RU2498256C2 - Method for non-switching test on centrifuge of electromagnetic relays with self-reset - Google Patents

Abstract

FIELD: test equipment.

SUBSTANCE: all tested relays are installed simultaneously on a centrifuge; measurement and control of parameters of the relays are combined and performed simultaneously at all the relays without any switching of wires per one increase of voltage of only one current source E₁ of power supply of coils of all the relays simultaneously till actuation voltage of all the relays and per one decrease till reset voltage of all the relays. Voltage of current source E₁ is changed at variable speed: quickly out of voltage intervals of both probable actuation, and probable reset of the relay, and slowly inside those intervals, and by switching only one toggle switch of plus supply of voltage of source E₁ simultaneously to coils of all the relays it is possible to change over from measurement and control of one combination of parameters simultaneously at all the relays to measurement and control of the other combination of parameters simultaneously at all the relays, and by including a certain number of toggle switches, it is possible to measure and control the parameters randomly of any combination of the relays. Measurements and control of parameters are performed for several times at the test interval with further exclusion of obviously erroneous results, and as evaluation of the parameter value there taken is average value of the rest results; with that, first, two measurements are performed; the obtained results are compared to the Specification (TU) requirements and to the results of the previous tests, and accuracy of measurement results is specified; if the result is erroneous, additional measurements are performed till an accurate results is obtained, and as evaluation of the parameter, there taken is average value of the previously obtained and additional measurements.

EFFECT: number of simultaneously tested relays is increased; switching of wires of the diagram is excluded during the test; the relay test procedure is simplified; evaluation accuracy and reliability of control of the relay parameters is improved.

3 cl, 1 dwg

Description

Application area. The invention relates to testing equipment, in particular to methods for testing electromagnetic products, namely electromagnetic relays with self-resetting by linear accelerations in a centrifuge, and can be used to test more than two relays in a centrifuge simultaneously.

Analysis of analogues and prototype. There is a known [1] method of pairwise-sequential tests in a centrifuge of two electromagnetic relays simultaneously with self-resetting along three mutually perpendicular axes X, Y and Z with switching wires, including installing the first pair of relays on a centrifuge in a position in which linear acceleration is created along the X axis, spinning the centrifuge to a predetermined speed, by switching wires connect two DC sources, a control lamp and measuring circuits to the first relay, turn on both current sources and alternate measuring and sequentially monitoring the parameters of the first relay by changing (increasing and decreasing) the voltage of both current sources, turning off both current sources, by switching wires, connecting the same as for the first relay, two current sources, a control lamp and measuring circuits to the second relay, switching on of both current sources and analogous, as for the first relay, alternating measurement and alternating control of its parameters by a similar change in voltage of both current sources, centrifuge stop, turn off reading both current sources, turning the first pair of relays to a position where linear acceleration is created along the Y axis, spinning the centrifuge to a predetermined number of revolutions, by switching the wires, the connection is similar to that along the X axis, the connection of both current sources and the same alternating measurement and alternately monitoring the parameters of the first and second relays in turn, stopping the centrifuge, turning off both current sources, turning the first pair of relays to a position in which linear acceleration is created along the Z axis, untwisting centrifuge to a predetermined number of revolutions, turning on both current sources and a similar alternating measurement and alternating control of parameters at the first and second relays, stopping the centrifuge, turning off both current sources, removing the first pair from the centrifuge and installing the second relay pair on the centrifuge and its similar tests , then similar tests of the remaining pairs of relays. In this case, the measurement and control of the parameters of each relay are carried out in turn: first, measurement, then control. As an estimate of the parameter, take the result of one of its only measurements. The moment of operation (return) of the relay is determined by the ignition (extinction) of the signal lamp, and the voltage of operation and return of the relay is measured with a voltmeter at the current source supply voltage to the relay coil. Changing the position of the relay in a centrifuge is done by changing the position of the device for mounting the relay on the rotary table and turning the centrifuge test table (long and laborious operation - you need to unscrew and tighten the bolts again).

