CS233552B1 - Testing device for sliding, especially bearing materials - Google Patents

Abstract

The device is intended for testing sliding materials, especially sliding bearing materials. It consists of a drive unit connected by a gear to a spindle, in which a test shaft is inserted, on which the tested bearing is mounted, fixed in a sleeve, equipped with a support device and a tensometric force sensor connected to a measuring instrument. The tensometric force sensor is arranged on the diaphragm of a servomotor connected to the outlet of the pressure medium from the reduction station, to which an electromagnetic converter is connected, while an arm is arranged on the bearing sleeve connected through a spring with elastic elements with an inductive transmitter connected both to a recorder and to a limiting regulator, the output of which is connected to the thyristor regulator of the drive unit.

Description

The invention provides a device for testing sliding materials, in particular sliding bearing materials.

So far, a sophisticated procedure has been used to solve sliding nodes and instruments in terms of tribological problems. The individual parameters were mostly determined separately on several types of test equipment. Testing carried out in several stages is complicated, the course of the tests is tedious and costly. Most of the testing machines serve as laboratory instruments for the determination of sliding / friction / characteristic quantities, which assess the suitability of the material for sliding bearings.

A more comprehensive assessment of materials used for plain bearings can be obtained on test model equipment, where the actual bearing model being tested or directly the actual bearing, where the closest approach to operating conditions, but even these test model equipment does not give a comprehensive assessment of test material.

These disadvantages are largely eliminated by the test device according to the invention.

The principle of the invention is that the device is made up of electrical, electronic and mechanical elements such that all parameters entered and measured, such as e.g. load force, sliding speed, frictional moment, test bearing temperature and ambient temperature are converted to an electrical signal and their size is recorded on a multi-curve chart recorder. The load force is generated by a liquid or gaseous medium in the diaphragm servomotor. It may be controlled manually or programmed according to the pre-selected for the gram determined by the test methodology.

233 552

A strain gauge force transducer is inserted between the actuator diaphragm and the load device, in which the load force is converted into an electrical signal whose size is proportional to its size. This signal is applied to a multi-curve recorder where the course of the load force is recorded on the registration paper.

The rotation of the test shaft on which the test sleeve with the test bearing is mounted is provided by a drive assembly, usually a direct current electric motor, which is controlled by a thyristor controller. The control of the thyristor controller and thus the continuous speed control of the electric motor can be carried out manually or programmatically.

The magnitude of the revolutions and thus the sliding speed is recorded on the recorder. The test sleeve in which the test bearing is mounted is connected to the inductive position transmitter by means of an arm and a rod. As a result of the rotation of the test shaft and the load force (perpendicularly), a frictional moment is generated which is balanced by the elastic element. The tilting of the sleeve with the arm is transmitted through these spring elements to the inductive position transmitter, in which an electrical signal is generated which is proportional to the friction moment. This signal is also applied to the recorder, where the frictional moment is recorded on the registration paper. The temperature measurement in the test bearing is converted using thermoelectric cells. Measurement of ambient temperature (working environment) is carried out by means of a Ptk resistor. Both temperatures are also recorded on the registration paper.

In the circuit for measuring the friction moment as well as the temperature of the tested bearing are included limiting regulators, whose task is to limit the max. permissible friction torque and maximum allowable temperature, thereby protecting the entire system against damage.

The test device according to the invention corresponds to a model device which allows the determination of the basic parameters of sliding bearing materials comprehensively in a single

skušobnom cjkle. The device allows to simulate the actual working conditions of the sliding bearing-shaft pair while ✓

retains the character of a laboratory instrument with the usual accuracy of measuring and sensing individual parameters. It is particularly suitable for quickly determining the basic sliding properties of bearing nodes, maximum bearing capacity of bearing materials, friction coefficient, temperature profile, sliding speed and wear. Fast test run allows relatively simple statistical evaluation and operative application.

The force on the test bearing is static and its size and course can be selected either by manual adjustment or by means of a pre-selected program. Similarly it is possible to change the course of the slide. The program control of the load force and the sliding velocity can be transferred simultaneously, simultaneously or independently of each other. The device can also be used for long-term life tests of plain bearings and after conversion treatment and tests under extreme conditions. It is also suitable for equipping with other accessories which enable to perform tests of radial-axial or only axial plain bearings.

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An exemplary embodiment of a test apparatus according to the invention is shown in the accompanying drawings, in which Fig. 1 is a schematic side view of a mechanical part of the apparatus; 2 shows a schematic side view of the mechanical part of the device, FIG. 3 block wiring diagram »

233 SS2

- 4 The test equipment consists of a drive unit. 1 coupled to the headstock 2, v

in which the test shaft 2 a is clamped. Test bearing 6 is built into sleeve 2. · Test bearing 6 mounted on test shaft 2 and the load applied to the servomotor 3 via a strain gauge 17 and load mechanism 2 · The pressure medium (gas or liquid) is delivered to the device via a pressure reducer a station 14 (FIG. 3) to an electromagnetic converter 13 where the medium is adjusted to the desired pressure. A pressure medium is provided from the electromagnetic converter 13 to the servomotor J, where it exerts a load force. The magnitude of the load force can be controlled by actuating the electromagnetic transducer 13 manually by means of the control device 13 or by a programmable control device 15b. In the strain gauge sensor 17, by applying a load force, an electrical signal is generated, which is coupled to a multi-curve recorder Z, where it occupies one of the measured locations. The waveform and the magnitude of the load force are recorded as a function of time. The test socket 2 ^e J by the arm 3 and the rod 4 through a spring connected to the elementary 8 due to friction in the sliding bearing test node 6 - The shaft 2 and leads to vvchýleniu arm and also the sag elastic elements eighth

This deflection is transmitted to the inductive position transmitter 20 where an electrical signal is generated which is proportional to the frictional moment. This signal is applied to the limiting controller 21 and to the recorder Z, where it occupies the others. measured location. The maximum permissible frictional torque can be set on the limiting regulator 21. If it is exceeded, the entire device is switched off. The microswitch 20a is mechanically coupled to the inductive position transmitter 20 and provides protection against excessive overloading of the device and protects the mechanical parts of the device from damage when the bearing 6 is abruptly seized.

