DE2739306C2 - Converter arrangement - Google Patents

Description

The invention relates to a converter with a line-commutated rectifier arrangement and a DC link with impressed direct current as well as a self-guided in inverter arrangement with a commutation device made up of capacitors and diodes to the phase sequence deletion and a variable speed connected to the three-phase connections of the inverter arrangement , .synchronous machine.

Such converters are used to power induction machines, in particular asynchronous machines with squirrel cage rotors and are in particular from the ETZ-A vol. 96 (1975) H. 11, page 520 and f. And from industrial electronics + electronics 20 (1975) 5. pp. 73-77, known. The feed of this converter is for example made up of a line-commutated converter and a smoothing choke and acts as a power source. The smoothing choke is arranged in the DC link between the rectifier and the inverter. The inverter is powered by an input. shaped direct current. Through the in the DC link built-in choke, the two circuits are almost decoupled. In which Like the rectifier, the inverter is a three-phase bridge circuit. Each of the two bridge halves of the inverter has a commutation device. The commutation device is in both bridge halves between the thyristors and the three-phase current connections Installed. Each of the commutation devices is constructed so that two are connected in series Capacitors connect the three branches of one half of the bridge with each other. These two capacitors a third capacitor is connected in parallel, which is the first and the third branch of the bridge half connects with each other. In front of the three-phase current connections of the inverter there is a bridge half in each branch a diode built in.

With such a converter is effected that a three-phase current of a certain frequency in a Three-phase current of a different frequency is converted. The converter works so that the three-phase current first converted into a direct current and this then working as a self-commutated inverter Converter is converted back into three-phase current.

This conversion of a three-phase current of a certain frequency into a three-phase current with a different frequency is almost always used when the output inverter works with forced commutation. After the first conversion of the input three-phase current into a direct current, a smoothing device can be achieved that the two three-phase systems work largely decoupled. This is how it is possible to still achieve output frequencies that are significantly higher than 50 Hz. A frequency limit is set by the release time of the thyristors. As mentioned earlier, the inverter assembly of the converter controlled by a commutation device. When operating one of the three-phase current connections The three-phase asynchronous machine connected to this inverter arrangement is set Voltage on the commutation capacitors of the commutation device from the following proportions together:

a) a part of the machine voltage,

b) a load current-dependent upper charge part.

In order not to limit the voltage of the thyristors

: ·, The capacitors of the commutation device must have a certain minimum size. The maximum value of the communication capacity is, however, determined by the necessary commutability even at the highest frequency.

This capacity, which keeps dangerous voltage peaks away from the thyristors, also reduces the maximum operating frequency.
The invention has for its object to be a

there are converters of the type mentioned at the beginning with increased commutation capacity, bypassing dangerous voltage peaks occurring at the thyristors and a lowering of the maximum To create operating frequency.

The solution to the problem is marked by dadu.-χΊ, that the inverter arrangement consists of at least two or more partial inverters connected in parallel is constructed, which are connected to one another via the DC connections and the three-phase connections are, and that with low output currents only some of the parallel-connected partial inverters are in operation is.

The division of an inverter into parallel-connected Partial inverter as such is known (DE-AS 14 88 096. DE-AS 23 48 157). There are, however all partial voltages to form a Gc-dmia output voltage necessary or the inverters must always be controlled in a coordinated manner.

The division of the arrangement according to the invention practically effects a division of the effective ones Commutation capacity. In the case of small currents, i.e. if the commutation takes a relatively long time, it is through Current conduction of only one partial inverter reduces the effective commutation capacity, where occurs through an acceleration of the commutation process and thus the upper frequency limit of the Inverter can be raised.

