SU1377955A1 - Arrangement for emergency-duty protection of three-phase induction motor - Google Patents

Abstract

The invention relates to electrical engineering. The aim of the invention is. Expansion of functionality by providing protection against phase failure and braked rotor mode. When a phase is broken, for example, A, transistor switch 39 closes and a logic level appears at its output. The outputs of the keys 37 and 38 still provide a logical zero. In this connection, at the outputs of the elements OR 40 and ZI-NO 41 there are logical units, at the output of the element 2I-NO 42 - a logical zero, and at the output of the element 43 - a logical

Description

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with

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unit. With a certain amount of time due to element 44, a logical zero appears at the S input of the CK Trigger 45. The trigger 45 is switched, the indicator 46 is illuminated, the level of the logical unit arrives at the OR element of the executive body. The output relay 23 turns on and disconnects the motor from the network. 5 3.p. f-ly, 2 ill.

Claims (6)

one The invention relates to electrical engineering, in particular, to devices for protecting electric motors from emergency operation. The purpose of the invention is the expansion of functional capabilities by providing protection against operation on two phases and the mode of a braked rotor. FIG. 1 is a schematic diagram of the protection device; on. FIG. 2 - diagrams of individual protection device blocks: overload protection unit with indication and actuation memory, two-phase protection unit with indication and actuation memory, protection unit from operation in the braked rotor mode with indication and actuation memory, block food The device consists of a compact current transformer 1 (Fig. 1), loaded on a resistor 2, an AC amplifier 3 on the basis of an operational amplifier, the gain factor of which is changed by a resistor 4, a rectifying unit 5 of the node (controlling the degree of load, including comparators 7–9, amplifiers 10–12 loaded on indicators 13–15. Elements 7, 10 and 13 form a load control unit above the nomings, elements 8, T1 and 14 are a load control unit, elements 8, 11 and 14 are a load control unit below nominal. Moreover, the non-inverting input of the comparator 9 is connected to the engine of potentiometer 16 connected between the non-inverting input of comparator 8 and the common point of the circuit, and the position of the engine of potentiometer 16 is graduated as a percentage of the nominal current.The device also contains an optothyristor 17, an overload protection unit with indication and trigger memory 18, five ten 15 20 25 thirty 35 40 45 a two-phase protection unit with indication and actuation memory 19, a braked rotor protection unit with indication and actuation memory 20, an element OR 21 of the actuator 22 with an output relay 23. The overload unit 18 (Fig. 2) contains a voltage converter - resistance 24, which is turned on at the input of the unit. Transformations-. The receiver is made on the basis of a resistor optocoupler 25. The block also contains an integration element 26 with integrating; variable capacitor 27: resistors 28 and 29, threshold element 30, RS flip-flop 31, and display element 32. The motor protection unit on two phases 19 (Fig. 2) contains small fast-setting current transformers 33 and 34, constant voltage limiters 35 and 36, transistor switches 37-39, elements OR 40, ZI-HE 41, 2I - NO 42, inverter 43, time delay element 44, RS flip-flop 45, trip indication element 46.. The motor protection unit in the mode of the braked rotor 20 (Fig. 2) contains a threshold element with a response delay 47, an inverter 48, a one-shot 49, the signal duration of which is controlled by the chain 50, the IMPLICATOR 51, the trigger 52, the indication indication 53 . The power supply unit 54 of the protection device contains a transformer 55, an intermediate relay 56 with a switching contact 57. The rectifying and stabilizing power circuits are not shown in the drawing. The protection device also contains a switch 58 operating mode (Fig, 1) The security device works as follows. Before switching on, the device is set to the rated current of the protected motor. To do this, switch 58 is set to the setting position, winding the winding on the core of the current transformer 1 (current transformers 1, 33 and 34 are toroidal and do not have their primary winding). An alternating current is passed through it to such an extent that the MDS is equal to the MDS winding, which is wound onto the core when the protection device is commissioned, if the rated current of the protected motor flows through it, for example, when the device is commissioned, have 1 turn of the primary winding. Then the MDS working nominal is equal to 110 Amp. When setting up, the protection devices exhaust, for example, 55 turns and pass a current of 2 A, Then the AMS setting will be 110 Ampervits. Under these conditions, the gain of the amplifier 3 is changed and the indicator of the 14th