 are installed in the bearing 3. The signal from the position sensor around the circumference of the sleeve 30 is fed to the mercury current collector and then to the input of the electronic control unit 10 where the comparison is made

corresponding to the extreme values of the operating range of the duration of action

values of the maximum hydrodynamic load, and tests are carried out on

Whose pressure in the bearing 3 with the specified technology.

the nominal (reference) value of this pressure. Thus, the application of a predlan. In case of inequality specified

pressure from the output of the electronic unit

The machine allows for greater accuracy and a wider range of modes.

IO sends a signal to the regulating devices 7 and 20 of the hydropulsator 6 and the hydraulic distributor 15, which provide a synchronous change of one or the other side of the amplitude and duration of the external load, thus maintaining the magnitude of the maximum hydrodynamic pressure in the bearing 3 at a predetermined level.

With the help of limit switches 38, the duration of the load is limited within the operating range of this unit, which uses bearing 3. Outside the specified limits by the regulating device of the hydraulic distributors, the correction of the hydrodynamic divider.

The pressure in the oil layer of the bearing is 3 2. The machine according to claim 1, is still produced due to a change in the fact that the hydrodistributor does not produce only hydrogas in the inside of the body from the pulsator 6. To do this, before the test bore and the inlet work, the operational bottom and outlet windows are installed, which are set within the range of the length of the movable opening of the sleeve with the load on the end, and with the possibility. deployed indicator diagrams in rotation around its axis of the sleeve, which function of the angle f of rotation of the shaft 50 made with a protrusion on the end with.

side of the sleeve and connected to the drive, as well as located in the sleeve and sleeve of the spool with axial and radial channels, and the axial channel of the device, etc. Then, when tested, 55 is connected to the working channel of the housing, and in particular, the sliding bearings are radially made with the possibility of internal piston engines connected to its outlet and intake run, the initial size of the gap 33 is set by the housing windows alternately.

the bearing is the gas pressure in the cylinder of the internal combustion engine, the pressure of the liquid (gas) in the piston space of the pump

0

corresponding to, for example, the average value of the range of change in the duration of the load (the range of action of the gas power AOR), 55, when testing the bearings of the combined internal combustion engines (range 80-180) 130, bearings that absorb the load from the imbalance 180, plunger bearings pumps and other machines with dynamically loaded bearing assemblies 180 - 360.

In each case, the end5 of the switches 38 is set to the position around the circumference of the sleeve 30,

 the switches 38 are set at the circumferential position of the sleeve 30,

corresponding to the extreme values of the operating range of the duration of action

The machine allows you to increase the accuracy and expand the range of modes

tests

Claims (1)

1. Machine for testing hydrodynamic sliding bearing according to ed. St. No. 871018, characterized in that it is equipped with a control valve rigidly mounted on the frame with a regulating device, kinematically connected with the shaft turning mechanism and hydraulically with the loading mechanism, while the output of the electronic control unit is additionally connected to t70  9 //////////// Y /// ///////////////: ///////////// l / l w // Y ////. 19 68231 srig.1 By FIG. 2 eleven 4HIJ / rtf r M. / 23 .7. h x. X Zi 36 3 21 35 FIG. J 33 Fiel