According to the technical specifications (TU) [2], a total of ten relays must be tested. In this case, it is necessary for each relay to measure two parameters: the operating voltage and the return voltage, as well as to control two parameters: the relay's ability to hold the contacts first in the closed and then in the open state when the relay is subjected to centripetal acceleration. Therefore, it is necessary to install 2 relays on the centrifuge 5 times (make 5 bookmarks) and each pair must be tested in three mutually perpendicular axes X, Y and Z, i.e. only 10 relays have to carry out 15 similar tests, which take two working days, and only three minutes are given to test each pair of relays on one axis along the TU (test interval).

This method is the only analogue and at the same time a prototype of the claimed method.

The disadvantages of this method are a small number (only two) of simultaneously tested relays, a large number of switched electrical wires for the entire duration of the test, complex technology (routine, burdensome) and a long test time, a long time to measure each parameter with low accuracy of its estimation, short time and low reliability of parameter control, large resource, energy and labor costs for testing (the centrifuge is rotated by a powerful electric motor).

Patent studies of inventions and utility models of the Russian Federation, the CIS countries and foreign countries on the classes G01M 7/00; G01M 7/02; G01M 7/06; H01H 51/00; H01H 51/02; G01P 21/00 from 1994 to the present. When conducting analysis of the prior art on patent information sources, no analogues were found that are characterized by features that are identical to all the essential features of the claimed invention. When analyzing the prior art by scientific and technical sources, one analogue was discovered [1], which was adopted as a prototype.

The purpose of the invention is to increase the number of simultaneously tested relays, eliminating the switching of wires during the test, simplifying the technology and reducing the test time, improving the accuracy of evaluation and reliability of monitoring relay parameters, reducing resource, energy and labor costs.

This goal is achieved by the fact that all the tested relays are installed on a centrifuge at the same time, the relays are measured and controlled at the same time and carried out simultaneously on all relays without switching wires for one voltage increase of only one current source E ₁ (see Fig.) Powering the coils of all relays simultaneously response to a voltage of the relay and one for reduction of the current source voltage E ₁ to return all relays, current voltage source _E1 change variable speed: fast as the voltage intervals is veroyatnog response and probable return relay and slowly within these slots, and by switching only one toggle switch T ₁ feed plus voltage source E ₁ simultaneously on all the relay coils can instantaneously move from the measurement and control of one set of parameters at the same time all the relay to the measurement and monitoring a different set of parameters at the same time for all relays, and by switching on a certain set of toggle switches T ₂ , ..., T _{n + 1,} you can measure and control the parameters for the choice of any set of relays, while I and the parameters are monitored several times on the test interval, followed by the exclusion of clearly erroneous results, and the average value of the remaining results is taken as an estimate of the parameter, moreover, two measurements are taken initially, the results are compared with the requirements of TU and with the results of earlier tests, and the accuracy of the results is established measurements, if the result is erroneous, additional measurements are made until an error-free result is obtained, while taking the parameter estimate average value of previously obtained and additional measurements. The moment of operation (return) of the relay is determined by the ignition (extinction) of the signal lamps, and the voltage of operation and return of the relay is measured with a voltmeter at the current source E _{1 of} supplying voltage to the relay coils.

The drawing shows a device for implementing the inventive method of testing a relay in a centrifuge.

