RU2751534C1 - Frequency converter - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to the field of electrical engineering and power electronics, in particular to static electrical frequency converters with double conversion of electrical energy. The technical result is achieved by the fact that a circuit breaker and an additional charging resistor are added to the circuit of the electric frequency converter, as well as new connections that allow the control system to be powered from the DC link of the power circuit of the frequency converter. The charging current of the storage capacitor is limited by means of two charging resistors, and the charging current of the storage capacitor is rectified using an artificially organized single-phase full-wave rectifier. Switching on and off of the frequency converter is possible both in manual mode and in remote mode from the upper level system. With a minimum number of elements, the electrical safety of the operating personnel and the reliability of the frequency converter are increased, efficiency is increased, weight, dimensions are reduced, and the functionality of the frequency converter is significantly improved.EFFECT: proposed frequency converter makes it possible to increase the safety of the device during operation, simplify the design of the device, simplify installation and operation, reduce weight, dimensions and cost, and also ensures both manual and remote start and shutdown of the frequency converter by a command from the upper-level system, increases reliability and efficiency of the device during its operation.4 cl, 4 dwg

Description

The proposal relates to the field of electrical engineering and power electronics, in particular to static electrical frequency converters with double conversion of electrical energy.

A device and method for pre-charging a storage capacitor of an electrical converter is known (US patent 20080239432, class H2H 7/125, priority date 09/26/2008, publication date 04/01/2010), containing a voltage rectifier, a voltage inverter, a storage capacitor and a charging resistor installed after the voltage rectifier and limiting the charging current of the storage capacitor, as well as a contactor that bypasses the charging resistor with its contact after the end of charging. The disadvantage of the known device is the need to install an additional power contactor, the contact of which must be designed for the full load current that flows in the DC link, and the presence of a powerful charging resistor.

Known frequency converter (the journal "Electrical Engineering", December 2001, "Comparative analysis of control algorithms for autonomous voltage inverters in asynchronous electric drives", author Gruzov V.L. pp. 34-40), containing an input power contactor, a rectifier, to the positive terminal of which through The smoothing choke is connected to the positive poles of the autonomous voltage inverter, braking module and storage capacitor, and negative poles of the autonomous voltage inverter, braking module and storage capacitor are connected to the negative terminal. The storage capacitor is charged using three current-limiting charging resistors, which are connected in parallel with the three power contacts of the input contactor. One of the terminals of each resistor is connected to the mains phase, and the other terminal is connected to the AC terminal of the rectifier. The disadvantage of the device is the need to use three charging resistors, which limit the inrush current of the capacitor. As a result, the weight, dimensions and cost of the device increase, and the reliability decreases. In addition, regular monitoring of the storage capacitor charging circuit is required. Another significant disadvantage of such a circuit is that when the contactor is off, the frequency converter circuit is under power voltage, as well as the fact that there are no protective devices in the frequency converter circuit that prevent the occurrence of emergency modes in the event of a short circuit.

The closest in technical essence is a frequency converter (patent RU 2653856 C2, class Н02М 5/42, priority date 09/20/2016, publication date 03/21/2018 Frequency converter, authors Gelver A.A., Gelver F.A. ), containing an input power contactor, a voltage rectifier, to the positive terminal of which the positive poles of the autonomous voltage inverter, braking module and storage capacitor are connected, and the negative poles of the autonomous voltage inverter, braking module and storage capacitor are connected to the negative terminal. The storage capacitor is charged using a single charging resistor and a voltage relay, organizing charging circuits parallel to the two contacts of the input power contactor. The advantage of the known invention is the simplicity of the circuit implementation of the charge circuit, as well as the implementation of the protection of the charge circuit from possible short circuits using fuses. The disadvantage of the known invention is the need for independent power supply of the control system or its power supply from the terminals of the supply network, as well as the need to protect the power supply line of the control system. In addition, the known scheme provides for the activation of the frequency converter only from the control system, and there is no provision for manual activation of the charging circuit without power supply to the control system. In the event of a short circuit of the frequency converter circuits after the input contactor to the case in networks with isolated neutral, the frequency converter will not be able to disconnect itself from the mains supply and protect the maintenance personnel from electric shock.

