RU2350001C1 - Electrical motor protection device - Google Patents

Abstract

FIELD: electricity; motors and pumps.

SUBSTANCE: protection device consists of current transformers, magnetic starter, three-phase AC power supply, rectifier, overload control unit, current-time curve generation unit. The latter unit is comprised of a thermal electrical motor imitator based on operating amplifier with the negative feedback parallel RC coupling, comparator and final control relay. The second operating amplifier with the negative feedback parallel RC coupling is introduced into the thermal imitator. The inverting input of the second operating amplifier is connected to the first operating amplifier output through the scaling resistor. The second operating amplifier output is coupled with the first operating amplifier input through the other scaling resistor.

EFFECT: increased device actuation accuracy and timely tripping of electrical motor.

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Description

The invention relates to electrical engineering and can be used in various sectors of the economy to disconnect the electric motor from the network during emergency operation.

Known devices for protecting electric motors containing current transformers for connecting to different phases of the electric motor power supply, a voltage rectifier, an overload control unit, a thermal electric motor simulator, a comparator and an actuating relay [1].

The closest in technical essence is a device for protecting the electric motor, containing current transformers for connecting to different phases of the electric motor power supply, a rectifier, the inputs of which are connected to the outputs of the corresponding current transformers, an overload control unit, the inputs of which are connected to the outputs of the rectifier, and the outputs to the inputs of the block the formation of the time-current characteristic, the outputs of the executive relay [2] are connected to the outputs of the latter through a comparator. In known protection devices, the circuit is powered from the same transformers, rectifiers, from which information about the current value of the protected circuit is taken. This reduces the weight and dimensions of the device.

A disadvantage of the known device is that the output voltage of the thermal simulator does not exactly match the temperature of the motor windings. This reduces the accuracy of the operation of the device and the timely shutdown of the motor.

The objective of the invention is to increase the accuracy of operation of the device and thereby timely shutdown of the electric motor.

This task is achieved by the fact that in the device for protecting the electric motor, containing current transformers for connecting to different phases of the electric motor power supply, a rectifier, the inputs of which are connected to the outputs of the respective current transformers, an overload control unit, the inputs of which are connected to the outputs of the rectifier, and a time-current characteristic generating unit , which in turn consists of a thermal simulator of an electric motor made on an operational amplifier with negative parallel feedback RC, and the parator, the inputs of the forming unit are connected to the outputs of the overload control unit, and the output normally open contacts of which are connected to the voltage source through the coil of the executive relay, and a second operational amplifier with negative reverse parallel RC connection is inserted into the thermal simulator, whose inverting input is connected to the output of the first operating amplifier, and the second output to the input of the first operational amplifier. This embodiment of the device allows to obtain a voltage simulating the temperature of the stator windings of the electric motor taking into account the temperature of the stator steel at the output of the block forming the time-current characteristic.

Figure 1 shows the electrical circuit of the proposed device; figure 2 is a structural diagram of a thermal engine simulator.

The device contains 1-3 current transformers for connecting the electric motor power to phases A-C, a rectifier 4, the inputs of which are connected to the outputs of the 1-3 current transformers, an overload control unit 5, the inputs of which are connected to the outputs of the rectifier 4, a time-current characteristic generating unit, which in turn, consists of a thermal simulator 6 and a comparator 7. The output normally open contacts of the comparator, which are simultaneously the output contacts of the unit for generating the time-current characteristic, are connected but with the winding of the executive relay 8, and the formed serial circuit is connected to a voltage source. A quadrator 9 made on an operational amplifier using a field-effect transistor 10 with a control p-n junction can enter the time-current characteristic forming unit. The overload control unit 5 is made in the form of a series-connected zener diode 11, a shunt resistor 12 and a zener diode 13. A capacitor 14 is used as a filter. The cathode of the zener diode 11 is connected to the positive terminal of the rectifier, and the anode of the zener diode 13 is connected to the negative terminal of the rectifier, the ends of the shunt resistor 12 form output terminals of overload control unit 5.

