RU66130U1 - FREQUENCY CONVERTER - Google Patents

Abstract

The utility model relates to a conversion technique and can be used as a power source for induction heaters. The utility model improves the reliability of the frequency converter. The frequency converter contains a direct current source and an autonomous current inverter, made in the form of a single-phase bridge on controlled gates 1-4 with counter-parallel diodes 5-8, connected to the output terminals of the DC source through the inductors of the filter 9, 10. The output terminals of the AC single-phase the bridge is connected to the output terminals of the frequency converter through switching inductors 11, 12. The output terminals of the frequency converter are shunted by a compensating capacitor 13. The DC source is made n in the form of a three-phase bridge on controlled valves 14-19. The input terminals of an alternating current of a three-phase bridge are connected to the input terminals of a frequency converter via saturation reactors 20-22. The load 23 is connected to the output terminals of the frequency converter. 1 ill.

Description

The utility model relates to a conversion technique and can be used as a power source for induction heaters. The utility model improves the reliability of the frequency converter.

A known frequency converter containing a direct current source and an autonomous current inverter, made in the form of a single-phase bridge on controlled valves, connected to the output terminals of the direct current source through the filter chokes, the output terminals of the frequency converter are shunted by a compensating capacitor (P. 2284640 RF, MKI N02M 7 \ 538. A method of controlling a current inverter \ Silkin EM - Declaration 10.11.04, Publish 27.09.06. BI No. 27).

The disadvantage of the frequency converter is the low reliability of operation on the induction heater, which is due to the lack of protection during overloads and short circuits of the induction heater.

A known frequency converter containing a direct current source and an autonomous current inverter, made in the form of a single-phase bridge on controlled valves with on-parallel diodes, connected to the output terminals of the DC source through the chokes of the filter, the output terminals of the alternating current of a single-phase bridge are connected to the output terminals of the frequency converter through switching inductors, the output terminals of the frequency converter are shunted by a compensating capacitor (P. 2220495 RF, MKI N02M 7 \ 5387. Current inverter \ Silkin E.M. - Declaration of March 18, 02, Publish. December 27, 03. BI No. 36).

The disadvantage of the frequency converter is the low reliability of operation on the induction heater, which is due to the lack of protection during overloads and short circuits of the induction heater.

The closest in technical essence to the utility model is a frequency converter containing a direct current source and an autonomous current inverter, made in the form of a single-phase bridge on controlled gates with counter-parallel diodes, connected to the output terminals of the direct current source through the filter chokes, AC output terminals single-phase bridge connected to the output terminals of the frequency converter through switching inductors, the output terminals of the frequency converter are shunted sizing capacitor (P. 2284641 of the Russian Federation, MKI N02M 7 \ 5387. Current inverter \ Silkin EM - Application. 12.05.03, Publish. 09.27.06. BI No. 27).

The specified frequency converter is considered (selected) as a prototype.

The disadvantage of the prototype is the low reliability, which is caused by insufficiently effective protection of the frequency converter during overloads and short circuits of the induction heater.

The utility model is aimed at solving the problem of increasing the reliability of the frequency converter, which is the purpose of the utility model.

This goal is achieved by the fact that in a frequency converter containing a direct current source and an autonomous current inverter, made in the form of a single-phase bridge on controlled gates with counter-parallel diodes, connected to the output terminals of the DC source through the chokes of the filter, the output terminals of the AC single-phase bridge connected to the output terminals of the frequency converter via switching inductors, the output terminals of the frequency converter are shunted by a compensating capacitor, the source to the DC is formed as a three-phase bridge to controlled valves, input terminals of the three-phase AC bridge is connected to the input terminals of the frequency converter via

saturation chokes.

A significant difference characterizing the utility model is an increase in the reliability of the frequency converter, which is achieved by its effective protection against overloads and short circuits of the induction heater by transferring the three-phase bridge on the controlled valves by changing the control phase of the controlled valves of the three-phase bridge to the operation mode of the inverter driven by the network.

Improving the reliability of the frequency converter is a technical result due to new elements in the frequency converter circuit, the order of their inclusion and new connections, that is, the hallmarks of the utility model. Thus, the distinguishing features of the inventive frequency converter are essential.

The figure shows the electrical circuit of the frequency converter.

The frequency converter contains a direct current source and an autonomous current inverter, made in the form of a single-phase bridge on controlled gates 1-4 with counter-parallel diodes 5-8, connected to the output terminals of the DC source through the chokes of the filter 9, 10, the output terminals of the AC single-phase of the bridge are connected to the output terminals of the frequency converter via commutating chokes 11, 12, the output terminals of the frequency converter are shunted by a compensating capacitor 13. The DC source is made n in the form of a three-phase bridge on controlled valves 14-19. The input terminals of an alternating current of a three-phase bridge are connected to the input terminals of a frequency converter via saturation reactors 20-22. A load (induction heater) 23 is connected to the output terminals of the frequency converter.