channel of the nominal load is lit. If the slider of the potentiometer 16 is installed in the upper position (FIG. 1), the indicator 15 will light up simultaneously. On this, the device setting is completed. The indicator 13 is set to trigger and adjust other units when the device is manufactured. These adjustments are made relative to the rated current of any protected motor, since the output of the rectifying unit 5 is set to the same voltage level for all the rated currents of the protected electric motors. Setting the threshold of protection, made when setting up the device, can be performed during operation. At the same time, with. Using the resistor 4 (Fig. 1), you can set the threshold of the device relative to any non-rated current. When commissioning the protection device, the primary windings of current transformers 1, 33 and 34 are wound with a wire of the supplying electric motor. 5 0 5 o Q five five 0 The network is connected, and transformer 1 is strictly according to the MDS settings, and transformers 33 and 34 are approximately the same. J number of turns, since these transformers are fast-sated, and for them it is enough to provide some minimum value of the MDS, Suppose the device is prepared for protection, t, e. a power supply unit is connected, current transformers are wound, and switch 58 is set in the Protected on position. If the electric motor has a current lower than the nominal one, then the indicators 13-15 are not light. You can set the degree of load of the motor if you move the slider of the potentiometer 16 DOWN (FIG. 1), by moving it to get the indicator 15 to work. This position on the scale of the potentiometer 16 counts the percentage of the load of the electric motors in relation to the nominal current. Suppose the motor is operating at a current that exceeds the nomi-. nalny. In this case, the light of the TC indicators 13-15 is triggered, with a frequency of 50 Hz, demister 17 (FIG. 1). At the same time, the current at the input of the optoresistor 25 (Fig. 2) increases, causing its resistance to decrease. The integration capacitor 27 is charged with a half-wave rectified current. As the motor current increases, the illumination of the optocoupler resistor 25 increases, its resistance decreases, and the charging current of the integrating capacitor 27 increases. When the voltage across the capacitor 27 reaches the threshold of the element 30, the voltage is applied to the S-input of the trigger 31, which causes a logical unit to appear at the forward output, which through the elements 21 and 22 (Fig. 1) acts on the output relay 23, The motor is disconnected from the network. At the same time, the logical zero appears at the inverse output of the trigger 31 and the display element 32 is lit. Disconnecting the motor from the mains or reducing the load to the nominal value causes the optothyristor 17 to close and the integrating capacitor 27 to gradually discharge. key 58 will not be set to Reset. Here, a logical zero is applied to the R-input of the trigger 31 and the trigger 31 returns to its original position. Suppose there is a break in the phase A of the power supply network. In this case, the transistor switch 39 is closed, at the output of its logical unit. The outputs of the keys 37 and 38 still provide a logical -; zero. In this connection, the output of the elements OR 40 and ZI-NO 41 contains logical units, the output of the element 2I-NO 42 is a logical zero, and the output of the element 43 is a logical one. With some time delay, the elements 44 at the S-input of the RS flip-flop 45 appear a logical zero. The trigger 45 is switched, the trigger indicator 46 is lit, and the voltage of a logical unit is applied to element 21 (Fig. 1). Relay 23 turns on and disconnects the motor from the network. To reset the protection device, the switch 58 briefly goes to the Reset position. If the phase B is broken, then the transistor switch 38 is closed, and if the phase C is broken, the key 37 is closed and the protection unit 19 operates in the same way as described. However, when phase C or B is lost, the coil of energizing the relay 56 of power supply unit 54 (Fig. 2) loses power, which is why the primary winding from the input voltage transformer 5 connected to the phase A of the power supply electr, the potentiometer 16 makes it possible to determine motor network, thereby ensuring reliable power supply protection circuit with display and trigger memory. When the motor starts, the voltage at the output of the rectifying unit 5 increases to the value at which the threshold element 47 is triggered. With some delay in the output of element 47, a logical zero appears, and at the output of element 48 there is a logical one that goes to the second input of the logic element IMPLICATOR 51. At the same time, the one-shot 49 receives a logical unit from the ZI-NO element 41 of the block 19. The one-way orbit turns on and produces a signal of a logical unit of a certain duration defined by the parameters his R-C-cent45 50 55 degree of load of electric motors, of different powers relative to their nominal values during operation. The use of a voltage-to-resistance converter with an adjustable amplifier on a bazer resistor optocoupler, the resistor of which is the main charging resistor of the integrating circuit RC and variable resistors for the charge-discharge circuit, without a contact switch based on an optotizer that is functionally connected to The channel of overload of the indication module at the corners allows the most close both to bake the required time-current protection characteristic in a wide power range. 