DE4438779A1 - Operation of DC link converter for induction machine if mains voltage drops temporarily - Google Patents

Abstract

The down-time of a DC link converter, comprising a mains rectifier 15, link inductances 16 and a machine inverter 17, all applied to an induction motor 20, is to be minimised if there is temporary mains voltage drop at the rectifier. To protect the semiconducting components of the machine inverter, firing of a cross-thyristor 22 bridging the link side output of the rectifier in series with a resistance 23 is undertaken by blocking the firing pulse for the rectifier. With a flux-oriented control structure containing a current, voltage, speed and load controllers, the load controller is excluded from the controller block. It receives a command variable for generator operation such that the necessary excitation current flows.

Description

The invention relates to a method according to the Preamble of claim 1. Such a method is known from DE 29 24 729 C2.

With a brief drop in the mains voltage a mains undervoltage, which also causes the complete failure of the Network, a period of time between 0 and be understood for about 10 seconds.

According to the procedure according to the above DE 29 24 729 C2 is at the beginning of the mains undervoltage complete DC link converter immediately switched off, d. H. there will be the regulation as well as the Ignition pulses from the mains converter and from the machine converter blocked. After a maximum of one Machine frequency period the current is reduced to zero amps, and the excitation of the asynchronous machine decreases in the de-energized State exponentially. At the beginning of the network return is a synchronization of the line converter on the line and of the machine converter to the possibly excited Asynchronous machine necessary, because otherwise mains voltage and Residual machine excitation can get into phase opposition, which cause overcurrents and overvoltages in the system can. That can easily become a backup or a Cause thyristor failure. To avoid this danger,  de-excitation in practice, despite the network return the asynchronous machine waited before network and Machine converter can be switched on again. After Precharge to ensure commutation in the As a rule, commutation existing in phase sequence erase circuit Rung capacitors in the machine power converter is with a "Runner search circuit" of the rotating rotor of the asynchronous machine "caught" (a catch circuit is for example in of DE 41 07 362 C2), then the asynchronous machine excited, then to the set speed setpoint worth speeding up. This results in a high one Delay time between network return and the Torque generation on the shaft of the asynchronous machine. The maximum de-excitation time of two-pole asynchronous machines from 100% to 10% of the nominal excitation when de-energized is about 15 s, the capacitor precharge time additional 0.2. . . 0.5 s. In addition, the fishing time comes between 1 . . . 5 s with an encoderless control of the machine (at In contrast, when using a speed sensor, the catch time is 0 s). There is also an excitation time for the asynchronous machine to be taken into account in the slip range of 1 s. At the An undervoltage can occur Downtime of around 21.5 s with an encoderless control or at least about 16.5 s with regulation Speed sensors occur.

A possibility of synchronization for a short time Power failure is shown in EP 142 808 A2. Here too the converter is completely blocked and one Electroless pause waited. With an additional The converter is then synchronized to the rotating asynchronous machine synchronized and the Magnetizing current over the control of the Maintain the machine converter. Here too must thus an interruption of the synchronization of approx. 200 ms to be accepted. In addition, there is also the Considerable effort for the synchronization circuit.

The invention has for its object a method of  specify the type mentioned at the beginning, by which after opening If there is a brief mains undervoltage, the downtime the asynchronous machine is minimized, i.e. a time-minimal one Torque build-up on the shaft of the asynchronous machine Network return is reached.

This object is achieved according to the invention by the in claim 1 marked features solved.

So there is through the conservation of electricity over that in Lei energy stored an uninterruptible Synchronization of the machine converter with the still excited asynchronous machine during a power failure approx. 10 s. When the power returns, the drive can to the set speed setpoint as quickly as possible be accelerated. The invention makes itself additionally take advantage of the knowledge that a rule structure for the converter-fed asynchronous machine anyway is available. Here is one with, for example, the DE 32 36 503 A1 known flow-oriented control structure, d. H. with standard control components, power conservation ensured. The regulatory effort to be used remains so low.

Advantageous embodiments of the method according to the Invention are characterized in the remaining claims.

The invention will now be described with reference to one in the drawing tion illustrated embodiment are explained. Show it

Fig. 1 shows the basic circuit diagram of a DC intermediate circuit converter with a flow-oriented control structure for using the method according to the invention and

Fig. 2 is a flow chart in the event of a network fault.