The frequency converter in steady state operates as follows. A three-phase source is connected to the input terminals of the frequency converter

AC supply voltage (mains). The three-phase bridge on the controlled gates 14-19 converts the alternating voltage of the network into a constant voltage, which is applied to the DC input terminals of the single-phase bridge on the controlled gates 1-4 with in-parallel diodes 5-8 of the inverter through the filter chokes 9, 10. The total inductance of the chokes filter 9, 10 is selected from the condition of smoothing the input current of the inverter, which is achieved by exceeding the total inductive resistance of the filter chokes 9, 10 at the inverter operating frequency equivalent to rotation of the load oscillating circuit formed by the induction heater 23 and the compensating capacitor 13, more than three times. The control pulses for pairs of controlled gates 1, 4 and 2, 3 of the single-phase bridge of the current inverter are supplied alternately with a frequency equal to the output frequency of the frequency converter and slightly higher than the natural frequency of the load oscillating circuit formed by the induction heater 23 and the compensating capacitor 13. The inverter operates at a higher frequency compared with the natural frequency of the load oscillating circuit allows you to provide close to optimal conditions for switching controlled valves 1 -4 single-phase bridge. Alternately switching pairs of controlled gates 1, 4 and 2, 3 of the single-phase inverter bridge generates an output alternating voltage on the load oscillating circuit. Switching chokes 11, 12 reduce the level of switching overvoltages and limit the rate of rise of the current of the controlled valves 1-4 at the time of switching.

The three-phase bridge on the controlled valves 14-19 operates in the fully controlled rectifier mode (direct current source) with phase regulation. Phase regulation of the rectifier provides the required change in the value of the supply (constant) voltage at the input of the current inverter of the frequency converter. Saturation Inductors 20-22 limit surge levels for controlled switching

valves 14-19 of a three-phase rectifier bridge.

A stepwise increase in the angle of control of the rectifier to 120 degrees. email puts the rectifier, working on the load of the frequency converter, into the inverter mode driven by the network. In this case, the input DC voltage of the inverter decreases, and the energy stored in the electromagnetic field of the filter chokes 9, 10 is recovered in the supply network. The adjustable rectifier is switched to the network-driven inverter mode each time the frequency converter is turned off, as well as in emergency situations, including overloads and short-circuits of the induction heater 23. Regulation of the DC voltage at the input of the current inverter allows stabilization of the voltage level at the output of the frequency converter and levels of direct voltages on controlled valves 1-4 and reverse voltages on on-parallel diodes 5-8 of a single-phase bridge.

The controlled valves 14-19 of the three-phase rectifier bridge can also simulate the operation of the “zero” valve at control angles of more than 90 degrees. e., which reduces the ripple of the rectified (constant) voltage at the input of the current inverter. To simulate the operation of the “zero” valve at large control angles, the corresponding valves adjacent to the main working valves at the shoulders of the three-phase bridge are switched on.

As controlled gates 14-19 of a three-phase rectifier bridge in a frequency converter, single-operation (SCR) thyristors can be used. As controlled gates 1-4 of the single-phase inverter bridge, both single-operation thyristors or reversible-switched dynistors and fully controlled gates (transistors, lockable thyristors), including valves that do not have reverse blocking ability, are used. Counter-parallel diodes 5-8, in particular, can be made based on Schottky diodes.

Saturation chokes 20-22 are implemented in the form of continuous (closed) ferromagnetic cores spanning connecting busbars without gaps from a non-ferromagnet.

The function of the switching chokes 11, 12 can be fully or partially performed by the inductance of the connecting buses of the frequency converter.

Compared with the prototype, the reliability of the frequency converter is significantly increased. This is achieved by reducing the overvoltage levels on the controlled rectifier and current inverter valves, reducing the forward voltage rise rates on the controlled current inverter valves and direct current through them in the switching intervals, reducing the electromagnetic interference levels that occur during switching of the rectifier and inverter valves, limiting the current through the converter elements frequency in emergency conditions, limiting the "buildup" of voltage on the elements when the load changes over a wide range, optimization of the device the power circuit of the frequency converter, ensuring effective protection of the frequency converter during overloads and short circuiting of the induction heater due to the transfer of the adjustable rectifier to the inverter driven by the network.

Compared with the prototype, in addition, the efficiency of the frequency converter is increased by reducing switching energy losses in controlled valves (lowering levels of switching overvoltages and initial rise and fall rates of currents when turning on and off controlled valves, recovering part of the overvoltage energy to an AC voltage source )

Additionally, in comparison with the prototype, the design of the energy (power) part of the frequency converter can be significantly simplified and its cost can be reduced due to the possibility of using controlled valves with

lower requirements for their parameters and lower price, as well as a more optimal device power circuit.

Compared with the prototype, the field of application of the utility model is expanding due to the provision of regulation of the electrical mode of operation and (or) stabilization of the output electrical parameters of the frequency converter and induction heater.

Claims (1)

A frequency converter containing a direct current source and an autonomous current inverter, made in the form of a single-phase bridge on controlled gates with anti-parallel diodes, connected to the output terminals of the direct current source through the filter chokes, the output terminals of the alternating current single-phase bridge are connected to the output terminals of the frequency converter through switching inductors, the output terminals of the frequency converter are shunted by a compensating capacitor, characterized in that the source of constant t The eye is made in the form of a three-phase bridge on controlled gates, the input terminals of the alternating current of the three-phase bridge are connected to the input terminals of the frequency converter via saturation chokes.