SU1379829A1 - Device for checking relay protection performance - Google Patents

Abstract

The invention relates to the field of electrical engineering and is intended to monitor the health of nodes, modules, and relay protection circuits embedded in active semiconductor elements, the signals on the same type of control points of different phases are equal to each other in the protection duty mode and are voltages of direct current, whose values can exist

Description

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penno ms and tg. from HarpyjKii h, ch1CP1ts; and my object. The same names; the temaites of different lif – ix phases; 1 11 and various replaceable modules of x-cassettes. The purpose of the invention is to verify the accuracy of geological accuracy of the control unit. The device consists of blocks 1,2,3 reconnaissance, whose inputs are input, the output through the adders A, 5,6 is connected to block 8 signal processing. The outputs of the signal processing unit 8 through the converter tribes 13, 14, 15 gtrisochny to logical block Invention (refers to electrical engineering and is designed to monitor the health of nodes, modules and protection relay targets made on active semiconductor elements, i.e. using transistors, amplifiers, logic circuits in microcircuit use, etc., the signals at the same type of control points of different phases of which, in the protection duty mode, are equal to each other and are DC voltages, which may significantly depend on the load of the object, the same type of elements of different phases of protection are located on different interchangeable modules of cassettes.

The aim of the invention is to increase the reliability and efficiency of control, and, as a result, the extension of the field of application to such interchangeable relay protection modules, which may not contain all three phase protection circuits simultaneously, may contain simultaneous points with constant current signals as constant , as well as time varying, and the dangers of control signals in different directions can be dangerous from the point of view of excessive and false alarms at different control points.

Fig. 1 shows the structural scheme of the proposed device for monitoring the operability of the relay for 1 (ity on (ig.2 - standard power

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21 and to the successively connected cyNfMaTopy 16, two-level comparator 17, decoder 18 and time delay element 19} Lement 19 Bhuiep-KH time gives a signal of protection failure, which also goes to the right unit 21. Improving the efficiency and reliability of the control panel is achieved by the introduction of three blocks 1,2,3 wiring, three adders 16, logical block 21, performed on the elements of the I-NC, and block 25 of the display. 3 il.

CX..1Y of the wiring unit, adder, test element, signal processing unit and converter element in FIG. 3 are the principal possible schemes of adder, two-level comparator, declider, logical unit, and dictation unit and decoupler unit.

The device (figure 1) contains blocks 1-3 of the wiring, designed to be combined in the process of mounting the device jumpers between the corresponding input and output terminals. The inputs of blocks 1-3 serve as inputs to the device.

The main inputs of adders 4-6, intended for summing signals with corresponding signs to them, are connected to one of the corresponding blocks, 1–3 wiring.

The outputs of the test element 7, designed to verify the health of the device, are connected to the additional inputs of adders 4-6.

The inputs of the signal processing unit 8, intended for proportional conversion of input signals, as well as the selection of the maximum input signal, are connected to the outputs of adders 4-6. The C51 signal processing unit 8 has outputs 9-11 that serve as outputs for signals proportional to the CI of the input signals block I, as well as output 12, ttred- and assigned to the signal proportional to the maximum of the input signals of block 8.

The main inputs of the converter elements 13-15 are connected to the corresponding outputs 9-11 of the block 8. The brake inputs of the converter elements 13-15 are connected to the output 12 of the block 8o. The converter elements 13-15 are intended to form single output signals in the case where the signals to the main inputs, the corresponding signals at the brake inputs are not less than the threshold

The inputs of the adder 16, designed to sum with the corresponding signs of the incoming signals, are connected to the outputs of the conversion elements 13-15,

The input of a two-level comparator 17 intended to form single signals at the outputs when the input signal exceeds the corresponding trigger thresholds is connected to the accumulator 16.

The inputs of the decoder 18 are connected to the outputs of a two-level comparator 17, the decoder 18 is designed to generate output signals depending on which way the signals on the control points of protection have changed.