The device contains two DC sources E ₁ and E ₂ , a signal-switching device (UPC) 1, a terminal board in the operator’s room 2, a terminal board of a centrifuge 3, a device for attaching a relay 4, four groups of spatially dispersed electrical jumpers П ₁ , П ₂ , P ₃ , P ₄ between the outputs of the circuit elements, four groups of toggle switches T ₁ , ..., Ti, ..., T _{n + 1} , while the SKP contains a signal unit (SB) 5, which in turn contains signal lights L ₁ , ..., Лi, ..., Лn, the number of which is equal to the number of tested relays, and the device for cre The relay panel contains the tested relays 7 P ₁ , ..., Pi, ..., Pn, the block of plug connectors (ШР) 6, which contains, in turn, the plug connectors 8 Ш ₁ , ..., Шi, ..., Шn, the number of which is equal to the number of tested a relay, and one group of jumpers P ₁ is located directly in the UPC, one P ₂ in the SB and two groups of jumpers P ₃ and P ₄ in the SR block, two groups of toggle switches T ₁ , T ₂ , ..., Ti, ..., Tn are directly in the SKP and two groups T ₃ , T ₄ , ..., T _{i + 1} , ..., T _{n + 1} - in the SB. The first group of toggle switches includes one toggle switch - T ₁ , the second - toggle switches T ₂ , ..., Ti, ..., Tn, in the third - one toggle switch T ₃ , in the fourth - toggle switches T ₄ , ..., Ti + 1, ..., Tn +1 The groups of jumpers and toggle switches differ in their functions, namely, through jumpers P _{1 they} supply minus voltage from the source E ₁ to the coils of the corresponding relays, through jumpers P _{2 they} supply minus voltage from the source E ₂ to the signal lights and contacts K ₁ , ..., Ki , ..., Kn of all relays (in Fig. The contacts are shown as a separate element for a clear understanding of the essence of the claimed method of relay testing; physically, the contacts are an integral structural element of the relay), through jumpers P _{3 they} supply plus voltage from the source E ₁ to the coils simultaneously of all relays, through jumpers П _{4 they} supply plus voltage from the source Е ₂ to the contacts of all relays simultaneously; through the tumbler T ₁ plus voltage supplied from the source ₁ E spool simultaneously all the relays through tumblers T _2, ..., Ti, ..., Tn is supplied from the negative voltage source _E1 to the respective relay coil, i.e. include the corresponding relay, through the toggle switch T _{3 they} supply plus voltage from the source E ₂ to the contacts of all relays simultaneously, through the toggle switches T ₄ , ..., Ti + 1, ..., Tn + 1 they supply minus the voltage from the source E ₂ to the contacts of the corresponding relays, t .e. turn on the signal lights of the respective relays when their contacts are closed. The device for mounting the relay contains the number of seats for the relay, equal to the number of tested relays.

For protection by a patent of the Russian Federation, a non-switching method of testing in a centrifuge simultaneously more than two self-resetting electromagnetic relays is proposed, which relates to testing equipment, in particular, testing electromagnetic products, namely, methods of testing electromagnetic relays with self-resetting by linear accelerations in a centrifuge, and can be used for testing simultaneously more than two relays in a centrifuge.

SUMMARY OF THE INVENTION All the tested relays are immediately installed on the centrifuge in a position in which linear acceleration is created along the X axis, the centrifuge is untwisted to the specified speed, both current sources and all toggle switches on the UPC are turned on, on source E, the voltage is set lower than the voltage of the probable relay operation (indicated in TU), and on E ₂ - the rated voltage sufficient to ignite the signal lights when the relay contacts are closed (indicated in the TU). Increasing the voltage of the source E, to the operating voltage of all relays, and then decreasing this voltage to the voltage of the return of all relays, measure by the voltmeter available on the source E ₁ , the voltage of operation and return of all relays for one change (increase and decrease) of the voltage on and turn off the warning lights. At the same time, the measurement and control of the parameters of all relays are combined simultaneously, i.e. when measuring both the operating voltage and the return voltage, both parameters are monitored, namely, when measuring the relay operating voltage for relays that have already tripped (their signal lamps are on), they control the relay contacts spontaneously (by the extinction of the lamps) under centripetal acceleration and at the same time, for relays that still do not work (their signal lamps do not light), they control the spontaneous closing of relay contacts (by light bulbs) under the action of centripetal acceleration and Borot, namely, when measuring the voltage of the relay return for already released relays (their signal lights went out), they control the spontaneous closure of relay contacts (by light bulbs) under the action of centripetal acceleration, and for those relays that remained in the triggered state (their signal lights are on) bulbs) control the spontaneous opening of relay contacts (by the extinction of bulbs) under the action of centripetal acceleration.

Consequently, for only one change (increase and decrease) of only one current source E _{1, it is} possible not only to measure both voltages (tripping and return) of all relays, but also to monitor twice both parameters of all relays. It is this set of operations and the complete exclusion of switching the wires of the measuring circuits that make it possible to redistribute time over a limited test interval (three minutes according to the technical specifications) to increase the accuracy of the assessment and reliability of monitoring relay parameters by repeatedly measuring and monitoring parameters of all relays in the test interval. As an estimate of the parameter, take the average value of the results of its measurements. Similar tests are carried out on the Y and Z axes.