The electric motor 15 is connected through a magnetic starter 16 to a three-phase AC source with phases A, B, C and neutral wire N.

The power of the operational amplifiers and the comparator is carried out from the voltages removed from the output of the rectifier 4. For the purpose of illustrating the operation of the device, the wires connecting the power to the operational amplifiers and the comparator are not shown in the electric circuit.

The coil of the magnetic starter 16 is connected to the network through a normally open button 17 "Start" and a normally closed button 18 "Step". In parallel with the “Start” button, normally open contacts of the starter 16 are connected. In series with the 18 “Stop” button, normally closed contacts of the executive relay 8 are connected.

Additionally, the device provides for the possibility of accelerated disconnection of the network from overload currents. For this purpose, a zener diode 19 is connected between the output negative terminal of the rectifier 4 and one of the input of the comparator 7.

In the proposed device, the thermal simulator 6 is made on the operational amplifier 20 with a negative connection.

Negative feedback is provided by a resistor 21 and a capacitor 22 connected in parallel between each other and between the output of the inverting input of the amplifier. A second operational amplifier 23 is also introduced into the thermal simulator, also with negative feedback. Negative feedback in the amplifier is provided by a resistor 24 and a capacitor 25, also connected between themselves in parallel and between the inverting input and output of the amplifier. Moreover, the inverting input of the amplifier 23 is connected through a large-scale resistor 26 to the output of the amplifier 20, and its output through a large-scale resistor 27 to the input of the amplifier 20.

The device operates as follows.

When you press the button 17 "Start" on the coil of the magnetic starter 16, the mains voltage is applied. The power contacts of the starter 16 are closed, the mains voltage is supplied to the electric motor, the contacts shunting the “Start” button are closed at the same time, and voltage is supplied to the starter coil 16. At the same time, currents flow through the primary windings of transformers 1-3. Voltages will be induced in the secondary windings of these transformers, and currents will arise through these windings, the magnitude of which is determined by the transfer coefficient of the transformers. The output voltage of the rectifier 4 will be determined by the voltage stabilization of the zener diodes 11, 13 and the voltage drop across the shunt resistor 12. Due to the small resistance of the shunt resistor, the output voltage of the rectifier will be kept stable and can be directly used to power operational amplifiers and a comparator.

The operation mode of the transistor 10 is set by the resistance of the resistor 12, 28 in the initial section of its current-voltage characteristics. We can assume that the current flowing through the resistor 28 will be proportional to the currents flowing through the windings of transformers 1-3. The current i _{c of the} drain of the transistor 10 will be almost equal to the current of the resistor 12. At low voltages U _{cu, the} drain - source field effect transistor behaves like a controlled resistor, the channel resistance of which is proportional to the absolute voltage at its pn junction. Therefore, the field-effect transistor, the gate of which is connected to the source, has a quadratic dependence U _cu = f (i _c ) ² , since the drain current determines the voltage drop of the channel, which in turn determines the resistance of the channel. We have the resistance R _cu drain - the source of the channel as a function of the current i _{c of the} drain of the transistor, i.e.

On the other hand, the drain current i _c is determined by Ohm's law

Solving together (1) and (2), we obtain

или

,

or

,

those. The drain current has a quadratic dependence of the voltage drop across the transistor on the drain current.

The output voltage of the simulator 6 simulates the temperature of the heating of the stator windings of an induction motor. A resistor 21, connected in parallel with the capacitor 22, simulates the cooling of the windings by discharging the capacitor 22.

The output voltage of the operational amplifier 23 simulates the value of the heating temperature of the stator steel. A resistor 24, connected in parallel with the capacitor 25, simulates the cooling of engine steel. The scale resistor 26 is determined based on the heating coefficient of steel from the stator windings, and the scale resistor 27 is determined based on the heating coefficient of the stator windings from steel. Hence, the output voltage of the thermal simulator 6 will simulate the actual heating of the stator windings, not only taking into account their cooling, but also taking into account the temperature of steel heating and its cooling.