The input of the element 19 is the time delay for the signal arriving at it for a time equal to, for example, 10–15 s connected to the main output of the decoder, and the output serves as the output signal of the protection malfunction,

The main inputs 20 of the logic unit 21, designed to detect the damaged replaceable monitored protection module and the signal for blocking the damaged protection phase, are connected to the outputs of the conversion elements 13-15, Additional inputs 22 and 23 of the logic unit 21 are connected to the additional outputs of the decoder 18 The main outputs 24 of the logic unit 21 serve as outputs for blocking the signal.

The inputs of the display unit 25, designed to indicate the damaged plug-in monitored protection module, are connected to the additional outputs 26 of the logic unit 21,

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Element 27 commuton1 D1 and is intended for commutators of the corresponding output signals about the mode of periodic health checks energized. Its blocking outputs 28 serve as outputs for blocking protection.

The inputs of the isolation unit 29, intended for the electrical isolation of the circuits of the monitored relay protection and the detection of signals to change the state of the active protection elements in the mode of periodic health checks, are connected to the main outputs 30 of the switching element 27. The outputs of block 29 serve as outputs of the signal to change the state of the active elements of the controlled state in the mode of periodic health checks.

The blocks 1-3 of the wiring (fig. 2) can be, for example, made in the form of a set of standard electrical switches on two positions or in the form of two rows of sockets on a printed circuit board, between which during the installation of the device corresponding jumpers are installed.

Adders 4-6 can, for example, be performed on a standard adder circuit based on amplifier 31 in a microcircuit design. Input resistors 32 connect the corresponding inputs of the adder to the non-inverting input of amplifier 31, resistors 33 to the corresponding inputs of the adder with inverting input of the amplifier 31, Resistors 34 and 35 are designed to adjust the operating point of the adder. Resistor 36 is designed to provide negative feedback. The chain of the resistor and the diode 37 is designed to work in the mode of checking the health of the proposed device.

The test element 7 may, for example, consist of three electrical buttons 38-40, one of the terminals of which is connected to the output of the power source, and the second serves as the output of the test element 7.

The signal processing unit 8 may, for example, consist of resistors 41-43 connecting the inputs of the unit 8 with its corresponding outputs 9-11, as well as resistors 44-46 connected in series with the diodes 47-49,

United cathodes of the diodes 47-49 are connected to the output 12 of the block 8.

Conversion elements 13-15 can, for example, be made on the basis of amplifiers 50 in microcircuit design. The outboard resistors 51 and 52 connect the corresponding inputs of amplifier 50 to the inputs of converter element 13. Resistors 53 and 54 are designed to adjust the operating point of amplifier 50, and 55 to provide negative feedback. The ballast resistor 56 together with the diode 57 is designed to shunt the negative polarity signal circuit at the output of the converter element 13. The capacitor 58 is designed to smooth the variable component of the signal

de converting element 13 in some modes.

The adder 16 can be configured similarly to adders 4-6, but in a simple way, the input resistors 59 connect the inverting input of the amplifier 60 to the inputs of the adder 16. Resistors 61 and 62 are designed for initial adjustment of the amplifier 60 to zero, resistor 63 - to provide negative feedback.

A two-level comparator 17 is made on the basis of transistor 64 and two miniature relays 65 and 66 with sealed contacts. The ballast resistor 67 connects the base of the transistor 64, designed to operate in the ammeter repeater mode, with the input of the comparator 17. The ballast resistors 68 and 69 are designed to limit the current in the winding circuits of the relay 65 and 66, the diode 70 - to prevent the transistor 64 from breaking through the electromotive force induced in the windings of relays 65 and 66 when the transistor 64 is closed.

The contacts of relays 65 and 66 are part of the decoder 18. Relay 66 has a switching contact, the middle of which is connected to the positive terminal of the power source. In series with the spreading part of the contact 66, the closing contact of the relay 65 is turned on, the second output of which is connected to a chain of series-connected ballast resistor 71 and LED 72. The latter is intended to signal the triggering

the state of the relay 65. The switch 73 is designed to connect the first additional output of the decoder 18 to the closing part of the switching contact 66. The chain of series-connected ballast resistor 74 and the LED 75 is used to signal the activated state of the relay 66. The diodes 76 and 77 are intended for electrical isolation of the circuits of the contacts of the relay 65 and the closing part of the contact of the relay 66.