In Fig. 1, a DC intermediate circuit converter is shown, which consists of a line converter 15 connected to a (usually three-phase) network 14 , a DC link impressing intermediate circuit inductance 16 and a (usually also three-phase) asynchronous machine 20 feeding machine converter 17 . On the DC link side, the line converter 15 can be bridged by a protective branch comprising the series connection of a transverse thyristor 22 and a transverse resistor 23 . The querthyristor 22 is fired to protect the power semiconductor components of the machine converter 17 when, as a result of a mains disturbance, overvoltages occur in the machine converter 17 (not shown here), usually for phase sequence erasure via block diodes (also not shown) between the AC voltage connections of the machine converter 17 switching capacitors.

During normal operation of the asynchronous machine 20 , the DC link converter has an asynchronous machine flow-oriented control:

For this purpose, the actual values of the active current and the EMF of the asynchronous machine 20 are fed via a current converter 18 and a current converter 19 to an actual value detection device 2 , which provides a signal corresponding to the actual voltage value xe and a signal corresponding to the actual current value xil of the asynchronous machine 20 at its output.

The actual voltage value xe is compared with a voltage setpoint value we (to be described later), whereupon the resulting control deviation is fed to a voltage control amplifier 10 . Its output signal forms, together with a machine-dependent predetermined constant I0, a setpoint value wiµ for the magnetizing current of the asynchronous machine 20 . In an adder 5 , the geometric addition of an active current setpoint wil (to be described later) is carried out with the magnetizing current setpoint wiμ in accordance with the current vector diagram for an asynchronous machine. The resulting command variable for the machine current is compared with a current controlled variable xi, and the resulting control deviation becomes stronger with a current regulator 11 fed. The current control variable xi is provided by a current actual value detection device 7 , to which the intermediate circuit current detected via a current transformer 13 is fed on the input side. The output signal of the current control amplifier 11 is applied to a pulse-forming device 3 , from which the valves of the line converter 15 are controlled to provide the required intermediate circuit current. A voltage detection device 1 connected to the network 14 via a voltage converter 12 ensures a corresponding synchronization of the control pulses for the line converter 15 with the frequency of the network 14 .

For the determination of the frequency of the machine power converter 17 , two possibilities are shown in FIG. 1 corresponding to the switch position of the (symbolic) switch C, namely whether the shaft of the asynchronous machine 20 is equipped with a speed sensor 21 (for example a speedometer machine) providing the actual speed xnT or not.

In the event that the actual speed xnT is directly available by the speed sensor 21 , this signal is compared with a selected speed setpoint wn and fed to a speed control amplifier 9 . The active current setpoint wil supplied to the adder 5 is then present at the output of the speed control amplifier 9 . This active current setpoint wil is also compared with the active current actual value xil provided by the actual value detection device 2 and fed to a load control amplifier 8 , which, however, acts here as a (speed) compensation control amplifier. Its output signal is given as a frequency correction signal fcorr to a summing point, which additionally has a signal xf2, which is proportional to the slip frequency of the asynchronous machine 20 and is provided by a member 6 which forms the slip frequency f2 from the predetermined active current setpoint wil, and the actual speed value xnT (corresponding to the rotor frequency of the asynchronous machine 20 ) are activated. The three variables xf2, fkorr and xnT mentioned together form a signal xf1 corresponding to the stator frequency of the asynchronous machine. On the one hand, this signal xf1 corresponds to the voltage setpoint we mentioned above and, on the other hand, it is used in a pulse-forming element 4 to provide the control signals for the machine converter 17 .

In the event that the speed sensor 21 is not present (corresponding to the position of the switch C actually shown), the load control amplifier 8 actually works as such. Its output signal xfL then corresponds to the actual speed value for the summation point to form the signal xf1 proportional to the stator frequency and is also supplied to the speed control as a value xn.

The method according to the invention is with immediate power conservation with the help of this previously described standard flow-oriented control structure (speed control without and also with encoder) and the switching on of the protective branch by ignition of the Querthyri stors 22 without additional synchronization effort in the event of mains voltage interruptions or reductions between 0 and Realized 10 s. During the power failure, the controller supply (not shown here) is buffered for a maximum of 10.5 s.

