WO2016091281A1

WO2016091281A1 - Device for power limitation while switching a load, circuit arrangement, and method

Info

Publication number: WO2016091281A1
Application number: PCT/EP2014/076915
Authority: WO
Inventors: Markus Pfeifer; Yannick Fotsing; Karsten Handt
Original assignee: Siemens Aktiengesellschaft
Priority date: 2014-12-08
Filing date: 2014-12-08
Publication date: 2016-06-16

Abstract

The invention relates to a device (1) for limiting an alternating current and/or an alternating voltage while switching a load (M), wherein the device (1) has a switching unit for switching the alternating voltage and/or the alternating current in a switching phase, and a bridging means (4) for bridging the switching unit in an operating phase (14) of the load (M). The switching unit comprises a semiconductor switching unit (2) that can be bi-directionally blocked, which is configured to switch off the alternating voltage and/or the alternating current independently of a currently existing phase angle of the alternating voltage and/or the alternating current. The device (1) has a protective circuit arrangement (3) for bridging the bidirectionally blockable semiconductor switching unit (2) upon a predetermined surge in the switching phase.

Description

description

Device for power limitation when switching a load, circuit arrangement and method

The invention relates to a device for limiting an alternating current and / or an alternating voltage when switching a load, wherein the device comprises a switching device for switching the alternating voltage and / or the alternating current in a switching phase and a bridging device for bridging the switching device in an operating phase. The invention also relates to a circuit arrangement and a method.

It is already known from the prior art to limit an electrical power when switching on or off an electrical device, or in general an electrical load. For this purpose, the electrical voltage and / or the electric current can be limited. This is also referred to as a soft start or as a soft stop.

For soft start or soft discharge of loads, such as motors, so-called soft starters are usually used by means of which a targeted start-up current reduction and a continuous increase in torque can be realized.

Such soft starters usually comprise two antiparallel-connected thyristors or a triac. By a

Phase control of both thyristors, the motor voltage and / or a motor current is slowly raised within an adjustable start-up time and thus regulated the starting current and the torque. After a zero crossing of the alternating voltage or the alternating current, the triac does not conduct the starting current until the triac receives a renewed ignition pulse. From this point on, the load, for example the motor, is supplied with the alternating current and / or the alternating voltage until the next zero crossing. from that However, there is the disadvantage that the alternating current or the starting current can be switched off only at a zero crossing of the alternating current and / or the alternating voltage. In the case of existing short circuits, for example due to cable damage or due to a short-circuit in the motor, all the components of the circuit arrangement, for example the thyristors, the motor, the semiconductor relays and other electronic components, must conduct the short-circuit current until the next zero crossing. In order to limit a short-circuit current, according to the prior art, oversized thyristors are used or special fuses are connected upstream.

During an operating phase of the load, the thyristors are usually connected by means of semiconductor relays or by-pass

Contacts bridged. In order to end the operating phase of the load, ie to turn off the load, the semiconductor relays or the bypass contacts are opened. The resulting arcing can lead to wear of the relay contacts.

It is an object of the present invention to provide a simple solution by means of which a load can be safely and reliably switched.

This object is achieved by a device, a circuit arrangement and a method having the features according to the respective independent claims. Advantageous embodiments of the invention are the subject of the dependent claims, the description and the figures.

An inventive device is used to limit an alternating current and / or an alternating voltage when switching a load. The device has a switching device for switching the alternating voltage and / or the alternating current in a switching phase and a bridging device for bridging the switching device in an operating phase. There- In addition, the switching device comprises a bidirectionally barrier-capable semiconductor switching device, which is designed to switch off the AC voltage and / or the AC independently of a current phase angle of the AC voltage and / or the AC current. In addition, the device has a protective circuit device for bridging the bidirectionally blocking-capable semiconductor switching device from a predetermined overvoltage in the switching phase.

About the device, which is also referred to below as a solid-state switch, so a load with, for example, provided by an energy source, electrical energy can be supplied.

In a switching phase, so when switching on and / or off the load, the bidirectional blocking semiconductor switching device can be operated pulsed, whereby the AC or starting current supplied to the load can be switched on and off at any time. The bidirectionally breakable semiconductor switching device can switch on and off the load current independently of a current phase of the alternating current and / or the alternating voltage. This means, in particular, that the bidirectionally non-conductive semiconductor switching device is designed to provide a

Alternating current and / or an alternating voltage, in contrast to a triac, also switch off outside of a zero crossing of the alternating current and / or the alternating voltage. Thus, for example, in the case of a short circuit, an energy flow to the load can be interrupted immediately by immediate opening of the bidirectionally inhibitable semiconductor switching device.