Element 19 time delay is made according to the standard scheme, for example, an electronic time relay having a time delay of 10-15 seconds.

The composition of the logical block 21 includes logical elements AND IS NOT 78-95, designed to implement the corresponding logical function. The chains of resistors and diodes 96-97, 98-99, 100-101 and 102-103 are designed to match the corresponding inputs of logic block 21 to the decoder 1B.

The display unit 25 consists of three identical display elements 104-106, each of which contains a transistor 107 for operating in a key mode with a resistor 108 in the base circuit, and a chain of series-connected ballast resistor 109 and an LED 110 for signaling 11 1 and open the state of the transistor 107.

The switching element 27 can be made in the form of a standard electric multi-position switch connected to the power supply terminals, the output of which, when switched alternately, gives signals of positive or negative polarity from the power source. The element 27 may also include an LED that indicates the position of the CHECK of the combination element 27. If necessary, it is possible to introduce into the composition of element 27 also the standard buzzer of the position CHECK.

The isolation unit 29 contains ballast resistors 111.112 and diodes 113 and 114 intended for electrical isolation of the inputs of controlled protection connected to the outputs of the unit 29.

The device for monitoring the health of the relay protection works as follows.

To set up the device, one must first physically or theoretically carry out the necessary experiments with a controlled protection relay. In this case, test points are selected in each interchangeable module of monitored protection. The number of control points can vary from two to three to ten and more on each interchangeable module, if necessary. The control points are taken from the outputs of microcircuits, the leads of transistors, diodes, resistors, etc. Then, the consequences of various damages to the elements, the input n {them in the composition of the monitored protection, as well as the misalignment of variable resistors, changes in the parameters of electrolytic capacitors and other elements, are determined. At the same time, it is determined what changes in the signals at the test points lead to each of the damages under consideration and to what consequences it can lead to unnecessary, false positives or failures of relay protection. Those damages that may lead to unnecessary and false positives are taken into account separately, since in the event of such damage, the device must carry a signal to block the protection being monitored. You also exclude how the magnitude of the signal deviation at each control point represents a danger from the point of view of the exit of one or several protection parameters beyond the allowed 1e boundary.

According to the research results, the device is configured. If, for example

From the point of view of unnecessary false positives of the monitored protection, it is dangerous to change the signal at the test point in the region of more positive values, then the corresponding input of the 1 wiring unit with the output connected to one of the resistors 32 is connected with a jumper. the point of view of unnecessary and false positives is a change in the signal at the control point towards more negative values, then the corresponding input of block 1 is connected to the output connected to one of the resistors

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33. As a result, a dangerous change in the signal at the control point leads to a change in the signal at the output of the amplifier 31 in the direction of more positive values, and non-hazardous - in the direction of negative values of the signal. In those circuits in which already a small change in control signals represents a danger to protection, it is envisaged to install minor ratings of resistors 32 and 33, in the chains of those control points on which a relatively large change in signals does not yet represent a danger to protection, large Nominal values of resistors 32 and 33. Approximately we can assume that the greater the sensitivity of the device you need to get, the smaller the nominal value of the corresponding resistor 32,33 should be set. However, the minimum values of the ratings must be such that when a short-circuit jm6oro of one of the series-connected resistors 32.33 does not occur, the controlled protection does not act correctly.

By means of a potentiometer 35, the output potential of the amplifier 31 in the duty mode of the operative protection is set approximately in the middle of the possible range of variation of the positive signals. For example, at a supply voltage of 15 V, the output of the amplifier 31 can normally be set to 5-7 V in the protection duty mode. At the same time, it should be ensured that with real changes in the parameters of the primary network of the controlled protection, the potential at the output of the amplifier 31 does not go away in the region of negative values and does not reach the saturation potential of the amplifier. In the process of tuning, it should be ensured that, in the duty mode of the inherent protection, the potentials at the outputs of the amplifiers 31, corresponding to all three phases of protection, should be equal to each other in the whole range of their variation. The change in the mode of operation of the primary network is simulated by changing the signals supplied to the circuits of controlled protection from laboratory autotransformers, phase shifters, current sources and other devices included in the standard test sets for relay protection. In case if