The invention is explained in more detail below with reference to a drawing:

ft'j Fig. 1 shows the converter according to the invention. This is in. essentially from a line-commutated rectifier arrangement 2 and an inverter arrangement 3 built. The inverter arrangement 3

is made up of at least two or more partial inverters 4 and 5 arranged in parallel with one another assembled The rectifier arrangement 2 is designed as a bridge circuit. It has three bridge branches with two thyristors each connected in series 6 and 7, 8 and 9, 10 and 11. Each center branch of the three bridge branches is via an inductance 12, 13,

14 connected to the rotary connections R, S, T. The rectifier arrangement 2 is connected to the inverter arrangement 3 via a direct current intermediate circuit 15. A choke coil 90 is built into the direct current intermediate circuit 15. The throttle 90 serves as an energy store and decouples the two circuits. The rectifier arrangement 2 acts together with the smoothing choke 90 as a current source which supplies the impressed direct current Id. The inverter arrangement 3 is connected to the direct current intermediate circuit via the direct current connections 151 and 152

15 connected. As already mentioned, the alternating right-hand arrangement 3 is constructed from two partial inverters 4 and 5 connected in parallel. Jf-.ier of the two partial inverters 4 and 5 is designed as a bridge circuit. They each have three bridge branches with two series-connected thyristors 16 and 17, 18 and 19, 20 and 21 or 22 and 23, 24 and 25, 26 and 27 uf. The partial inverters 4 and 5 are connected to one another and to the variable-speed asynchronous machine 80 fed by the converter via their three-phase connections R 2. 52 and 7 "2 (each bridge branch half 40 and 41 or 42 and 43 of the two partial inverters 4 and 5 has a Commutation device 28 and 29 or 30 and 31. The commutation device 28, 29, 30, 31 is in the bridge branch half 40, 41, 42, 43 between the thyristors 16, 18, 20 and 17, 19, 21 and 22, respectively. 24, 26 or 23, 25, 27 and the three-phase connections R 2. 52. T2 of the partial inverters 4 and 5. The commutation device 28, 29, 30, 31 is constructed as follows and ο in the bridge branches 40, 41, 42 and 43 switched on that two capacitors 32 and 33, 34 and 35 or 36 and 37, 38 and 39 connected in series connect the three branches of the bridge half 40, 41, 42, 43. The two capacitors 32 and 33, 34 and 35, 36 and 37. 38 and 39 is a third capacitor 50, 51, 52, 53 parallel ge sct. which connects the first and third branches of the bridge halves 40, 41, 42, 43. In addition, each commutation device 28, 29, 30 and 31 has three didoes 60, 61, 62 and 63, 64, 65 and 66, 67, 68 and 69, 70, 71, respectively. In each case one of the three diodes is built into a branch of the bridge halves 40, 41, 42 and 43 between the capacitors and the three-phase connections R2.S2, 7 "2.

The converter according to the invention has the following mode of operation:

In the frequency range up to the type point of the three-phase asynchronous machine, all partial changes ricnter 4 and 5 are in function. To explain the mode of operation, it is now assumed that at time f 0 only thyristors 16 and 21 or 22 and 27 of partial inverters 4 and 5 are live. The other thyristors are blocked, ie not carrying current. In this case, a component Id 1 of the impressed direct current Id at point 151 flows into Hen thyristor 16 and a second component Id2 of this impressed direct current Id flows into thyristor 22. Components id 1 and / c / 2 of the divided direct current / c / are same size.

The current is divided by the volume resistances of the semiconductors. Balancing resistors can possibly also be used here. The current IdI or Id2 flows from the thyristor 16 or 22 via the diode 60 or 66 and the three-phase connection R 2 into the ^; Asynchronous machine 80. From there the current flows from phase 72 of asynchronous machine 80 via diodes 65 or 71 and thyristors 21 and 27 back to point 152 of intermediate circuit 15. The voltages LJC32 and UC50 or £ / C36 and UC52 the commutation capacitors 32 and 50 or 36 and 52 of the two commutation devices 28 and 30 should be greater than the peak values of the induced machine voltage. At time 1, 1, the thyristors are fired 18 and 24th The imprinted

