DE102021209437A1 - frequency converter - Google Patents

Abstract

Frequency converter (1), having: - at least three X capacitors (2, 3, 4), which are looped in between an associated phase line (5, 6, 7) and a common star point (8), - a Y capacitor (9 ) with a first connection (10) and a second connection (11), the Y-capacitor (9) being electrically connected with its first connection (10) to a reference potential, - an intermediate circuit capacitor (12) with a first connection (13 ) and a second connection (14), and- a double-contact relay (16) which has a first switching means (16a) and a second switching means (16b),- the first switching means (16a) of the double-contact relay (16) being connected between the common neutral point (8) the at least three X-capacitors (2, 3, 4) and the second connection (11) of the Y-capacitor (9) is looped in, and- the intermediate circuit capacitor (12) with its first connection (13) having a Intermediate circuit line (15) is electrically connected to which a negative Zwisc connection circuit potential (UZK-) is present, and the second switching means (16b) of the double contact relay (16) is looped in between an intermediate circuit line (17), on which a positive intermediate circuit potential (UZK+) is present, and the second connection (14) of the intermediate circuit capacitor (12). is; or wherein the second connection (14) of the intermediate circuit capacitor (12) is electrically connected to the intermediate circuit line (17) on which the positive intermediate circuit potential (UZK+) is present, and the second switching means (16b) of the double contact relay (16) is connected between the intermediate circuit line (15) at which the negative intermediate circuit potential (UZK-) is present and the first terminal (13) of the intermediate circuit capacitor (12) is looped in.

Description

The object of the invention is to provide a frequency converter with effective inrush current limitation.

The frequency converter conventionally has at least three X capacitors that are looped in between an associated phase line and a common neutral point.

The frequency converter also conventionally has a Y-capacitor with a first connection and a second connection, the Y-capacitor being electrically connected with its first connection to a reference potential, for example protective earth.

The frequency converter also conventionally has an intermediate circuit capacitor with a first connection and a second connection.

The frequency converter also has a conventional double-contact relay, which has a first switching means or a first switching contact and a second switching means or a second switching contact. The first switching means or the first switching contact of the double contact relay is looped in between the common star point of the at least three X capacitors and the second terminal of the Y capacitor.

The first connection of the intermediate circuit capacitor is electrically connected to an intermediate circuit line, on which a negative intermediate circuit potential is present, and the second switching means of the double-contact relay is looped in between an intermediate circuit line, on which a positive intermediate circuit potential is present, and the second terminal of the intermediate circuit capacitor. Alternatively, the intermediate circuit capacitor is electrically connected with its second connection to the intermediate circuit line on which the positive intermediate circuit potential is present, and the second switching means of the double contact relay is looped in between the intermediate circuit line on which the negative intermediate circuit potential is present and the first terminal of the intermediate circuit capacitor.

In one embodiment, the frequency converter has a first (pre-charging) resistor, the first resistor being connected in parallel with the first switching means of the double-contact relay. When the first switching means is open, the first resistor is used to precharge the Y capacitor. After the pre-charging has taken place, the first switching means is closed and the first resistor is consequently bridged.

In one embodiment, the frequency converter has a second (pre-charging) resistor, the second resistor being connected in parallel with the second switching means of the double-contact relay. When the second switching means is open, the second resistor serves to precharge the intermediate circuit capacitor. After the pre-charging has taken place, the second switching means is closed and the second resistor is consequently bridged.

In one embodiment, the first switching means of the double contact relay and the second switching means of the double contact relay are controlled together and therefore change their respective switching state synchronously or simultaneously.

In one embodiment, the frequency converter also has: a first phase connection for connecting a first phase of a multi-phase, in particular three-phase, three-phase network, a second phase connection for connecting a second phase of the multi-phase three-phase network, and a third phase connection for connecting a third phase of the multi-phase three-phase network, wherein a first X-capacitor of the at least three X-capacitors is looped in between the first phase connection and the common neutral point, wherein a second X-capacitor of the at least three X-capacitors is looped in between the second phase connection and the common neutral point, and wherein a third X-capacitor of at least three X-capacitors is looped between the third phase connection and the common star point.