A large number of signals of the same polarity is supplied to one of the inputs of amplifier 31. It may be reasonable to alleviate the main part of the signal by adding an additional resistor between the input of the amplifier and the corresponding power supply terminal. The magnitude of the additional resistors in this case is chosen so that the total value of the signals at each input lies within the allowable for amplitude-j d limits

The required sensitivity of the device is adjusted by means of a resistor 54, which provides the threshold for triggering the conversion element 20 element. If the signals arriving at the inputs of the conversion element 13 from outputs 9 and 12 are equal in magnitude, then they balance

13 operates (like the other conversion elements) in a mode close to the comparator mode. As long as the signals at its input are close to each other, the voltage at the output of amplifier 50 is negative. Diode 57 sets a negative signal output circuit and there is no voltage at the output of the converter element 13. If the signal arriving at the non-inverting input of amplifier 50 through resistor 52 exceeds the signal at the inverting input by an amount greater than the response threshold, then the output of amplifier 50 is a positive signal that comes to the output of converter element 13. Since the value resistor 55 in the negative feedback circuit is sufficient; the scale, then with a slight excess

signal at the non-inverting input, the amplifier 50 pushes; output and each other. Accurate to step 1 post-25 signal of the converter element

The receiving signals in the duty protection mode are provided by moving the slider of the resistor 51.

The setting order of the converter element 13 may be as follows. In the absence of signals at the input of the element 13 (for example, when each of the inputs is shorted to the common wire), the zero potential at the output of the amplifier 50 is set by resistor 54. Then, the inputs of the converter element 13 are unscrewed and the watchdog mode of the proper protection is simulated. In this case, if the voltage at the output of the amplifier 50 deviates from zero, it is again zeroed out, the slider of the resistor 51. After the input signals are balanced in this way, move the slider of the resistor 54 so that at the output of the amplifier 50 a negative polarity voltage appears. The magnitude of this voltage is set in such a way that the control device is triggered at those signal change values at the test points that are dangerous from the point of view of the function of the monitored protection. These values are determined by the described experiments with controlled protection. Due to the fact that the size of the resistor 55 is chosen sufficiently large (tens to hundreds of kilo), the conversion element

13 operates (like the other conversion elements) in a mode close to the comparator mode. As long as the signals at its input are close to each other, the voltage at the output of amplifier 50 is negative. Diode 57 sets a negative signal output circuit and there is no voltage at the output of the converter element 13. If the signal arriving at the non-inverting input of amplifier 50 through resistor 52 exceeds the signal at the inverting input by an amount greater than the response threshold, then the output of amplifier 50 is a positive signal that comes to the output of converter element 13. Since the value resistor 55 in the negative feedback circuit is sufficient; the scale, then with a slight excess

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13 does not depend further on the difference of the input signals if this difference continues to increase.

Adjusting the output signal of the adder 16 to zero in the absence of input signals is accomplished by moving the slider of a resistor 62. Resistors 68 and 69 are matched when adjusted so that when the input signal from the output of the conversion element arrives at one input of the adder 16, only relay 65 is activated, and relay 66 does not work . When signals are simultaneously received at the two inputs of the adder 16, both relays 65 and 66 must operate, since the emitter voltage of the transistor 64 operating in the emitter follower mode, increases approximately two times.

The overlay in the switch 73 closes in the direction of the contacts of the relay 66 if it is required to issue a signal to block the protective phase in the event of a malfunction that is dangerous from the point of view of excessive and false alarms. If the automatic protection blocking is not required, the switch 73 is turned off condition.

At this point, the adjustment of the device for monitoring the operability of the relay protection is completed and it can be entered.

but in working with controlled protection 3

The duty mode of serviceable protection. The signals at the same test points of the different phases of the monitored protection in the duty mode are the same DC voltage values. They can vary with magnitude, for example, when the SRI changes the load of the protected object, but with proper and properly configured protection, the approximate equality of signals at the same type of control points of different protection phases is maintained. As a result, the outputs of all three adders 4-6 have the same magnitude positive polarity signals. At the output 12 of the signal processing unit 8, a signal appears, the value of which is approximately equal to the signals at the outputs 9-11 of this unit. Thus, the signals at the inputs of all three transducer elements 13-15 are equal to each other and these elements do not work. The signals at their outputs are zero. There are no signals at the outputs of the time latch element 19 and at the inputs of the logic unit 21. The LEDs in the unit 18 are not illuminated.

