RU2015596C1 - Electric motor protection device - Google Patents

Abstract

FIELD: electric technique. SUBSTANCE: device has an actuator, thyristor, pulse generator on the basis of a unijunction transistor, comparator, measuring bridge with a temperature sensor at its input connected through a diode and resistor to one phase of the mains. The unijunction transistor is connected to the output of the comparator and its emitter is connected to RC-circuit connected to a second capacitor connected through a second diode to a another phase of the mains to a third phase of which through the thyristor the actuator is connected so as to simplify circuit and enhance operating reliability. Furthermore, the device provides protection of the electric motor from overheating, incomplete-phase operating mode, breaks and short circuiting in the temperature sensor circuit. EFFECT: widened operating capabilities, simplified construction and enhanced reliability. 4 cl, 1 dwg

Description

 The invention relates to electrical engineering and is intended to protect three-phase electric motors from emergency operation.

 A device for protecting an electric motor is known, comprising control buttons connected to the first phase of the network and connected in series, an actuator and a thyristor, the control electrode of which is connected to the first output of the first resistor, a single-junction transistor, the emitter of which is connected to the midpoint of the RC circuit, the resistor of which is through the first the diode is connected to the second phase of the network, the second diode and the first capacitor are connected in series, the second capacitor and the second resistor, the third capacitor and the third resistor after They are included in the second phase of the network, the second terminals of the third, first and fourth resistors, the first plates of the first and fourth capacitors, the thyristor cathode and the first base of the single-junction transistor are connected to the neutral wire, the second base of which is connected to the second plate of the first capacitor and the cathode of the second diode, the anode the latter is connected to a common connection point of the second capacitor and the second resistor included in the third phase [1].

 The known device is characterized by limited functionality: it does not provide thermal protection for the electric motor, for example, during overloads.

 The purpose of the invention is to simplify the circuit and increase reliability in operation.

 To do this, in a device for protecting an electric motor containing an actuator, a thyristor, a single-junction transistor with an RC circuit at the input, a comparator, the inputs of which are connected to the outputs of the temperature-sensitive bridge, one of the arms of which includes a temperature sensor, one of the inputs of the comparator through a diode connected in series and the resistor is connected to the output of the comparator, the comparator and the measuring bridge are connected to the first capacitor, one lining of which is connected to the cathode of the thyristor, one pin of the comparator, one pin the house of the thermosensitive bridge connected to the first output of the temperature sensor and the terminal for connecting the neutral wire of the network, the second lining of the first capacitor through the first resistance connected in series and the diode is connected to the first terminal for connecting one of the network phases, and directly to the other input of the measuring bridge and the other output of the comparator, three diodes, and a second capacitor, a single-junction transistor is connected to the output of the comparator, and its emitter is connected to an RC circuit connected to the second capacitor, one and the lining of which through the second diode is connected to the second terminal connected to another phase of the network, and the other lining of which is connected to the cathode of the thyristor, the RC capacitor is connected through the second diode to the control electrode of the thyristor, and through the third diode to the second output of the temperature sensor, and the thyristor anode through the executive unit - with a third terminal for connecting the third phase of the network.

 The drawing shows a diagram of the device.

 The device contains an actuating element 1, for example, a magnetic starter, contacts controlling the operation of the protected electric motor, terminals 2-5 for connecting three phases and a neutral wire of the network. The winding 1 of the magnetic starter is connected to the terminals 4-5 of the network through a thyristor 6, made symmetrical. To another terminal 2 through a diode 7 and a resistance 8, for example a resistor, a filter capacitor 9 is connected to which a measuring bridge is connected, composed by resistors 10-13 and a temperature sensor 14; a comparator 15, forming with a diode 16, a resistor 17 and a capacitor 18 a storage element. A single-junction transistor 19 is connected to the output of the operational amplifier 15, the emitter of which is connected to the cathode of the thyristor 6 through the capacitor 20 of the RS circuit and resistor 21, and through the resistor 22 of the RC circuit to resistors 23, 24 forming a voltage divider connected to the filter capacitor 25 This capacitor is connected to terminal 3 of the network via diode 26.

 The capacitor 20 is connected through the diode 27 to the temperature sensor 14, and through the diode 28 to the control electrode of the thyristor 6. A capacitor 30 is connected through the resistor 29 in parallel to the executive device 1. The temperature sensor 14 can be made in the form of a resistor, thermistor, etc., and is installed in stator windings of an electric motor.

 The device operates as follows. When applying a three-phase voltage to all three phases - terminals 2-4, when the temperature of the motor and the resistor 14 are below the limit value, the filter capacitor 9 is charged through the diode 7 and resistor 8 under the influence of voltage at terminals 2, 5 until the voltage drops across the comparator 15 and the measurement pattern 10-13. When the posistor 14 is not overheated, its resistance is small, the voltage drop on the shoulder of the thermosensitive bridge 13 is higher than on the resistor 11 and the resistor 14, so the voltage at the output of the comparator and the bases of the OPT 19 is approximately equal to the voltage across the capacitor 9. This diode 16 is blocked by this voltage. At the same time, a capacitor 25 is charged through a diode 26, and a capacitor 20 is periodically charged through a resistor 22 with a voltage across the resistor 24.