In one embodiment, the frequency converter further includes a current-compensated coil, comprising: a first sub-coil electrically connected to the first phase connection, a second sub-coil electrically connected to the second phase connection, and a third sub-coil , which is electrically connected to the third phase connection.

• 1 ein schematisches Schaltbild eines Frequenzumrichters mit einer erfindungsgemäßen Einschaltstrombegrenzung.

The invention is described in detail below with reference to the drawing. This shows:

• 1 a schematic circuit diagram of a frequency converter with an inrush current limitation according to the invention.

1 shows a schematic circuit diagram of a frequency converter 1.

The frequency converter 1 has X-capacitors 2, 3, 4, which are looped in between an associated phase line 5, 6 or 7 and a common star point 8. The frequency converter 1 optionally has further X-Kon on the input side capacitors 25, 26, 27, which are looped in between an associated phase line 5, 6 or 7 and another common neutral point.

The frequency converter 1 also has a Y-capacitor 9 with a first connection 10 and a second connection 11, the Y-capacitor 9 being electrically connected with its first connection 10 to a reference potential in the form of protective earth (PE).

The frequency converter 1 also has an intermediate circuit capacitor 12 with a first connection 13 and a second connection 14, the intermediate circuit capacitor 12 being electrically connected with its first connection 13 to an intermediate circuit line 15 at which a negative intermediate circuit potential UZK− is present.

The frequency converter 1 also has a double contact relay 16, which has a first switching element 16a and a second switching element 16b, the first switching element 16a being connected between the common star point 8 of the at least three X capacitors 2, 3, 4 and the second connection 11 of the Y capacitor 9 is looped in, and the second switching means 16b is looped in between an intermediate circuit line 17, on which a positive intermediate circuit potential UZK+ is present, and the second terminal 14 of the intermediate circuit capacitor 12. Unlike in 1 shown, the first switching means 16a can alternatively also be looped in between the intermediate circuit line 15 and the first terminal 13 of the intermediate circuit capacitor 12, with the second terminal 14 of the intermediate circuit capacitor 12 being connected to the intermediate circuit line 17 in this case.

The frequency converter 1 also has a first resistor 18, the first resistor 18 being connected in parallel with the first switching means 16a of the double-contact relay 16.

The frequency converter 1 also has a second resistor 19, the second resistor 19 being connected in parallel with the second switching means 16b of the double-contact relay 16.

The first switching means 16a and the second switching means 16b are controlled together, i.e. opened at the same time in the pre-charging mode and closed after the pre-charging mode.

The frequency converter 1 also has: a first phase connection 20 for connecting a first phase L1 of a three-phase network 23, a second phase connection 21 for connecting a second phase L2 of the three-phase network 23, and a third phase connection 22 for connecting a third phase L3 of the three-phase network 23. The X-capacitor 2 is looped between the first phase connection 20 and the common neutral point 8, the X-capacitor 3 is looped between the second phase connection 21 and the common neutral point 8 and the X-capacitor 4 is looped between the third phase connection 22 and looped into the common star point 8.

The frequency converter 1 further has a current-compensated coil, having a first sub-coil 24a, which is electrically connected to the first phase connection 20, a second sub-coil 24b, which is electrically connected to the second phase connection 21, and a third sub-coil Coil 24c electrically connected to the third phase terminal 22.

The frequency converter 1 also has varistors 28, 29 and 30 in the wiring shown.

By means of the invention, the switch-on leakage current of the Y-capacitor 9 of the 3-phase frequency converter 1 is reduced without additional costs in such a way that operation on a standard fault-current circuit breaker is possible.

The Y-capacitor 9 at the mains input causes the highest leakage current in the three-phase frequency converter 1 when the mains is switched on. According to the invention, the relay contact or the switching means 16a and the relay contact or the switching means 16b are each switched off or opened when the mains is switched on, so that the leakage current of the Y capacitor 9 is limited by the high-impedance resistor 18 and the pre-charging current of the intermediate circuit capacitor 12 by the high-impedance Resistance 19 is limited. This prevents a residual current circuit breaker from tripping even if the 3 mains phases L1, L2 and L3 are not switched on synchronously. After the simultaneous pre-charging of the Y-capacitor 9 and the intermediate circuit capacitor 12, both switching contacts 16a and 16b are closed at the same time and the pre-charging resistors 18 and 19 connected in parallel are thus bridged.