The toggle switches allow you to measure and control the parameters of all or any choice of relay sets, while by switching only one toggle switch supplying plus voltage of the source E ₁ to the coils of all relays, you can instantly switch from measuring and monitoring one set of parameters at the same time for all relays to measuring and monitoring a different set of parameters simultaneously for all relays.

In order to speed up the process of obtaining an estimate of the parameter value, two measurements are made, the results obtained are compared with the requirements of TU and with the results of earlier tests. If the obtained two measurement results are close to each other, satisfy the requirements of TU and are within the statistical spread of the measurement results in previous years, then the measurement process is completed, and the average value of these two measurements is taken as an estimate. If one measurement is erroneous, additional measurements are made until an error-free result is obtained, the average value of two measurements is evaluated: one previously obtained and an error-free additional.

With a large number of tested relays, two testers test them simultaneously, while one changes the voltage on the relay coils and takes a voltmeter reading, and the second registers this reading and monitors the status of the signal lights.

In the case of installing the relay twice in a centrifuge, the sequence of relay tests along the axes during the second installation is reversed, i.e. during the first installation - X → Y → Z, during the second installation - Z → Y → X.

The technical feasibility of the method. First, set all the relays on the centrifuge to position X, assemble the electrical circuit, as shown in Fig., Turn on all the switches on the UPC, turn on both current sources, set the rated voltage on source E ₂ (indicated in the technical specifications), and set the minimum voltage on source E ₁ voltage (less than the response voltage of the relay). In this case, plus from the source E ₁ is fed through the included toggle switch T ₁ , jumpers P ₃ and the first contacts of all plug connectors Ш ₁ , ..., Шi, ..., Шn to the first outputs of the coils of all relays, and minus from the source E ₁ through jumpers П1, the included toggle switches T ₂ , ..., Ti, ..., Tn, the second terminals of the plug connectors Ш ₁ , ..., Шi, ..., Шn is supplied to the second terminals of the coils of all relays. However, none of the relays will trip because the source voltage E _{1 is} set to minimum. Plus from the source E ₂ through the included toggle switch T ₃ , jumpers P ₄ and the third terminals of the plug connectors Ш ₁ , ..., Шi, ..., Шn is supplied to the first outputs of the contacts of all relays, and minus from the source E ₂ through jumpers P ₂ , the included toggle switches T ₄ , ..., Ti + 1, ..., Tn + 1 bulbs L1, ..., Li, ..., Ln, the fourth terminals of the plug connectors Ш1, ..., Шi, ..., Шn is supplied to the second terminals of the contacts of all relays. But the lamps L1, ..., Li, ..., Ln will not light up, since the relays did not work and their contacts K1, ..., Ki, ..., Kn are open.

Measurement and control of relay parameters is as follows. First measure the voltage of the relay. To do this, after spinning the centrifuge to a predetermined number. revolutions, quickly increase the voltage of the current source E ₁ to a value that is obviously lower than the relay actuation voltage (this voltage is known from TU and is determined empirically), and then smoothly and slowly in the interval of the voltage of the probable relay operation until all relays operate. In this case, the contacts of all relays K1, ..., Kn are closed and the lamps L1, ..., Ln are lit. At the time of ignition of the bulbs by the voltmeter available at source E ₁ , the response voltage of the corresponding relays is recorded. At the same time, during the increase in the voltage of the current source E ₁ before the operation of all the relays, both parameters are monitored for all relays: for the relays that have already worked (they have signal lights on), spontaneous opening of the contacts is controlled (by the extinction of the bulbs) under the action of centripetal acceleration, for non-working ones more relays (their signal lights are off) control the spontaneous closing of contacts (by the light of the bulbs on) under the action of centripetal acceleration. To do this, you only need to observe the signal lights. Here it should be taken into account the fact that when measuring the voltage of the relay, after the lamp of a relay lights up, the test of spontaneous opening of the contacts of this relay under the action of centripetal acceleration has already begun, since the contacts of this relay remain closed while they measure the voltage of the other relays. And so for all relays. It turned out that during the measurement of the response voltage of the next relay, the fact of spontaneous opening of the contacts of all previously triggered relays was already monitored. they stayed on. Moreover, we take into account one more fact. The greater the voltage applied to the relay coil, the greater the force of contact pressing and keeping them closed. Therefore, if under the action of linear acceleration, the contacts remain closed at a lower voltage, then, moreover, they will be kept closed and at a higher voltage, since the acceleration in the test interval remains constant. Thus, during the measurement of the response voltage of all the relays, both parameters of all the relays were monitored - spontaneous opening and closing of their contacts under the action of centripetal acceleration, i.e. measurement of the operating voltage and control of both parameters are combined and are carried out simultaneously for all relays.