 When the capacitor 20 is charged up to the OPT 19 unlock threshold, the OPT is unlocked by passing the discharge current of the capacitor 20 through the resistor 21. Under the influence of voltage pulses emitted by the resistor 21, the triac 6 is unlocked and the magnetic starter 1 is turned on, connecting the electric motor to the three-phase network by power contacts. The frequency of pulses generated by the OPT is more than an order of magnitude higher than the frequency of the network. Due to this, the triac 6 is unlocked at the beginning of each half-cycle of the mains voltage, and almost all the mains voltage is allocated to the winding 1 of the magnetic starter. To reliably turn on the inductive load using the triac 6, the input of which receives relatively short current pulses, the RC circuit 29, 30 is used.

 When the temperature of the electric motor increases above the emergency value, for example, with its current overload, the resistance of the posistor 14 and the voltage drop across it will increase sharply. When the voltage drop across the posistor 14 and resistor 11 exceeds the voltage drop across the resistor 13, the operational amplifier switches and the voltage at its output and the bases of the OPT 19 decreases to a logic zero voltage. The generator on the OPT 19 stops, and the triac 6 and magnetic starter 1 are turned off. Through the diode 16 and the resistor 17 is shunted by the comparator resistor 13.

 Therefore, at the non-inverting input of the comparator there will be a higher potential even after the motor cools down and the resistance of the temperature sensor decreases. In this regard, the comparator will be in a state when its output will be zero potential, and the magnetic starter will be turned off. The capacitor 18 eliminates the bypass of the non-inverting input of the comparator through the diode 16 when applying a supply voltage to the circuit, when its output can be a logical zero.

 To turn on the electric motor in operation after cooling of the temperature sensor 14, it is necessary to first temporarily de-energize the circuit for discharging the capacitor 9 and removing the potential from the inverting input of the comparator 15. After applying voltage to the network terminals 2-5, the generator again starts to generate pulses on the OPT 19, triac 6 and magnetic starter 1. If the electric motor has not cooled and the resistance of the posistor 14 is large, then before the OPT 19 starts, the comparator 15 will switch, preventing the generation of pulses and switching on triac 6 and magnetic starter 1, i.e. turning on the electric motor is possible only when the temperature sensor cools. When a break in the circuit of the temperature sensor 14, the comparator 15 capsizes, the generator stops and the triac is locked, disconnecting the magnetic starter 1 and the motor. In the case of short-circuit in the circuit of the line connecting the posistor 14 to the circuit, the control circuit of the triac 6 is shunted through the diode 27. The triac is locked, turning off the electric motor.

 The device also provides instantaneous, without preliminary overheating of the electric motor, its shutdown when any of the phases 2-4 break. When phase 2 breaks, the power of the comparator 15 and the generator OPT 19 is lost. When terminal 3 is de-energized, the power to the RC circuit 22, 20 of the generator is stopped, which will cause the triac 6 to lock and magnetic starter 1 to turn off. If there is no voltage in phase 4, the coil of magnetic starter 1 is de-energized and it will turn off.

 The proposed device has wide functional capabilities, providing protection of the electric motor both from overheating and in-phase operation, breakage and short circuit in the temperature sensor circuit, it is characterized by high reliability, stability and accuracy of operation, low power consumption, insignificant dimensions and weight, it does not have intermediate relays and their contacts, which will allow it to be widely used for monitoring, control and protection of AC electric motors of various industries and agriculture.

Claims (4)

 1. DEVICE FOR PROTECTING THE MOTOR, containing leads for connecting the actuator, the first of which is connected to the anode of the triac, the cathode of which is connected to the first terminal connected to the zero terminal of the network, and the common terminals of the first and second sources of rectified voltage, the input terminals of the first and second rectified voltage sources are used to connect to the first and second phases of the network, the first output of the first resistor is connected to the positive output terminal of the first rectified voltage source, in the second terminal of which is connected to the first terminal of the first capacitor and the input terminal of the voltage threshold element, the second terminal of the first capacitor is connected to the first terminal of the second resistor, the second terminal of which and the first terminal of the voltage threshold element are connected to the cathode of the triac, the second capacitor and third resistors, characterized in that the first and second diodes are introduced into it, a heat-sensitive bridge with a thermistor at the input and a threshold element with a memory, the power leads of which are thermally sensitive of the second bridge are connected to the output and the common terminal of the second source of rectified voltage, to the common terminal of which is connected the first terminal of the thermistor, the second terminal of which is connected through the first diode to the first terminal of the second resistor, which is connected through the second diode to the control electrode of the triac, the outputs of the thermosensitive bridge are connected to the inputs of the threshold element with memory, the output of which is connected to the second output terminal of the threshold voltage element, the second capacitor through the third resistor is connected to conclusions for connecting the executive apparatus connected to the third phase of the network.  2. The device according to p. 1, characterized in that the threshold voltage element is made in the form of a single-junction transistor.  3. The device according to claim 1, characterized in that the threshold element with memory contains a third diode, a fourth resistor, a third capacitor and an operational amplifier, the non-inverting input of which through the diode is connected to the first terminals of the fourth resistor and the third capacitor, the second terminal of which is connected to the output the output of the second power source, and the second output of the fourth resistor is connected to the output of the operational amplifier.  4. The device according to claim 1, characterized in that the first and second rectified voltage sources contain filter capacitors and series-connected circuits, each of which contains a ballast element and a diode, the first output of each chain is connected to a terminal connected to the corresponding phase of the network, and the second conclusions of the chains are the outputs of the sources and are connected to the first conclusions of the corresponding filter capacitors, the other conclusions of each of which are connected respectively to the common output of the rectified voltage source and with the midpoint of its chain in series.

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