The proposed frequency converter makes it possible to simplify the design of the device, evenly distribute the energy of the charging circuit between the charging resistors, increase the efficiency, reliability, safety of the device during operation, as well as improve the overall and operational characteristics. In addition, the proposed frequency converter allows both manual starting of the frequency converter and starting from the upper level system. The advantage of the proposal should also include the limitation of the current value in the event of a short circuit to the ground, as well as the use of a reusable protective device in the circuit. In addition, the proposed circuit of the frequency converter allows automated control of the insulation resistance of the frequency converter before its operation. The proposed circuit of the frequency converter allows the control system to be powered from the DC link, which allows protection against switching on the frequency converter in the event of a short circuit in the DC link. Thus, such a circuit design allows for automated pre-start diagnostics of the frequency converter. In addition, such an organization of the storage capacitor charging circuit allows the frequency converter to be reliably de-energized during its maintenance and repair, as well as to exclude the false activation of the input power contactor in the event of a control system failure.

The problem is solved due to the fact that in the frequency converter circuit containing a control system, a charging resistor, an input power contactor consisting of normally open contacts and a coil, the contactor coil is connected to the control system, the contacts of the input power contactor are connected by their input to the mains, and their output is connected to the input of a three-phase rectifier bridge, to the output of which an autonomous voltage inverter, a storage capacitor and a braking module consisting of a transistor of two diodes and a braking resistor are connected, and the transistor collector is connected to the cathode of the first diode and the positive bus of the rectifier bridge, and the emitter of the transistor is connected with the anode of the first diode, the cathode of the second diode and the first terminal of the braking resistor, the second terminal of which is connected to the anode of the second diode and the negative bus of the rectifier bridge, the charging resistor is connected by its first terminal to the output of the first contact of the input force contacts new contactor, the following differences are provided: the frequency converter is equipped with a two-pole automatic switch and an additional: charging resistor, moreover: the second terminal of the charging resistor through the first contact of the circuit breaker is connected to the input of the first contact of the contacts of the input power contactor, the additional charging resistor is connected with its first terminal to the output of the second the contacts of the contacts of the input power contactor, and the second output of the additional charging resistor is connected through the second contact of the circuit breaker to the input of the second contact of the contacts of the input power contactor, and the control system is connected to the output of the rectifier bridge.

In addition, the frequency converter may contain a circuit breaker with an electromagnetic on-off coil and an electromagnetic off-coil, and the on-and-off electromagnetic coils are connected to the terminals of the upper level system, in addition, the electromagnetic off coil is connected to the upper level control system.

In addition, the frequency converter can contain a two-pole residual current device, which is included in the circuit between the contacts of the circuit breaker and the charging resistors, the residual current device has a mechanical release and a normally open contact, and the mechanical release is mechanically connected to the circuit breaker and the normally open contact of the residual current device. , and the normally open contact of the residual current device is connected to the control system.

In addition, the frequency converter may contain a circuit breaker, which additionally contains a normally open contact block installed in the power circuit of the contactor coil.

The frequency converter, the diagram of which is shown in FIG. 1, contains a control system 1, a charging resistor 2, an input power contactor consisting of normally open contacts 3 and a coil 4. Coil 4 of the contactor is connected to the control system 1. Contacts 3 of the input power contactor are connected by their input to the supply network 5, and by their output connected to the input of the three-phase rectifier bridge 6. To the output of the three-phase rectifier bridge 6 are connected an autonomous voltage inverter 7, a storage capacitor 8 and a braking module 9, consisting of a transistor 10 of two diodes 11, 12 and a braking resistor 13. The collector of the transistor 10 is connected to the cathode of the first diode 11 and the positive bus of the rectifier bridge 6, and the emitter of the transistor 10 is connected to the anode of the first diode 11, the cathode of the second diode 12 and the first terminal of the braking resistor 13. The second terminal of the braking resistor 13 is connected to the anode of the second diode 12 and the negative bus of the rectifier bridge 6. Charging resistor 2 with its first pin is connected to the output of the first contact 14 to contacts of the 3 input power contactor. The frequency converter is equipped with a two-pole automatic switch 15 and an additional: charging resistor 16. The second output of the charging resistor 2 through the first contact 17 of the circuit breaker 15 is connected to the input of the first contact 14 of contacts 3 of the input power contactor. An additional charging resistor 16 with its first terminal is connected to the output of the second contact 18 of contacts 3 of the input power contactor. Second: the output of the additional charging resistor 16 is connected: through the second contact 19 of the circuit breaker 15 to the input of the second contact 18 of the contacts 3 of the input power contactor. Control system 1 is connected to the output of the rectifier bridge 6.