In an operating phase of the load, the device or the solid-state switch can be operated in the continuous phase or in continuous operation. The bidirectional lockable is

Semiconductor switching device bridged by the bridging device. The bridging device can be used as a mechanical switch, for example as a power switch. lais, be executed. As a result, a load current can be conducted via the bridging device past the bidirectionally blocking-capable semiconductor switching device to the load. A designed as a mechanical switch bridging device generally has lower Kontaktwider states as a semiconductor switching device. This results in the advantage that in continuous operation of the Vorrichtun the power loss in the bidirectional blocking semiconductor switching device is reduced and thus heating of the solid-state switch is reduced.

Said protective circuit device is designed to bridge the bidirectionally barrier-capable semiconductor switching device from a predetermined overvoltage, which can lead to destruction or damage to the bidirectionally blocking-capable semiconductor switching device. Such overvoltages, which are also referred to as voltage peaks, can occur, for example, when switching off inductive loads.

In order to control the bidirectionally breakable semiconductor switching device for opening and / or closing, for example, a control device may be provided.

Thus, a safe switching on and / or off a load can be realized by means of the device according to the invention in an advantageous manner. The fact that the bidirectionally barrier-capable semiconductor switching device is designed to switch off a short circuit immediately, the device is designed particularly short-circuit proof.

Particularly preferably, the bidirectionally barrier-capable semiconductor switching device has an antiserial circuit of two IGBTs. An IGBT (insulated gate bipolar transistor) is a bipolar transistor with an insulated control electrode, a so-called gate electrode, and combines the advantages of a bipolar transistor, namely a good on-state behavior and a high blocking voltage, with the advantages of a bipolar transistor Field effect transistor, namely the almost powerless control. Due to the antiserial circuit of the IGBTs, the bidirectionally non-conductive semiconductor switching device is designed for switching alternating currents and / or alternating voltages. Since IGBTs are operated pulsed, a switching on and off of the IGBTs is possible at any time, that is independent of a current phase angle of the alternating current and / or the alternating voltage and thus closing and opening the bidirectional Sperrfähigen Halbleiterschaltein- direction possible.

According to an advantageous embodiment of the invention, the bidirectionally breakable semiconductor switching device on an anti-parallel connection of two backward blocking IGBTs. Backward blocking IGBTs, so-called RB-IGBTs, are capable of blocking in both a forward direction and a reverse direction. Thus, the semiconductor switching device is advantageously designed to block alternating current. In addition, it is possible to dispense with a freewheeling diode, which is necessary in the case of non-backward blocking IGBTs for realizing a reverse blocking capability. This leads above all to a reduction of the switching losses. The device is thus particularly low loss and designed to save on components.

It can be provided that the bidirectionally blocking-capable semiconductor switching device has an antiserial circuit of two power MOSFETs. Power MOSFETs, also referred to as DMOS field effect transistors, have a vertical construction, unlike MOSFETs used in integrated circuits, for example, and are designed to conduct and block large currents and voltages. Power MOSFETs have particularly fast switching times.

It can also be provided that the bidirectionally blocking-capable semiconductor switching device has an antiserial circuit of two junction field-effect transistors. barrier layer Field effect transistors or JFETs (Junction Field Effect Transistor) are particularly easy to manufacture.

A preferred embodiment provides that the said protective circuit device is designed to bridge the bidirectionally barrier-capable semiconductor switching device as of a breakdown voltage of the bidirectionally blocking-capable semiconductor switching device as the predetermined overvoltage. While a blocking voltage is present across the bidirectionally blocking-capable semiconductor switching device, the bidirectionally blocking-capable semiconductor switching device is in a blocking operation and can block a load current from the energy source to the load. In particular, only a small reverse current flows.

If the said overvoltage, at which the protective circuit device turns on, corresponds to the breakdown voltage of the bidirectionally blocking-capable semiconductor switching device or exceeds the breakdown voltage, a so-called breakdown can not occur in which the

Reverse current increases abruptly, although the bidirectional blocking semiconductor switching device is operated in the blocking mode. For the protective circuit device is designed to bridge the bidirectionally barrier-capable Halbleiterschaltein- direction by passing, for example, caused by the overvoltage overcurrent of the bidirectional blocking semiconductor switching device.