There are no signals at the inputs of logic block 21, therefore, logical 1 appears at the outputs of the AND-NE 78-80 elements. At the left inputs of the elements IS-NE 81.83 and 85, the signal is O, the right receives 1 from the elements 80.79 and 78. At the outputs of the elements 81.83 and 85 appear 1, there are no signals (which can be considered the presence of a signal equal to O) at the outputs of the elements AND-NE 82,84 and 86, as a result of which the outputs of these elements appear 1. As a result, logical 1 is applied to all the inputs of the AND-NE 87-89 elements and at the output of these elements logical O. At the inputs of the AND-NOT elements 90-92 O are received (i.e. there is no signal), the outputs of these elements appear logical 1 which arrive at the inputs of the elements AND-NOT 93-95, causing at the outputs of the last elements logical O, i.e. no signal. Thus, the signals at the outputs of the logic unit 21 are missing.

The absence of signals at the inputs of the display unit 26 leads to the fact that the transistors 107 included in its structure 7982912

tav, closed and LEDs 110 Ffp rally vehicle.

The switching element 27 is in the OPERATION position, there are no signals at its outputs. There are no signals at the outputs of the block 29.

Some asymmetry of signals, which may appear when they are not Q-sewn, due to temperature changes, for example, for a power source or other similar reasons, does not trigger the transducer elements 13-15,

jr since it does not exceed the threshold of their triggering.

If one of the monitored replaceable protection modules is damaged, in which the signal at one or a few 20 control points of one protection phase changes significantly as compared with signals at control points of other phases, the signals at the outputs of the adders 4-6 are lost.

25 If, for example, in phase A of a monitored protection, damage occurs, dangerous from the point of view of idle or false alarms, the signal at the output of the adder 4 is more positive, Q than the signal at the outputs of the adders 5 and 6. At the output. 12, signal processing unit 8, a signal appears that is approximately equal to the signal at output 9 of this unit and exceeds the signals in codes 10 and 11. If the difference of the signals in

 Outputs 12 and 10, as well as Outputs 12 and 11, exceed the response threshold of the conversion element, then conversion elements 14 and 15 are triggered, and Element lJ remains in an inoperative state. At the two inputs of the adder 16, positive signals appear, and at the output of the adder 16, a signal proportional to the sum of the input signals and having a negative sign. At the emitter of transistor 64, a signal appears approximately equal to the signal at the output of adder 16, as a result of which relays 65 and 66 are triggered. Relay 66 switches

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an LED 75, which begins to light, signals the controlled protection of a dangerous from the point of view of excessive or false triggering of the damage protection. Through the switch 73, the signal enters the input 23 of the logic unit 21. At the same time, the signal enters the di

o 96 and through diode 76 to the input of time lag element 19. Since the converting elements 14 and 15 are in the activated state, the signal also goes to the inputs of the AND-NE elements 79 and 80, causing logical O on their outputs. At the same time, 1 is fed to one of the inputs of the AND-NE elements 82 and 84, it does not cause a change in potential at their output, since there is still no signal at the second inputs (this is equivalent to the presence of a signal equal to logical O). The signals on the OUTPUTS of the NES 81 and 83 elements on the inputs where there was 1 change, O appears, and vice versa, but the potential of the outputs of these elements remains unchanged (it is equal to 1), since the signal is still 1 input , on the other O. Since the signals at both inputs of element 85 become 1 (the left input receives 1 from the decoder, 1 continues from the IS 78 element to the right input), the signal at its output becomes 0, the signals at the inputs and the outlets of elements 86-88 remain the same as those on duty for proper protection. Since the signal at the left input of element 89 became equal to zero, at its

1, as a result

output appears

which is the signal at the input of the display unit 25. The transistor in the display element 104 opens and the LED turns on, indicating a fault in phase A of the monitored protection. Elements 90, 91, 93 and 94 do not change their state. -.