After that, the voltage of the relay return is measured. To do this, quickly reduce the voltage of the source E ₁ to a value that is known to be higher than the relay return voltage (this voltage is known from TU and determined empirically), then smoothly and slowly in the voltage range of the probable return (release) of the relay until all the relays are released. At the time of the extinction of the bulbs, the return voltage of the corresponding relays is recorded by the voltmeter available on the source E ₁ . At the same time, during a decrease in the voltage of the current source E ₁ before the start-up of all the relays, both parameters are monitored for all relays: for the relays that have already released (their signal lights go out), they control the spontaneous contact closure (by light bulbs) under the action of centripetal acceleration, unreleased relays (they still have signal lights on) control the spontaneous opening of contacts (by the extinction of the bulbs) under the action of centripetal acceleration. To do this, you only need to observe the signal lights. Here, it should be taken into account that when measuring the voltage of the relay return, after the light of some relay goes out, the spontaneous closure of the contacts of this relay under the action of centripetal acceleration has already begun, since the contacts of this relay remain open while they measure the return voltage of the other relays. Thus, during the measurement of the return voltage of all relays, both parameters of all relays were monitored - spontaneous closure and opening of their contacts under the action of centripetal acceleration, i.e. measurement of return voltage and monitoring of both parameters are simultaneous and carried out simultaneously for all relays.

Thus, for only one voltage change (increase to the operating voltage of all relays and decrease to the return voltage of all relays) of only one current source E _1, supply plus voltage to the coils of all relays at the same time, it is possible to measure and double-check all parameters at the same time for all relays, combining measurement and control operations. This technique, as well as the complete absence of switching wires, can significantly reduce the time of one measurement and control of all parameters of all relays and provide the ability to measure and control the parameters several times on the test interval and, thereby, significantly increase the accuracy of assessment and reliability of control of relay parameters .

The toggle switches completely exclude the switching of wires and, thereby, significantly simplify the technology and the complexity of the tests and increase the time for measuring and monitoring parameters. Recall that for testing the relay on one axis, it takes only three minutes according to the technical specifications. The diagram shows that through the toggle switch T ₁ voltage is applied to one output of the coils of all the relays simultaneously. If you turn on the T ₁ toggle switch, then all the relays will work simultaneously and, accordingly, all the signal lights will come on, provided that all the other toggle switches are on. Observing the burning lamps, they control the reliability of keeping the contacts in the closed state at the same time of all relays. If any light goes out, therefore, the contacts of this relay spontaneously open under the action of centripetal acceleration. If you turn off the T ₁ toggle switch, all relays are simultaneously released and, accordingly, all the lights go out. Observing the extinguished bulbs, they control the reliability of holding the contacts in the open state at the same time of all relays. If any light comes on, therefore, a spontaneous short circuit of the contacts of this relay occurred under the action of centripetal acceleration. Toggle switches T ₂ , ..., Ti, ..., Tn + 1 allow you to choose any set of relays for testing by turning off the desired toggle switch numbers.

Therefore, by switching only one toggle switch T _1, it is possible to measure and control all the parameters of all relays at the same time, and due to the toggle switches T ₂ , ..., Ti, ..., Tn + 1, you can select any relay set, without any wire switching . Moreover, only by switching only one T1 toggle switch almost instantly it is possible to switch from measuring and monitoring some parameters of all relays at the same time to measuring and monitoring other parameters at the same time of all relays.

