SU1647813A1 - Inverter - Google Patents

Abstract

This invention relates to the field of power conversion technology. The goal is to increase the functional reliability of the inverter by detecting an emergency situation and preventing its development. The inverter contains three thyristor bridges: main 1 - 6, distribution 7 - 12 and reverse 13-18. Between the poles of the main and distribution bridges of the same polarity, switching capacitors 19, 20 are connected through dual-operation thyristors 21, 22, which through current sensors 43, 44 and rectifiers 41, 42, transformers 39, 40 and converters 27, 28 are connected to dose sources 25. 25. In addition to current sensors 43, 44, logic gates 2I 47, 48 and HE 46 are introduced, which provide for blocking the dose source for the switching time of the main thyristors, which makes it possible to use rectifiers 41.42 for overvoltage protection life to capacitors 19, 20 and thyristors 1-6. 1 hp ff, 3 ill. about. VI 00 CA fui.l

Description

The invention relates to a converter technique used mainly in an autonomous traction electric drive with asynchronous short-circuited electric motors.

The aim of the invention is to increase the functional reliability of the inverter by detecting an emergency situation and preventing its development.

FIG. 1 is a schematic diagram of an inverter with control units; in fig. 2 - diagram of the protection unit; in fig. 3 is a DC / DC converter circuit.

The inverter contains main thyristors 1-6, distribution thyristors 7-12, and reverse controlled gates 13-18, forming bridges interconnected by alternating-current terminals. In addition, the main and reverse bridges are interconnected by direct current leads. Switching capacitors 19 and 20 and switching lockable control thyristors 21 and 22 form two successive chains connected between the opposite DC terminals of the main and distribution bridges. Charge diodes 23 and 24, respectively, are connected in parallel to the switching thyristors 21 and 22. Auxiliary power supply sources 25 and 26 of a constant voltage, in a particular case, is a common battery pack, supplying converters 27 and 28 of a constant voltage to a pulse.

As transducers 27 and 28, semiconductor DC circuit breakers, Royer type transducers and others can be used, implemented by well-known circuits. Dividing diode 29 is connected between the DC terminals of the distribution bridge. The main power supply 30 of the inverter is connected to the DC terminals of the main and reverse bridges. The magnitude of the voltage of source 30 may vary widely. Accepted that source 30 has inverse conductivity. The load of the inverter 31 (traction - asynchronous motor) is connected to the AC terminals of the main, reverse and distribution bridges. Frequency adjuster 32 is connected to the distributor 33 pulses and block 34 of delays. The outputs of the distributor 33 pulses are connected to the inputs of the formers 35 - 38 of the switching pulses of the respective distribution thyristors 7-12, switching thyristors 21 and 22, reverse controlled gates 13-18 and converters 27 and

28, main thyristors 1-6. The outputs of block 34 are connected to the inputs of the formers 36-38. The outputs of the formers 35-38 are connected to the control electrodes of the respective thyristors and to the control inputs of the converters 27 and 28.

The outputs of the converters 27 and 28 are connected to the primary windings of transformers 39 and 40, respectively, secondary

windings of which are connected to diode rectifiers 41 and 42, respectively. Transformers 39 and 40 provide galvanic separation of auxiliary and main circuits, as well as coordination

The supply voltage with the voltage of the sources 25 and 26. The diode rectifiers 41 and 42 are assembled in a bridge circuit and are connected to the switching capacitors 19 and 20 through the current level sensors 43 and 44, respectively. The logical elements HE 45 and 46 are connected to the outputs by their inputs a driver 37, which outputs pulse-on transducers 27 and 28, respectively. Logic outputs

HE 45 and 46 are connected to the first inputs of logic elements AND 47 and 48, respectively, the second inputs of which are connected to the outputs of sensors 43 and 44. The outputs of logic elements 14 47 and 48 are connected to the inputs of block 49 of protection. Elements 25, 27, 39, and 41 make up the sources of sublimation yes.

The inverter works as follows.