Initially, the AND-NOT 92.95 elements do not change their state, since 1 enters the two inputs of the element 92, and the third continues to remain O. After the activation of the time delay element 19, a signal appears at its output, which illuminates on the control panel board PROBLEM PROTECTION. At the same time, the signal from the output of element 19 enters the third input of the element IS-HE 92, as a result of which O appears at the output of this element, and at the output of element 95 - 1, i.e. a signal is issued to block the defective protection phase A. Simultaneously, the control panel lights up

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The LOCKED PROTECTION board. When these signals appear on the control panel, a crew of service personnel is sent to the place where the protection is installed and the LED module entering element 104 detects a damaged module. Each monitored module has its own display element included in the display unit 26, therefore, revealing a damaged protection module does not cause difficulties. After a damaged module is detected, it is replaced with a working one.

If during phase A of the monitored protection damage occurs, which is not dangerous from the point of view of excessive and false alarms, the signal at the output of the adder 4 became less positive than the signal at the outputs of the adders 5 and 6. At the output 12 of the signal processing unit 8, the signal continues to remain equal to the signals at the outputs of 5 blocks 5 and 6. Signals at the outputs of the 10 and 11 blocks. 8 are approximately equal to the signal at output 12, and the signal at output 9 of block 8 decreases, because the signal decreases at the code of adder 4. If the difference of signals at outputs 12 and 9 exceeds the response threshold of the converter element 13, it works, and elements 14 and 15 remain in an unworked state. A signal appears at one input of the adder 16, as a result of which, in the same way as described, the relay .65, which is part of the two-input comparator 17, is triggered, and the relay 66 remains in an idle state. The LED 72 starts to turn on, signaling in a monitored protection of a fault that is not dangerous from the point of view of excessive or false action. Element 19 time delay signal appears, which after 10-15 s enters the output of element 19 and displays on the control panel of the board PROTECTION FAILURE.

Since the transducer element 13 triggered, 1 appears at the input of element 78, and its output is O. Since O appears at both inputs of element 85, there is l at the output. At the same time, one input of element 86 from output 13 enters 1, and the other input of element 86 1 enters from the contacts of relay 65 through diode 102. At the output of the element

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151379829

86 we have O. Since the inputs of element 89 receive O,

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the LED in the element 104 of the display unit 25, signaling phase A damage of the monitored protection. The signal to block the protection is not given, since O is inserted at one of the inputs of each of the elements 90-92, since the input 23 of the logical unit 21 signals the switch 73, which is part of the decoder 18, is missing.

In case of damage in other phases of protection, the device acts in the same way. In case of any damage that the device feels, on the control panel the PROTECTION FAILURE is displayed, the LEDs in the block 25 signalize which particular protection module is damaged. A signal to block the damaged phase of protection you

is given only if the potential for its disabling effect

No damage is dangerous in terms of excessive or false protection operation. In the alarm mode (e.g., at near asymmetrical short circuits), for example, the Q on the test points can significantly differ from each other during the time that the alarm mode exists. In this case, the conversion elements and relays that make up the two-level comparator may work, but the signal at the output of time delay element 19 does not have time, since the element 19 time delay with a margin longer than this mode.

To check the health of the device to monitor the health of the relay protection, alternately press the buttons 38-40 in the verification element 7 When you press button 38, the input of the adder 4 receives an additional signal simulating a dangerous, in terms of excessive or false operation of the monitored protection, damage in the phase A removable module. At the same time, the LED corresponding to the damaged module should light up in the display unit 25, and 10–15 seconds later will be displayed on the control panel

protected object) at the time of the inspection. In the next step, a signal is sent through the resistor 111 and the diodes 113 of the output unit to the active elements of the monitored protection, changing their mode of operation, i.e. leading to a change in voltage at control points. Since the same signal arrives at once to the three phases of protection, the voltages at the test points of the serviceable and properly configured protection should remain approximately equal to each other and the proposed device for the controller should not operate. In the next step, the switch included in element 27 can receive signals of the opposite polarity at the inputs of the same or other active elements of the monitored protection, and the test is repeated, and so on. Upon completion of the described test, the element 27 returns to its initial state and the monitored protection starts working normally again. Light-signaling devices, which may be part of element 27, fix the attention of personnel that element 27 is in CHECK mode and protection is blocked.