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Rotational movement of the shaft 2 a is induced by the drive assembly 1 by means of a mechanical transmission 1 b. The speed of the drive unit 1 is controlled by a thyristor speed regulator 1e which can be controlled manually by the control device 15 or by a program control device 15b. The test shaft speed sensed by the tachogenerator 3 and their instantaneous size can be read on the measuring instrument 4 a. The electrical signal that is generated in the tachogenerator 3 and is fed via the adjusting intermediate 5b to the recorder Z, where the course and magnitude of the sliding speed of the twisted shaft 2a are continuously recorded.

The measurement of the temperature in the twisted bearing 6 is converted by means of the thermoelectric element 31. The course and the magnitude of the temperature in the bearing 6 are also recorded on the recorder Z. The electrical signal from the thermoelectric element 31 is also applied to. a limiting regulator 21, wherein v

It shows the instantaneous temperature values and is also connected by a bad coupling to a 1 c speed thyristor regulator.

The maximum permissible temperature of the tested sliding node can be set on the limiting regulator. After it is exceeded, the device is taken out of operation.

The recorder Z is further connected with an ambient temperature sensor 3.3, which records the course of the working environment temperature during the test.

The test device according to the invention is intended to rapidly determine the parameters and properties of plain bearings in general, particularly porous carbonated bearings produced by powder metallurgy technology, as well as other sliding elements intended as sliding pairs.

The device allows four basic tests to be carried out:

and / limit load test /. seizure test /,

233 552 b / limit speed test / so-called. speed restraint /, c / load test to determine /p.v/ diagram, d / durability test / durability /;

- the limit load test shall be carried out to determine the max. load capacity of given sliding material / boundary / p.v / curve in area of specific load p / MPa /,

- the limit speed test is carried out to determine the max. permissible sliding speed of the sliding material / limitation p.v / curve in the sliding speed area v / ms "^ /.

- the load-bearing test is carried out in order to determine the /p.v/ curve of the sliding material,

- the durability / durability / plain bearing or material test is carried out to determine the max. the failure-free running time of the bearing under certain operating conditions (depending on the sliding speed and gentle load).

The test machine allows the simulation of the operating conditions of the sliding node when these are within its technical parameters / 0 - F ^ max,

- Vmax /, or running model tests of sliding materials on standard test bearing and shaft dimensions. It is possible to work at a constant speed and the variable parameter becomes a specific load, which can be set manually or is changed automatically according to a pre-selected program. The device can also operate in the opposite direction, i.e. with constant load and sliding speed, it can be selected individually or programmed. If necessary, it is possible to run the two main parameters, i. load at sliding speed v ”independently programmed.

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- 7 The measuring system of the testing machine, in addition to the main parameters "p" and v, allows the measurement and recording of other parameters such as bearing temperature, friction torque (from which the friction coefficient "^") and working temperature (ambient) are calculated.

During the test, the operating personnel only perform a random check of the measuring and recording instruments and the operation of the equipment. When the program ends or when the pre-selected max. permissible bearing temperature or max. the friction coefficient stops the machine automatically. Upon completion of the test, it is necessary to graphically record the course of the test / which is made by the recorder / decrypt into numerical form to the relevant test reports / tables /. The test data obtained in this way can be statistically processed and evaluated. Based on the determined and processed hoandt of individual parameters, it is possible to determine the following interrelated relations:

- friction coefficient as a function of load at constant sliding speed / ^ u = F / p /, at v = constant /

- friction coefficient in dependence on sliding speed at constant load / ^ u = F / v, p = constant /

- load dependence p on sliding speed ^M in ^M at const. temperature T p = F / v / χ T = const.

and the opposite v = F (p); T = const.

- wear dependence on load and sliding speed;

- dependence of bearing temperature on load or sliding speed;

- relationship between wear and friction coefficient.

Claims (3)

Sliding test device, in particular bearing materials, consisting of a drive assembly coupled to a headstock in which a test shaft bearing a test bearing is mounted, mounted in a sleeve, provided with a load cell with a strain-gauge force sensor connected to a measuring instrument, characterized in that a tensometric force sensor (17) is provided on the diaphragm of the servomotor (3) connected to the output of the pressure medium from the reduction station (14) to which the electromagnetic converter (15) is connected, 6) there is provided an arm (5a) connected via a rod (4) with resilient element (8), with an inductive transmitter (20) connected both to the recorder (Z) and to the limiting regulator (21), whose output is connected to a thyristor by the drive unit regulator (1c). Testing device according to claim 1, characterized in that the electromagnetic transducer (15) and the thyristor speed regulator (1c) associated with the microswitch (20 a) mounted on the inductive transmitter (20) are provided with a hand control device (15 a) with programmable control device / 15 b /. Testing device according to claim 1, characterized in that an ambient temperature sensor (33) and a thermocouple (31) for measuring the temperature in the test bearing (6) with a built-in limiting regulator (21) are connected to the recorder (Z). connected to ie / ristor controller / lc / speed.