In the initial state, the circuit is de-energized, the voltage of the source 30 is zero, the capacitors are discharged, the control signals and the switching pulses of the semiconductor devices and devices are absent. When the control signal Uy is applied to

the input of the setter 32. the latter produces clock signals Gr, the frequency of which varies depending on the signal Uy. The alarm signal Ua is absent, the normal operation of the inverter flows, With the arrival of the signals GT, the distributor 33 outputs the signals DI, shifted relative to each other by the time T / b

and repeating with period T -, where f is the frequency of the inverter output voltage. Block 34 performs the function of delaying the GT signals sequentially for a time te, to, ta and outputs, respectively, the signals GB, Go, Cz, shown in FIG. 1 generalized GI signal. The delay t &, calculated from the beginning of the next interval T / 6, determines the instant of switching on of the corresponding switching thyristor. The te + to delay determines the instant at which the switching thyristor is disconnected. The delay te + to + ta determines the moment of switching on the respective main thyristor, the reverse controlled valve and the dosing converter.

The on state of the converters 27 and 28 is set by pulses F27, F28, respectively, the duration of which is determined by the constant time of the charge circuit of the switching capacitors, but not more than T / b - te - to -13. The inclusion of converters 27 and 28 provides for the charge of switching capacitors 19 and 20 from sources 25 and 26 to a predetermined voltage level, the polarity of which is shown in FIG. 1. In the process of charging capacitors 19 and 20, sensors 43 and 44, respectively, produce signals that are fed to the inputs of elements 47 and 48. Since there are no signals from the outputs of elements 45 and 46, respectively, at the other inputs of elements 47 and 48, elements 47 and 48 of the output no signals are generated and block 49 is inactive, signal UA is equal to logical O, signal UA is equal to logical 1. At the same time, setpoint 32 continues to function normally, and external circuits supply voltage from source 30 in accordance with signal UA on which the switching pulses are applied, gain the load current 31.

After the T / B interval has elapsed, the corresponding main thyristor, for example, thyristor 1, is switched. In this case, the starting pulse is removed from the control electrode of the thyristor 1, and a switching pulse is applied to the thyristor 7. When the delay IB has expired, the thyristor 21 and along the circuit: capacitor 19 - diode 29 - thyristor 7 - thyristor 1 - thyristor 21 - capacitor 19 begins to discharge the discharge current of capacitor 19. In thyristor 1, the discharge current flows counter to the load current and forces it out of thyristor 1, the latter de-energizes and begins to recover To energize the control properties. During a time to the partial discharge of the capacitor 19 to the load current occurs. After the delay t3, the thyristor 21 is switched off along its control circuit. In this case, the load current in the switched phase passes into the circuit: capacitor 20 - thyristor 7 - n load 31 - thyristor 2 - diode 24 - capacitor 20.

After the delay has elapsed, switching-on pulses are applied to the control electrodes of thyristors 4 and 13 and converter 28. At the same time, diode 24 and thyristor 7 are locked by the voltage of capacitor 20 applied to them in the opposite direction along the circuit, capacitor 20, diode 24 - valve 13 - thyristor 7 - capacitor 20. Valve 13 collects inductive load current and shunts thyristor 4 until inductive current drops to

zero, after which the thyristor 4 gains the active load current of the switched phase in the opposite direction. The inclusion of the converter 28 provides the discharge of the capacitor 20 to a predetermined level. The circuit is ready for the next commutation.

In the event of an emergency situation in the inverter, for example, due to non-switching off of the main or switching thyristor during the switching process, due to their loss of control properties, the switching capacitor is completely discharged and after that the load current reloads it. When the return voltage on the capacitor reaches

The level of the voltage drop across the diodes of the rectifier 41 or 42, the latter begin to conduct the load current, as a result of which the current level sensor 43 or 44 is triggered. The output signal is fed to one of the inputs of the element AND 47 or 48, respectively. At the same time, there is also a signal at the other input of the element And, because in the process of switching there is no impulse to turn on the corresponding converter 27 or 28

0 and the elements 45 or 46 generate output signals to the input elements And 47 and 48, respectively.

As a result, the element And is triggered and its output signal affects the block.

5 49 protection, which generates an alarm 1Gd, equal to logical 1, acting on setpoint 32 in such a way that it turns off and stops generating GT signals. It disappears the thyristor turn-on pulses, thereby preventing the occurrence of a through short circuit in the inverter.

In addition, the UA signal change on

5 logical O triggers the protection of the electric drive, which shuts down the power supply 30 or reduces its voltage to zero. As a result, the inverter is de-energized.