It should be noted that a rapid increase (decrease) in the voltage of the source E ₁ at the beginning of the process of increasing (decreasing) its voltage allows you to "save" time and use it for additional measurement and control of relay parameters. Repeated measurement and control of relay parameters allows using the average statistical value of a sample of measurement results as a parameter estimate.

In order to accelerate the process of obtaining an estimate of the parameter, it is proposed to initially make two measurements, compare the results with the requirements of TU and with the results of earlier tests. If the obtained two measurement results are close to each other, satisfy the requirements of TU and are within the statistical spread of the measurement results in previous years, then the measurement process is completed, and the average value of these two measurements is taken as an estimate. If one measurement is erroneous, additional measurements are made until an error-free result is obtained, the average value of two measurements is evaluated: one previously obtained and an error-free additional.

In order to reduce the time of measuring and monitoring the parameters of the relay, it is proposed to test the relay for two testers, with one tester changing the voltage on the relay coils and taking a voltmeter reading, and the second tester will record this reading and monitor the status of the signal lights.

If the relay is installed on the centrifuge twice (two bookmarks are made), then in order to “save” time and reduce the complexity of the tests, the sequence of relay tests on the axes during the second installation is reversed, i.e. during the first installation - X → Y → Z, during the second installation - Z → Y → X.

Technical result: the number of simultaneously tested relays is increased, switching of circuit wires during the test is excluded, the relay test technology is simplified, the parameters are measured and controlled and carried out simultaneously for all relays, the accuracy of evaluation and reliability of the control of relay parameters is increased, the total number of tests is reduced, the overall number is reduced test duration, reduced resource, energy and labor costs, provided the ability to almost instantly switch from measuring and monitoring one set of parameters at the same time in all the relay to measure and control a different set of parameters at the same time for all relays, it provided an opportunity to experience a choice of any set of relays.

Sources of information taken into account during the examination

1. Cherkasov Yu.N. Periodic testing of relay 8E123M. Second edition, revised and supplemented. Ed. P.V. Malysheva. - M .: FSUE NPP VNIIEM, 2010, 112 s, p. 92-98.

2. TU 16-647.037-86 "Electromagnetic relay 8E123M." Specifications EZHIA.647115.001 TU.

Claims (3)

1. A method of testing a relay in a centrifuge along three mutually perpendicular axes X, Y and Z with measuring and monitoring parameters for each relay, characterized in that more than two tested relays are installed on a centrifuge at the same time, measurements and monitoring of relay parameters are combined and carried out simultaneously for all wirelessly relays for switching one voltage increase of only one current source E ₁ supply reels simultaneously to all relay actuation voltage of the relay and one for reduction of the current source E ₁ to the voltage return all p le, the power source voltage E ₁ change the variable speed: fast outside the intervals of voltage as a possible trigger, and a possible return of the relay, and slowly within these slots, and by switching only one tumbler feed plus voltage source E ₁ simultaneously on the coil of relay instantly go from measuring and monitoring one set of parameters at the same time for all relays to measuring and monitoring another set of parameters at the same time for all relays, and by turning on a certain set of toggle switch The ditches measure and control the parameters for the choice of any relay assembly, while the measurements and parameters are monitored several times in the test interval, followed by the exclusion of obviously erroneous results, and the average value of the remaining results is taken as an estimate of the parameter value, and two measurements are initially performed, and the results are compared with the requirements of TU and with the results of earlier tests and establish the accuracy of the measurement results, if the result is erroneous, additional Our measurements to obtain a faultless result, and the parameter for evaluating the mean value of previously obtained and additional measurements. 2. The method according to claim 1, characterized in that for a large number of tested relays, two testers measure simultaneously, with one tester changing the voltage on the relay coils and taking a voltmeter reading, and the second tester records this reading and monitors the status of the signal lights. 3. The method according to claim 1, characterized in that in the case of installing the relay twice in a centrifuge, the sequence of relay tests on the axes during the second installation is reversed, i.e. at the first installation - X → Y → Z, at the second installation - Z → Y → X.