For this purpose, the protective circuit device preferably has a varistor for this purpose. A varistor or a VDR (Voltage Dependent

Resistor) is a voltage-dependent resistor whose dif ferential resistance abruptly decreases from a certain threshold voltage. The varistor is in particular dimensioned such that its differential resistance is abruptly smaller than the predetermined overvoltage as the threshold voltage. As soon as the predetermined overvoltage and thus the threshold voltage at the varis connected in parallel with the bidirectionally inhibitable semiconductor switching device gate is applied, a current flow is passed to the bidirectional blocking semiconductor switching device over the varistor. Varistors have short response times and can also limit very short-term overvoltage nondestructively.

It proves to be advantageous if the protective circuit device has an RC element. An RC element comprises a series connection of a resistor and a capacitor. A protective circuit with an RC element is particularly well suited for alternating voltages and / or alternating currents, since a damping of high-frequency voltage peaks can be effected bidirectionally by the capacitor.

It can be provided that the protective circuit device has a gas absorber. Gas ablators are gas discharge tubes which are used as surge arresters. The Gasabieiter, which is connected in parallel to the bidirectional blocking semiconductor switching device, behaves below an ignition voltage, which is adapted in the context of the invention, in particular to the predetermined overvoltage, such as an insulator and thus does not affect the bidirectional blocking semiconductor switching device in an advantageous manner. As soon as the predetermined overvoltage is applied to the gas absorber, it ignites and passes an overcurrent caused by the overvoltage almost completely past the bidirectionally inhibitable semiconductor switching device.

The described protective circuit devices are in particular self-disconnecting, e.g. lock them if the voltage drops below the overvoltage.

The invention also includes a circuit arrangement with a load, a control device and at least one device according to the invention. For example, a polyphase electrical line may be provided and a device of the type described may be present in each phase. The Load is electrically connected to the at least one device and the control device is designed to control the respective bidirectionally barrier-capable semiconductor switching device of the at least one device and / or the respective bridging device of the device for opening and / or closing. The load can be an inductive, an ohmic or a capacitive load. An inductive load may be, for example, a three-phase asynchronous machine which can be supplied with three-phase alternating current or three-phase alternating current via three phases or three conductors, wherein each of the three phases can each have a device according to the invention.

In addition, the invention comprises a method for limiting an alternating current and / or an alternating voltage when switching a load. When the load is switched on, a bidirectionally inhibitable semiconductor switching device is closed and then bridged by a bridging device and thus the load is operated in an operating phase. Alternatively or additionally, when the load is switched off, the bridging device is bridged by the bidirectionally blocking-capable semiconductor switching device, then the bridging device is opened to terminate the operating phase and the bidirectionally blocking-capable semiconductor switching device is blocked for momentary-phase angle-independent blocking of the alternating current and / or the alternating voltage.

When the load is switched on, the bidirectionally barrier-capable semiconductor switching device can, for example, be operated pulsed, so that an alternating current and / or an alternating voltage is limited when the load is switched on. If, for example, a short circuit occurs or occurs during the switching on of the load, the bidirectionally breakable semiconductor switching device can block the alternating current and / or the alternating voltage independently of a momentary phase, ie from a current phase angle of the alternating current and / or the alternating voltage. Once the load with a predetermined operating voltage and / or a predetermined operating current is supplied, the load can be operated in the operating phase. In the operating phase, the bidirectionally barrier-capable semiconductor switching device is bridged by the bridging device, which may be designed, for example, as a mechanical switch. For this purpose, for example, a mechanical switch connected in parallel with the bidirectionally inhibitable semiconductor switching device can be closed as a bridging device. After closing the bridging device, the bidirectionally disabling semiconductor switching device can be opened, so that the alternating current and / or the alternating voltage is conducted to the load only via the bridging device.

To end the operating phase, the bridging device is bridged by the bidirectionally blocking-capable semiconductor switching device. In this case, first the bidirectionally barrier-capable semiconductor switching device is closed, while the bridging device is still closed. After closing the bidirectionally blocking-capable semiconductor switching device, the bridging device is opened, as a result of which the alternating current and / or the alternating voltage is conducted via the bidirectionally blocking-capable semiconductor switching device. In the case of a bridging device designed as a mechanical switch, an arc is thus avoided or an arc duration reduced when the mechanical switch is opened.

Finally, the bidirectionally barrier-capable semiconductor switching device is also opened, whereby no AC and / or no AC voltage is fed to the load.