The frequency converter (Fig. 2) can be made so that the circuit breaker 15 contains an electromagnetic on-coil 20 and an electromagnetic off-coil 21. The on-off and off-magnetic coils 21 are connected to the terminals 22 of the upper-level system. The solenoid coil 21 is connected to the control system 1 of the frequency converter.

The frequency converter (Fig. 3) may contain a two-pole residual current device 23, which is included in the circuit between contacts 17, 19 of the circuit breaker 15 and the charging resistors 2, 16. The residual current device 23 has a mechanical release 24 and a normally open contact 25, the mechanical the release 24 is mechanically connected to the circuit breaker 15 and the normally open contact 25 of the residual current device 23. The normally open contact 25 of the residual current device is connected to the upper level control system.

The frequency converter (Fig. 4) can be made, so that the circuit breaker 15 additionally contains a normally open block contact 26 installed in the power circuit of the coil 3 of the contactor.

The operation of the frequency converter is as follows. If it is necessary to turn on the frequency converter, it is necessary to manually (Fig. 1) turn on the circuit breaker 15. In this case, contacts 17 and 19 of the circuit breaker 15, form the charging circuit of the storage capacitor 8 - phase A of the supply network 5, contact 17 of the circuit breaker 15, charging resistor 2 , diode of the cathodic (anode, depending on the polarity of voltage U _AB ) group of a three-phase rectifier 6 connected to phase A, storage capacitor 8, an anode diode (cathode, depending on the polarity of voltage U _AB ) of the group of three-phase rectifier 6 connected to phase B, additional charging resistor 16, contact 19 of the circuit breaker 15 and phase B of the supply network 5. With a positive half-wave of voltage U _{AB, the} diode of the cathode group connected to phase A and the diode of the anode group connected to phase B will work, and vice versa with a negative half-wave of voltage U _AB will work the diode of the anode group connected to phase A, and the diode of the cathode g group connected to phase B. Thus, the charging circuit is a single-phase full-wave rectifier with a limitation of the charging current by the value of the total resistance of the charging resistor 2 and an additional charging resistor 16 installed on the AC side. In this case, the process of increasing the voltage across the capacitor 8 is exponential with a time constant determined by the parameters of the total resistance of the charging resistor 2 and the additional charging resistor 16 and the value of the storage capacitor 8. The current changes in the value of the inverse exponential dependence on the maximum value of the total resistance of the charging resistor 2, limited by the value. and an additional charging resistor 16 to zero with the same time constant. After the end of the charging process, the control system 1 will be powered from the output of the voltage rectifier 6 from the DC link. If no emergency situations occurred during the charging of the storage capacitor 8, the control system 1 diagnosed the state of the elements of the frequency converter and did not detect emergency modes, it will turn on the coil 4 of the contactor, which will close the contacts 3 of the contactor, thereby making the power connection of the frequency converter to the supply network 5. Contacts 17 and 19 of the circuit breaker 15 must be designed for a rated current 5-7 times less than the starting or charging current of the storage capacitor 8. In this case, the circuit breaker 15 protects the charging circuit and the entire frequency converter from a short circuit in the DC link or the input of the three-phase voltage rectifier 6. In the event of a short circuit in the DC link or at the input of the three-phase voltage rectifier 6, the current consumed from the network 5 will be limited only by the value of the total resistance of the charging resistor 2 and the additional charging resistor 16, while the current value of the current will be unchanged, which will cause the circuit breaker 15 to trip and disconnect the frequency converter from the supply network 5. In this case, the control system 1 will not receive power and will not be able to turn on the coil 4 and contacts 3 of the input power contactor. In addition, the disconnected circuit breaker 15 provides the possibility of safe maintenance and repair of the frequency converter in the presence of voltage on the phases of the supply network 5. In the event of an emergency operation of the circuit breaker 1.5 and after eliminating the malfunction in the frequency converter, you can immediately carry out a test run without replacing the charging circuit elements. The advantage of the proposed scheme is that the control system 1 is powered by a DC link. With such a power scheme, the control system 1 can receive, store and analyze information from the sensors of the frequency converter during its emergency shutdown. Another advantage of this circuit is that the charging resistor 2 and the additional charging resistor 16 are energized and limit the charging current of the storage capacitor 8 only in the process of preparing the frequency converter for operation for a short period of time, and after turning on the contacts 3 of the contactor will be bypassed. The advantage of the proposal can be considered the fact that in the event of a voltage failure on the phases of the supply network 5, and then its appearance, the frequency converter will automatically charge the storage capacitor 8 and prepare the frequency converter for operation.