In order not to incur additional costs, a switching means or switching contact 16a of double-contact relay 16 is used to switch Y-capacitor 9, with the further switching means or further switching contact 16b of double-contact relay 16 being used to precharge or switch intermediate circuit capacitor 12 becomes. Thus, the double contact relay 16 fulfills a double function as a single relay, namely the precharging of the intermediate circuit on the one hand and the precharging of the Y capacitor 9 on the other hand.

According to the invention, the second switching means or the second switching contact 16a is connected to the star point 8 of the X capacitors 2, 3, 4. As a result, no high isolation voltage of the relay 16 is required. If the switching contact 16a were at PE potential, the insulation voltage between the two contacts would have to be 5 kV so that no flashover occurs during an insulation test.

Claims (6)

Frequency converter (1), comprising: - at least three X-capacitors (2, 3, 4), which are looped in between an associated phase line (5, 6, 7) and a common neutral point (8), - a Y-capacitor (9) with a first connection (10) and a second connection (11), the Y-capacitor (9) being electrically connected with its first connection (10) to a reference potential, - an intermediate circuit capacitor (12) with a first connection (13) and a second connection (14), and - a double contact relay (16) having a first switching means (16a) and a second switching means (16b), - the first switching means (16a) of the double contact relay (16) being looped in between the common star point (8) of the at least three X capacitors (2, 3, 4) and the second connection (11) of the Y capacitor (9), and - wherein the first connection (13) of the intermediate circuit capacitor (12) is electrically connected to an intermediate circuit line (15) on which a negative intermediate circuit potential (UZK-) is present, and the second switching means (16b) of the double contact relay (16) is connected between a Intermediate circuit line (17) on which a positive intermediate circuit potential (UZK+) is present and the second connection (14) of the intermediate circuit capacitor (12) is looped in; or wherein the second connection (14) of the intermediate circuit capacitor (12) is electrically connected to the intermediate circuit line (17) on which the positive intermediate circuit potential (UZK+) is present, and the second switching means (16b) of the double contact relay (16) is connected between the intermediate circuit line (15) at which the negative intermediate circuit potential (UZK-) is present and the first terminal (13) of the intermediate circuit capacitor (12) is looped in. Frequency converter (1) after claim 1 , characterized in that - the frequency converter (1) has a first resistor (18), the first resistor (18) being connected in parallel with the first switching means (16a) of the double contact relay (16). Frequency converter (1) according to one of the preceding claims, characterized in that - the frequency converter (1) has a second resistor (19), the second resistor (19) being connected in parallel with the second switching means (16b) of the double contact relay (16). Frequency converter (1) according to one of the preceding claims, characterized in that - the first switching means (16a) of the double contact relay (16) and the second switching means (16b) of the double contact relay (16) are controlled together. Frequency converter (1) according to one of the preceding claims, characterized in that the frequency converter (1) further has: - a first phase connection (20) for connecting a first phase (L1) of a polyphase three-phase network (23), a second phase connection (21) for connecting a second phase (L2) of the polyphase three-phase network (23), and a third phase connection (22) for connecting a third phase (L3) of the polyphase three-phase network (23), - wherein a first X-capacitor (2) of the at least three X capacitors (2, 3, 4) are looped in between the first phase connection (20) and the common star point (8), - a second X capacitor (3) of the at least three X capacitors (2, 3, 4) is looped in between the second phase connection (21) and the common star point (8), and - wherein a third X-capacitor (4) of the at least three X-capacitors (2, 3, 4) is connected between the third phase connection (22) and the common star point (8) is looped in. Frequency converter (1) after claim 5 , characterized in that the frequency converter (1) further comprises: - a current-compensated coil, comprising: - a first partial coil (24a) which is electrically connected to the first phase connection (20), - a second partial coil (24b ) which is electrically connected to the second phase connection (21), and - a third sub-coil (24c) which is electrically connected to the third phase connection (22).

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