During these switching phases (switching on / off of the load), the bidirectionally blocking-capable semiconductor switching device can be bypassed by a protective circuit device when a predetermined overvoltage occurs. The preferred embodiments presented with reference to the device according to the invention and their advantages apply correspondingly to the circuit arrangement according to the invention and to the method according to the invention. In the following, the invention will now be explained in more detail with reference to a preferred embodiment as well as with reference to the accompanying drawings.

Show it:

1 shows a schematic representation of an embodiment of a device according to the invention;

FIG. 2 shows a schematic illustration of a further embodiment of a device according to the invention; FIG.

Fig. 3 is a schematic representation of an embodiment of a circuit arrangement according to the invention; 4 shows a schematic illustration of a further embodiment of a circuit arrangement according to the invention;

5 shows a schematic illustration of the switching characteristics within an embodiment of the device according to the invention when a short circuit occurs during a switch-on phase of a load; and

6 shows a schematic representation of the switching characteristics within an embodiment of the device according to the invention when a short circuit occurs during an operating phase of a load.

The same or functionally identical elements are provided in the figures with the same reference numerals.

The exemplary embodiment explained below is a preferred embodiment of the invention. at In the exemplary embodiment, however, the described components of the embodiment represent individual features of the invention, which are to be considered independently of each other, and which each independently further develop the invention and thus also individually or in a different combination than shown as part of the invention. Furthermore, the described embodiment can also be supplemented by further features of the invention already described.

Fig. 1 shows a device 1 for limiting an alternating current and / or an alternating voltage when switching a load, not shown here. The device 1 constitutes a solid-state switch and comprises a bidirectionally blocking-capable semiconductor switching device 2, a protective circuit device 3 connected in parallel with the bidirectionally-blocking semiconductor switching device 2 and a bypass device 4 connected in parallel with the bidirectionally-blocking semiconductor switching device 2 and the protective circuit device 3.

The bidirectional blocking semiconductor switching device 2 here comprises an antiserial circuit of a first IGBT 5 and a second IGBT 6. Each of the IGBTs 5 and 6 has a control terminal or a gate terminal G, via which the IGBTs 5 and 6 can be controlled. For this purpose, the gate terminal G may for example be connected to a driver circuit or control device, not shown here, which is designed to turn on and / or off the respective IGBT 5 and 6. Since IGBTs are usually limited in the reverse direction only limited, here between an emitter terminal E and a collector terminal C of each of the IGBTs 5 and 6 is provided in each case a freewheeling diode FD, which conducts in the reverse direction. When the bidirectionally breakable semiconductor switching device 2 is closed, that is, the IGBTs 5 and 6 are turned on, an alternating current and / or an alternating voltage can be applied across the bidirectionally breakable semiconductor switching device 2 are performed.

The protective circuit device 3 is designed here as a varistor and is designed to bridge the bidirectionally barrier-capable semiconductor switching device 2 from a predetermined overvoltage, which may occur, for example, as a so-called voltage peak when switching off an inductive load. While the bidirectionally breakable semiconductor switching device 2 is bridged by the protective circuit device 3, a current caused by the predetermined overvoltage can be conducted past the protective circuit device 3 to the bidirectionally inhibitable semiconductor switching device 2. Further possibilities for overvoltage limiting are so-called active clamping or monitoring of the collector-emitter voltage (U _CE ) of the IGBTs 5 and 6.

The bridging device 4 is designed here as a relay or as bypass contacts and serves to bridge the bidirectionally blocking-capable semiconductor switching device 2 in an operating phase of the load. While the bidirectionally barrier-capable semiconductor switching device 2 is bridged by the bridging device 4, the alternating current for supplying the load or the load current can be passed over the bridging device 4 to the bidirectional blocking semiconductor switching device 2.

FIG. 2 shows a further embodiment of a device 1 according to the invention. The bidirectionally barrier-capable semiconductor switching device 2 here has a parallel connection of a first backward blocking IGBT (RB-IGBT) 7 and a second backward blocking IGBT 8. By using the backward blocking IGBTs 7 and 8, the freewheeling diodes FD according to FIG. 1 can be dispensed with.