In order to be able to remotely turn on and off the charging circuit of the frequency converter (Fig. 2) on command from the upper level system, the circuit breaker 15 can be equipped with an electromagnetic on-off coil 20 and an electromagnetic off-coil 21, which can be controlled from the terminals 22 of the upper-level system. For the possibility of automatic complete disconnection of the frequency converter from the mains in emergency situations, the electromagnetic shutdown coil 21 can be connected to the control system 1 of the frequency converter. So, in the event of an emergency, the control system will turn on the electromagnetic shutdown coil 21 and completely disconnect the frequency converter from the supply network 5. by disconnecting contacts 3 and contacts 17, 19 of the circuit breaker 15.

In order to protect the maintenance personnel from electric shock, the frequency converter (Fig. 3) can be equipped with a residual current device 23. The residual current device 23 allows diagnosing a decrease in the insulation resistance of the frequency converter, as well as detecting the short circuit of the frequency converter circuits to the case. The residual current device 23 is included in the circuit between contacts 17, 19 of the circuit breaker 15 and the charging resistors 2, 16. When the circuit breaker 15 is turned on and in the presence of a short circuit of the frequency converter circuits to the case or a decrease in insulation, currents flowing through the charging resistor 2 and the additional charging resistor 16, will not be equal, and the residual current device 23 will operate. The mechanical release 24 of the residual current device 23 will disconnect the contacts 17, 19 of the circuit breaker 15 and break the charge circuit and, therefore, prevent the frequency converter from turning on. In this case, contact 25 of the residual current device will give a signal about an unsuccessful charge of the storage capacitor and an unsuccessful start of the frequency converter to the upper level system.

In order to protect the maintenance personnel and reduce the number of control variables and control signals in the frequency converter (Fig. 4), it can be made, since the circuit breaker 15 additionally contains a normally open block contact 26 installed in the power circuit of the coil 3 of the contactor. If it is necessary to disconnect the frequency converter from the mains during its operation in the staging mode or in case of an emergency, it is enough to turn off the circuit breaker 15, while the contacts 3 of the contactor are also automatically disconnected by disconnecting the power supply to the coil 4 of the contactor block by contact 26.

Thus, the proposed device simplifies the design of the converter, increases the safety of service personnel and operational efficiency, increases reliability, simplifies installation and operation, reduces weight and dimensions, and also allows you to significantly expand the functionality.

Claims (4)

1. A frequency converter containing a control system, a charging resistor, an input power contactor consisting of normally open contacts and a coil; bridge, to the output of which an autonomous voltage inverter, a storage capacitor and a braking module are connected, consisting of a transistor, two diodes and a braking resistor, and the collector of the transistor is connected to the cathode of the first diode and the positive bus of the rectifier bridge, and the emitter of the transistor is connected to the anode of the first diode, the cathode the second diode and the first terminal of the braking resistor, the second terminal of which is connected to the anode of the second diode and the negative bus of the rectifier bridge, the charging resistor is connected by its first terminal to the output of the first contact of the contacts of the input power contactor, characterized in that it is equipped with two with a pole-mounted circuit breaker and an additional charging resistor, the second terminal of the charging resistor through the first contact of the circuit breaker is connected to the input of the first contact of the contacts of the input power contactor, the additional charging resistor is connected by its first output to the output of the second contact of the contacts of the input power contactor, and the second terminal of the additional charging resistor connected through the second contact of the circuit breaker to the input of the second contact of the contacts of the input power contactor, and the control system is connected to the output of the rectifier bridge. 2. The frequency converter according to claim 1, characterized in that the circuit breaker contains an electromagnetic on-off coil and an electromagnetic off-coil, the on-and-off electromagnetic coils are connected to the terminals of the upper level system, in addition, the off electromagnetic coil is connected to the upper level control system. 3. The frequency converter according to claim 1, characterized in that it additionally contains a two-pole residual current device, which is included in the circuit between the contacts of the circuit breaker and the charging resistors, the residual current device has a mechanical release and a normally open contact, and the mechanical release is mechanically connected to the automatic circuit breaker and normally open contact of the residual current device, and the normally open contact of the residual current device is brought into the upper-level control system. 4. Frequency converter according to claim 1, characterized in that the circuit breaker additionally contains a normally open contact block installed in the power circuit of the contactor coil.

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