When the voltage at the output of the thermal simulator of the response threshold set by the resistors at the input of the comparator 7 is reached, the electronic key closes at its output, current flows through the winding of the executive relay 8, its normally closed contacts open, which are connected in series with the Stop button. Through the coil of the magnetic starter 16, the current will stop and its contacts will open. The electric motor is de-energized.

If the current flowed to the electric motor no higher than the set value, its start-up was normal and the electric motor is functioning normally, then the output voltage of the simulator 6 does not reach the threshold of the comparator 7.

When the electric motor is disconnected from the mains by the Stop button or as a result of an emergency operation of the device through the transformer windings 1-3, the currents stop, the coil of the executive relay 8 is de-energized, its contacts are closed, i.e. after a certain period of time, the device is ready for restarting. The capacitor 22 of the simulator 6 is gradually discharged through a resistor 21, respectively.

In the event of emergency operating conditions, for example, when a circuit is closed, large currents exceed the starting currents flow through the primary windings of transformers 1-3. At the output of rectifier 4, a significantly higher voltage will appear. The operating point of the zener diode 19 enters the mode of electrical breakdown, resulting in a voltage drop at the midpoint of the voltage divider of the comparator 7. The comparator is triggered, current will flow through the coil of the executive relay 8 and the magnetic starter will disconnect from the mains voltage. This ensures quick identification of the emergency mode and disconnecting the electric motor from the mains voltage without installing special protections, since the device also has high-speed protection, which is detuned from the starting currents.

In the proposed device for supplying operational amplifiers and a comparator, stabilized voltages from the same rectifier are used, from which a signal is obtained proportional to the current of the protected electric motor, without the use of special stabilizers. This leads to a simplification of the design of the device.

The use of a thermal simulator of a second-order electric motor, which takes into account copper heating and separately heating the stator steel, increases the reliability of protecting the electric motor from current overloads of unacceptable duration, because Such a thermal simulator more accurately takes into account the heating of the stator wires, which leads to the timely shutdown of the electric motor.

When modeling the thermal processes occurring in the engine, we obtain a closed link with positive feedback (figure 2), where k ₁ , k ₂ , k ₃ - transmission coefficients;

T ₁ - constant cooling time of copper (stator winding), s;

T ₂ is the stator cooling time constant (stator steel), s;

p - time differentiation operator, s ^-1 .

The transfer function of the obtained model of thermal heating of the engine has the form

.

.

This transfer function corresponds to a thermal simulator 6 of heating the motor windings (Fig. 1) k ₁ <1, k ₂ <1, hence the real part of the positive feedback is less than unity. The system is always stable.

Improving the accuracy of simulating thermal processes in the engine leads to an increase in the accuracy of operation of the device, to the timely shutdown of the engine.

Information sources

1. Patent 2009593 of the Russian Federation, cl. H02H 7/08, 1994.

2. Patent 2192699 of the Russian Federation, cl. H02 7/08, 2001.

Claims (1)

A device for protecting an electric motor, containing current transformers for connecting the electric motor to different phases of the electric motor, which is connected to a three-phase AC source by means of a magnetic starter, and the magnetic starter coil is connected to the network by means of a normally open “Start” button, a rectifier, the inputs of which are connected to the outputs corresponding current transformers, an overload control unit, the inputs of which are connected to the outputs of the rectifier, a unit for generating a current-time characteristic, consisting, in turn, of a thermal simulator of an electric motor made on an operational amplifier with negative parallel RC feedback, and a comparator, the inputs of the time-current characteristic forming unit are connected to the outputs of the overload control unit, and the output normally open contacts are connected in series with the actuator relay winding, the serial circuit formed in this case is connected to a voltage source, characterized in that a second operational amplifier with negative-feedback RC-parallel connection, the inverting input of which is connected through a scaling resistor to the output of the first operational amplifier and its output through another resistor to the input of the scaling of the first operational amplifier.