At the beginning of the line voltage interruption detected by the line voltage detection device 1 , the following is carried out: the ignition pulses for the line converter 15 , the voltage control amplifier 10 , the speed control amplifier 9 and the current control amplifier 11 are blocked, and ignition pulses are switched to the cross-thyristor 22 . The actual value for the load control amplifier 8 is switched from the active current actual value xil to the motor current actual value xi _motor and the reference variable is switched from the active current setpoint wiμ to a current conservation value wStr (wStr current setpoint to maintain the machine excitation). The machine converter 17 is operated via the load control amplifier 8 , which is now the only one is still driven and its valves continue to fire. The machine frequency (stator frequency xf1) is set by the load control amplifier 8 so that the current required to maintain the machine excitation can flow.

When the network returns, the flow-oriented control described above is fully released again. At the beginning of the network return, an adjustable rush time for synchronizing the network to the line converter 15 or the rush time of a converter transformer (not shown here) of approximately 100 ms must first be waited for. Then the ignition pulses of the power converter 15 are released again, also the current control amplifier 11 , the voltage control amplifier 10 and the speed control amplifier 9 . The ignition pulses of the querthyristor 22 are blocked. The current in the protective branch is reduced and the transverse thyristor 22 is blocked by the positive components in the network-side intermediate circuit voltage.

The line converter 15 has thus again assumed the current specification. Due to the control difference between the speed setpoint wn and the speed actual value xn and the release of the speed control amplifier 9 , the actuating variable wil, which is valid again instead of the current maintenance setpoint wStr, specifies an acceleration torque in order to accelerate the asynchronous machine 20 again to the setpoint set.

FIG. 2 shows the time sequence for the previously explained blocking or control of individual components shown in FIG. 1 over time t. At time t1, the line voltage detection device 1 detects the line fault. The signal A then emitted interrupts the supply of the ignition pulses from the pulse formation device 3 to the mains converter 15 , bridges the control amplifiers 10 and 11 and permits the supply of an ignition pulse to the querthyristor 22nd At the same time, at the time t1, the speed control amplifier 9 is also bridged by the signal A output by the mains voltage detection device 1 and the current conservation setpoint wStr is specified for the load control. This state lasts a time Tu which allows the current conservation according to the invention up to a maximum of about 10 s.

After the mains return (and waiting for a first period of time corresponding to a rush time of 100 ms), the control amplifiers 9 , 10 and 11 are put into operation again by the signal A at time t2, the ignition pulses are fed back to the mains converter 15 and the ignition pulses are passed on to Querthyristor 22 locked.

The control signal wil is used instead of Conservation current setpoint wStr of the load control as Leadership variable.

If the time Tu of the mains voltage reduction lasts longer than approx. 10 s or the excitation of the ASM is less than approx. 10% of the nominal excitation, the load control amplifier 8 is also bridged via a signal D output by the mains voltage detection device 1 , and the ignition signals for the machine converter 17 also blocked.

Claims (4)

1.Method for operating a DC link converter formed from a line converter, DC link inductances and a machine converter and connected to an asynchronous machine in the event of a brief reduction in the line voltage applied to the line converter, with an ignition of one of the DC link output of the line converter in series with to protect the power semiconductor components of the machine converter a transverse resistance bridging querthyristor is carried out by blocking the ignition pulses for the mains converter and a regulator lock, characterized in that in the case of an asynchronous machine flow-oriented control structure containing a current, a voltage, a speed and a load regulator for the direct current intermediate circuit converter which determines the frequency of the Machine controller regulating load controller is excluded from the controller lock and it is a reference variable for the generator operation of the As ynchron machine is specified such that a current required to maintain the excitation of the asynchronous machine flows. 2. The method according to claim 1, characterized, that the load controller is a reference variable for current conservation is specified and its actual value from the active current actual value the motor current actual value is switched. 3. The method according to any one of claims 1 or 2, characterized, that when the mains voltage returns, initially after The ignition impulses for the Mains converter released the ignition pulses for the Querthyristor blocked and the current, voltage and the speed controller can be unlocked.   4. The method according to claim 3, characterized, that the time span 100 ms after the return of the full Mains voltage expires.