0 FIG. 2 shows a block diagram of the protection unit 49 for practical implementation, built on K 155 series microcircuits. Signals A7, 148 elements 47 and 48 are set on element 50 (the K 155 / 1L1 chip has four

5 element 2ILI), the output of which is connected to the S-input of the trigger 51 (K 155 TM2 chip - two triggers). The initial state of the trigger 51 is set either manually by pressing the button 52, or automatically by the device 53 restoring the protection circuit on the signal Uz associated with the R inputs of the trigger 51.

Block 49 (Fig, 2) works as follows.

By pressing the button 52 or the device 53, according to the signal Ouse, the trigger 51 is set to the initial state when the signal UA is absent (logical O), and the signal Od, respectively, occurs (logical 1). When an emergency situation occurs in the inverter, the occurrence of any of the signals (47. Lc translates the trigger 51 into the opposite state, in which the signal equals logical 1 and the signal UA - logical O. To restore the protection circuit after eliminating the accident in the inverter, it returns to the initial manual position by button 52 or automatic device 53.

The DC / DC converter circuit 27 is based on the well-known Royer circuit (FIG. 3). The diagram also shows auxiliary constant voltage source 25, transformer 39 v switching pulse elements F27 as applied to the Royer circuit. The converter contains transistors 54 and 55, diodes 56 and 57 are connected in parallel with each other. The transistor control circuit includes a saturating transformer 58, current limiting resistors 59–62 and diodes 63–66. The logical element HE 67 and amplifier 68 form a pulse conversion circuit switch on F27. Converter 28 is similar to that described.

In the absence of a signal Fa (logical O), there is a (logical 1) signal at the output of the element NE 67 (Fig. 3). This signal is amplified in amplifier 68 and appears at its output in the form of the voltage indicated in FIG. 3 polarities. Under the action of the output voltage of the amplifier 68, the amplifier 68 - the resistor 61 - the diode 63 - the diode 65 - the amplifier 68 and the amplifier 68 - the resistor 62 - the diode 64 - the diode 66 - the amplifier 68 flow currents, resulting in the transistors 54 and 55 being locked a voltage drop across the diodes 65 and 66, respectively, and Royer's converter is inactive.

With the onset of the on pulse F27, the signal F27 and the voltage at the output of the amplifier 68 disappear. At the same time, the voltages locking the transistors 54 and 55 are removed, and Royer’s converter begins to generate a low-voltage alternating voltage, which is then transformed and then used to dose the switching capacitor .

The introduction of current level sensors into the source circuit and the use of AND logic elements, NOT to block the source source for the switching time in

the inverter allows the use of a diode rectifier to protect the switching capacitors and thyristors from negative polarity overvoltages on the capacitor and high-frequency

natural oscillations in the switching circuit during an emergency situation in the inverter, and also allows detecting this situation in a timely manner and taking measures to eliminate it, thereby improving the reliability of the inverter and the associated electrical equipment, since the development of supercurrents in them is prevented.

20

Claims (2)

1.Inverter, containing main and reverse thyristor bridges interconnected, respectively, by AC and DC terminals, an expansion thyristor bridge, connected to the main and reverse bridges by AC terminals, switching lockable thyristors and switching capacitors, which form two sequential chains, connected between the DC terminals of the main and distribution bridges, recharge sources, separation diode connected between the DC terminals of the distribution box power bridge, charge diodes, connected by anti-parallel switching thyristors, frequency master, connected to the pulse distributor and pulse delay unit, 0 thyristor turn-on and turn-off pulse shapers and subtree sources, a protection unit and current level sensors, characterized in that, in order to increase reliability by detecting 5 of the emergency situation in the inverter and preventing its development, the sources of lasers are connected to the switching capacitors through current level sensors, the output of each of which is connected to one of 0 inputs of the input two-input logic elements AND, to the other input of which the output of the input logic elements NOT is respectively connected, the inputs of which, in turn, are respectively connected 5 to the outputs of pulse shapers switching on sources of charging, yes. and the outputs of the logic elements And are connected to the inputs of the protection unit. 2. The inverter according to Claim 1, characterized in that each charge source comprises a series-connected DC / DC converter of an auxiliary power source to a pulsed one controlled by a driver switching-on pulses of the charging source, separating matching transformer and diode rectifier. t & 7 "W chg UA silt 2