0 five 0 five 0 35 pi 50. The duration of this signal is chosen slightly longer than the motor starting time in normal mode. Therefore, if a normal motor start occurs within a time shorter than the duration of the one-shot signal, then the output of the IMPLICATOR element 51 will be a logical unit and block 20 will not operate. If the duration. if the start is greater than the established one or the working machine is jammed, then the input X of element 51 will be a logical zero, and the input X j will be an element. This 51 is a logical unit, causing a logical zero to appear at its output, an RS-flip-flop 52, a trip indicator 53, and an element 21 and 22 (Fig. 1) is energized, causing the relay 23 to trip and the motor off ; network. Thus, supplying the device with an AC amplifier ci with adjustable gain and a motor load control node 6 allows it to be tuned to a different (nominal) current and to use a device for protecting electric motors of different power. At the same time, current transformers 1, 33, 34, amplifier 4, display unit 6, protection blocks 18-20 and other elements of the device remain the same for all protected motors, regardless of their rated power. Turning on comparator 9 through potentiometer 16 allows you to determine the degree of load of electric motors, of different powers relative to their nominal values during operation. I Using a voltage-resistance converter with an adjustable amplifier on a bazer resistor optocoupler, the resistor being the main charging resistor of the integrating circuit RC and variable resistors for the charge-discharge circuit, a contactless switch based on an optothyristor that is functionally connected to the overload channel The load indication unit allows you to most closely provide the required time-current protection characteristic in a wide power range. 7137 The use of two additional fast latching current transformers with two transistor switches, and -Also a third transistor switch functionally connected to the rectifier unit via a switch, as well as a logic unit, allowed the Motor to be protected from work on two phases in a wide range of contact switch fg, and the second in the input power. The use of the threshold element functionally connected with the spinning unit, the one-shot functionally connected with the protection unit | 5 against two-phase operation, and the logic circuit allowed protection against operation in the mode of braked rotor in a wide power range. The use of RS flip-flops and display elements, as well as an intermediate relay with a switching contact in the power supply unit, ensured a reliable response memory when any phase of the power supply motor 25 was disconnected. The same protection units are connected to the common point of the circuit via the disconnecting contact of the same switch, and the output of the above protection units is connected via the OR element to the input of the actuator. 2. The device according to claim 1, characterized in that the node controlling the degree of load is executed in the form of three blocks: the load control block is higher than the nominal, the output of which is the output of the control block of the control block of the nominal load, and the load control block is lower than the nominal, each block consists of a series-connected comparator, a power amplifier, and an indicator; the inverting inputs of the comparators are combined and are the input of the degree of load control unit, while the non-inverting input of the comparator of the control unit Booting lower face attached to a movable contact of potentiometer invention prograduiroFormula 1. Device for protection of three-phase asynchronous electric motor from emergency mode, containing phase current transformers, with the transformer of the first phase, shunted by a load resistor, produced in percentage of nominal 45 The power supply unit, to which the overload protection unit is functionally connected, the power amplifier with the executive relay, the AC power supply, is designed so that, in order to extend the functionality by providing phase failure protection and the mode of the braked rotor, it is additionally equipped with an AC amplifier with an adjustable gain factor by the control unit of the degree of load, a switch with closing and razmikayapshm contacts, an OR element, an optothyristor, an oy on two phases and a protection unit from the mode of a stalled rotor, while the AC amplifier is connected between the secondary winding of the first phase current transformer and the rectifier unit, the input of the load