^{: 5} direct current Id or its components / t / 1 and Id2 commutate after a very short time from the thyristors 16 and 22 to the thyristors 18 and 24, since the voltages of the commutation capacitors 32 and 50 or 36 and 52 for the thyristor 16 or 22 act as reverse voltage. This commutation time is generally negligible for the commutation process at low frequencies. The impressed direct current Id and its components ld I and / t / 2 fl-food after the commutation from the point 151 of the DC intermediate circuit 15 through the thyristor 18 and 24 and the commutating capacitor 32 or 26 and the diode 60 or 66 to the phase R 2. The return flow of the current via the machine winding? N to point 152 of the intermediate circuit corresponds to that already

^{) n} course described above. The diode 61 or 67 of the commutation device 28 or 30 cannot yet become conductive at this point in time, since both the voltage of the capacitor 32 or 36 and the voltages of the capacitors 33 and 50 or 37 and

^r '52 of the commutation device 28 or 30 and the instantaneous value L /.>.%.' of the linked voltage of the asynchronous machine are still present in the reverse direction at this point in time.

The diode 62 or 68 also remains blocked.

^{4 (1} On the basis of this voltage configuration, the commutation capacitors 32, 33 and 50 or 36, 37 and 52 of the two commutation devices 28 and 30 are charged or discharged by the components Id 1 and / t / 2 of the impressed current Wum · or At time / 2, the capacitor 32 or 36 is discharged. The diodes 61 and 62 or 67 and 68 remain blocked due to the machine and capacitor voltages if the commutation circuits are designed accordingly

' ⁿ commutation devices 28 and 30 are therefore further charged or recharged by the currents Id 1 and / c / 2. The current load in the asynchronous machine is not changed by the first commutation step. At time / 3 the tension is reversed

polarity at the diode 61 or 67 um. the diode becomes conductive. The commutation currents Ik 1 and Ik 2 forced in the commutation oscillating circuits are directed in the opposite direction to the impressed St: jmen IdI and Id2 in the diodes 60 and 66 of the two commutation devices 28 and 30. The resulting currents IRi = Idi - Iki and IR2 - Id ?. - Ik2 in diodes 60 and 66 and in phase R 2 of the asynchronous machine are therefore reduced, while the current in Phav S 2 is built up. The Komniut ¹ : -

^The step is ended when Ik 1 = IdX and / c / 2 = / Ar 2. The impressed current is thus commutated from phase /? 2 to phase 52 of the asynchronous machine. The capacitors 33 and 37 of the two

5 6

Commutation devices 28 and 30 are by the way, as it is above for the two bridge halves 40 and

Commutation process described so charged 42 was described. All commutation steps

been that when the thyristors 20 and 26 are triggered, the partial changes that are in operation take place

Thyristors 18 and 24 are deleted. judges at the same time.

With this method, the commutation> As already mentioned above, this mode of operation applies

therefore at least two steps per commutation of the converter only for a frequency range up to

establishment on. The first step consists in the um-type point of the three-phase asynchronous machine. in the

or charging of the commutation capacitors with partial load operation at high frequencies persists

the direct currents Id \ and W2 The second step is to block the ignition pulses of the other partial inverters

due to the oscillation of the commutation oscillation n> ter only one in operation. When operating only one

circles knotted / calibrated. Inverter, the commutation of the same

The commutation in the bridge branches 41 and 43 bcn as well as the commutation described above

the two partial inverters 4 and 5 takes place in the same of all partial inverters.

1 sheet of drawings

Claims (1)

Claim: Converter with a network-controlled rectifier arrangement and a direct current intermediate circuit with impressed direct current as well as a self-commutated inverter arrangement with a commutation device composed of capacitors and diodes for phase sequence deletion and a variable-speed asynchronous machine connected to the three-phase current connections of the inverter arrangement, characterized in that the inverter arrangement (3) consists of at least two or more parallel-connected partial inverters (4 and 5), which are connected to one another via the direct current connections (151 and 152) and the three-phase connections (R 2, 52, Tl) , and that with low output currents only some of the parallel connected partial inverters (4, 5) is in operation.