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SECURITY PROTECTION and FOR- PROTECTION BOARD After element 27 returns to its outcome, DIHTA is LOCKED. Similarly, behaves a working device when pressing buttons 39 or 40, only in

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in these cases, damage is simulated, respectively, in phases B and C of the controlled protection. If during the verification process it becomes clear that the single-system device for monitoring the protection of the relay protection is defective, it should be replaced with an operational one or the malfunction should be rectified.

If it becomes necessary to conduct an additional check of the operability of the monitored protection in order to increase the reliability of the monitoring, the switching element 27 can be used. In the initial, normal state of the element 27, the signals at its outputs are absent and it does not affect the operation of the circuit. When translating the multi-position switch 0l of the element 27, into the CHECK mode, in the first step of the switch operation, at its blocking output, a signal appears that blocks the protection phase being checked (for

protected object) at the time of the inspection. In the next step, a signal is transmitted through the resistor 111 and the diodes 113 of the isolation block to the active elements of the monitored protection, which changes their mode of operation, i.e. leading to a change in voltage at control points. Since the same signal arrives at once to the three phases of protection, the voltages at the control points of the serviceable and correctly configured protection should remain approximately equal to each other and the proposed device for the controller should not operate. In the next step, the switch of the element 27, the inputs of the same or other active elements of the monitored protection can receive signals of the opposite polarity and the test is repeated, and so on. Upon completion of the test described, element 27 returns to its original state and the protection is monitored again. starts to work normally. Light-signaling devices, which may be part of element 27, fix the attention of personnel that element 27 is in CHECK mode and protection is blocked.

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After element 27 returns to its original state, the alarm stops. If, during the test, the proposed single-system device for monitoring the protection of the relay protection is triggered and generates a signal of protection failure, the damaged plug-in module is detected by the LED in the display unit 25 and is replaced with a working one.

Claims (1)

Claim 0 A device for monitoring the protection of the relay protection, the signals at the same type of control points of different phases of which are in the duty mode of the proper protection equal to each other DC voltage, containing three converter elements, an adder, a two-level comparator, an element of the test-20 main inputs of the logic unit jays, a time delay element, the output of which serves as an output signal of a protection fault, a decoder, a switching element and an isolation unit, the inputs of the converter elements being soy The dinenes with the outputs of the resistive signal processing unit, the inputs of the adder are connected to the outputs of the converter elements, and the output of the adder through a two-level comparator is connected to the inputs of the decryptor, the main output of which is connected to the input of the element. time blocking output switch outputs serve as outputs of the blocking protection, the main outputs of the switching element are connected to the inputs of the isolation unit, the outputs of which serve as outputs of the signal for changing the state of the active elements of the monitored protection, characterized in that, in order to increase the reliability and effectiveness of the control, three wiring unit, three adders, a logical unit made on the elements of NAND, and a display unit, the inputs of the wiring units serve as inputs to the device, the outputs of the wiring units are connected to the main inputs of the co corresponding adders whose outputs are connected to the inputs of the signal processing unit, dinene with outputs of converter elements, additional inputs of the logic unit are connected to additional outputs of the decoder, auxiliary input of the logic unit is connected to the outputs of the time delay element, the main outputs of the logic unit serve as outputs for blocking protection, additional outputs of the logic unit are connected to the inputs of the display unit, and outputs The verification element is connected to the additional inputs of the entered adders. L Coitro / 1 point phase A f3 ss “В | one" - - Kf / f J7 V H n 1 / f adder f6 FIG. 2 l w to CijMMamopafi 5.6.  From supmato-g rob b, b f (npeo5flajo6a telts elements / 4f 13 / J n From other fS On the signal of f Bucnpafr- Vc tfl // and blonarie aschi / 776 / K bhodap KOHmpoJiupf / eMOfi lashchita ig.Z