degree control unit is connected to the output of the rectifier unit, and its output is , 50 55 current, and the input of the potentiometer is connected to the wind of the non-inverting input of the comparator of the control unit of the nominal load and the common point of the circuit. j 3. The device according to claim 1, characterized in that the power supply unit against overloads is provided with an RS-trigger, an indication element, while the voltage converter is a resistance with an adjustable gain factor based on a resistor | the input of the first unit, the optocoupler photoresistor is in series with the integrating capacitor, the output of the threshold element is connected to the S-input of the RS flip-flop whose inverse output is connected to the indication element, the direct output is connected to the output of the unit, and the R-input of the RS flip-flop is connected to second input block and, the input of the threshold element is connected to the output of the resistor optocoupler divider. eight the thyristor, the anode of which is connected to the AC power supply, and the cathode to the enabling input of the overload protection unit, the first inputs of the overload protection units, operation on two phases and the mode of the braked rotor are connected to the output of the rectifier unit through the closing contact switch, and the second input The same protection units are connected to the common point of the circuit via the disconnecting contact of the same switch, and the output of the above protection units is connected via the OR element to the input of the actuator. 2. The device according to claim 1, characterized in that the node controlling the degree of load is executed in the form of three blocks: the load control block is higher than the nominal, the output of which is the output of the control block of the control block of the nominal load, and the load control block is lower than the nominal, each block consists of a series-connected comparator, a power amplifier, and an indicator; the inverting inputs of the comparators are combined and are the input of the degree of load control unit, while the non-inverting input of the comparator of the control unit Booting lower face attached to a movable contact of the potentiometer, prograduiro45 , 50 55 current, and the input of the potentiometer is connected to the wind of the non-inverting input of the comparator of the control unit of the nominal load and the common point of the circuit. j 3. The device according to claim 1, characterized in that the power supply unit against overloads is provided with an RS-trigger, an indication element, while the voltage converter is a resistance with an adjustable gain factor based on a resistor | the first block, the optocoupler photoresistor is in series with the integrating capacitor, the output of the threshold element is connected to the S-input of the RS flip-flop whose inverse output is connected to the indication element, the direct output is connected to the output of the block, and the R-input of the RS flip-flop is connected to the second input block and, the input of the threshold element is connected to the output of the resistor optocoupler divider. 4. The device according to claim 1, about tl and - so that the block of protection against operation in two phases is equipped with  An RS trigger and a display element, the output of the amplifier of the two-phase protection unit is connected to the q S-input of the trigger, whose R-vhrd is the second input of the protection unit, the inverse output of the RS flip-flop is connected to the display element, and the direct output is the output of the protection unit. 5. The device according to claim 1, characterized in that the protection block against operation in the mode of the braked rotor is provided with a threshold element with a time delay, an inverter, a single vibrator and an IMPLICATOR element, an RS trigger and an indication element, the threshold element is installed at the input of the unit, its output through the inverter is connected to the second input of the IMPLICATOR element, the direct input of the single vibrator is connected to the output of the elec ZI-NO cop of the protection unit from working on two phases, and the output is connected to the first input of the IMPLICATOR element, the output of which is connected to the S-input of the RS flip-flop, the R-input of which is connected to the common point of the circuit through the break contact of the switch the stroke is connected to the display element, direct output is the output of the protection unit. 6. The device according to claim 1, about tl and that the power supply unit is provided with: an intermediate relay with a switching contact, one end of the primary winding of the voltage transformer of the power supply unit is grounded, the second is connected through the disconnecting contact of the relay to the first phase of the mains, and through the closing contact - to the second phase of the mains, and the relay coil is connected to the second and third phase of the mains. 51 -