Fig. 3 shows an embodiment of a circuit arrangement 9 according to the invention with a load M. The load M is here exemplified by an asynchronous three-phase machine. The load M is operated via three phases or conductors LI, L2, L3 with a three-phase alternating current. Each of the three conductors LI, L2, L3 has in each case a device 1, via which the load M is supplied with an alternating voltage and / or an alternating current. Each of the devices 1 here has a bidirectionally barrier-capable semiconductor switching device 2 according to FIG. To switch on the load M, eg to start up the

Asynchronous three-phase machine, the bidirectional breakable semiconductor switching device 2 is first closed by at least two of the three conductors LI, L2, L3. For this purpose, the IGBTs 5 and 6 of the respective bidirectionally blocking-capable semiconductor switching device 2 can be driven pulsed to a

Soft start of the load M to enable. For controlling the bidirectionally inhibitable semiconductor switching device 2 or the IGBTs 5 and 6, for example, a control device not shown here may be provided. During the switch-on phase of the load M, the bridging device 4 is galvanically isolated from the load M. If a short-circuit occurs during turn-on of the load M, the bidirectionally breakable semiconductor switching device 2 can be opened immediately, ie independently of a current phase of the alternating current and / or the alternating voltage, and the load M thereby switched off. An overvoltage occurring when switching off can be limited by the protective circuit device 3. In the event of a successful, in particular short-circuit-free, starting of the load M, the bidirectionally barrier-capable semiconductor switching device 2 can be bridged by the respective bridging device 4. After bridging the respective bidirectionally blocking-capable semiconductor switching device 2, this can be opened, that is, switched to a blocking state. The load M is now operated in an operating phase and is only activated via the respective bridging direction 4 supplied with the alternating current and / or the alternating voltage.

To terminate the operating phase, the respective bi-directional blocking semiconductor switching device 2 is closed again, ie the IGBTs 5 and 6 are turned on. Subsequently, the respective bridging device 4 is galvanically separated from the load M. In the case of a bridging device 4 designed as a relay, during the opening of the relay, contact resistances at the respective relay rise in such a way that the respective IGBTs 5 and 6, ie the bidirectionally nonconductive semiconductor switching device 2, take over the carrying of the alternating current. As a result, the relay is switched off and there is no arc.

Subsequently, the respective IGBTs 5 and 6 are turned off. By switching off the inductive load M or by leakage inductances in the Kommutierungskreis the circuit 9 surges or so-called voltage peaks can arise, which can be limited by the respective protective circuit device 3.

FIG. 4 shows a further embodiment of a circuit arrangement 9 according to the invention, in which the three conductors L 1, L 2, L 3 have a device 1 according to FIG. 2.

FIG. 5 shows switching characteristics 10 and 11 of the bridging device 4 and the bidirectionally inhibitable semiconductor switching device 2 when a short circuit 12 occurs during a switch-on phase 13 of the load M. The switching curve 10 corresponds to the switching curve of the bridging device 4 and the switching curve 11 corresponds to the switching curve of FIG bidirectionally blocking semiconductor switching device 2. The switching curves 10 and 11 are plotted over the time t. A respective switching state "1" means that the bidirectional blocking semiconductor switching device 2 or the bridging device 4 is closed. A respective switching state "0" means that the bidirectionally barrier-capable semiconductor switching device 2 or the bridging device 4 is open

Semiconductor switching device 2 is closed to switch on the load M, that is to say into the switching state "1." The bridging device 4 is opened during the switch-on phase 13, thus has the switching state "0". The alternating current and / or the alternating voltage is thus conducted to the load M only via the bidirectionally non-conductive semiconductor switching device 2. During the switch-on phase 13 at a time .2, the short-circuit 12 occurs here. Subsequently, the bidirectionally barrier-capable semiconductor switching device 2 is opened, that is to say placed in the switching state "0", the bridging device 4 remains open, so that a flow of the alternating current to the load M is interrupted.

An overvoltage occurring when opening or shutting off the bidirectionally blocking-capable semiconductor switching device 2 can be limited by the protective circuit device 3. FIG. 6 shows the switching characteristics 10 and 11 of the bridging device 4 and of the bidirectionally inhibitable semiconductor switching device 2 during the occurrence of the short circuit 12 during an operating phase 14 of the load M over the time t.

In order to switch on the load M, the bi-directionally blocking-capable semiconductor switching device 2 is closed in the switch-on phase 13, that is, in the switching state "1", between times t 1 and .2 At time t 2, when a predetermined operating voltage is applied to the load M, for example , In addition, the lock-up device 4 is closed, so also in the switching state "1" offset. From time t2, the load M is in the operating phase. 14. Until a point in time t3, both the bidirectionally blocking-capable semiconductor switching device 2 and the bridging device 4 remain in the closed state. At the instant ts, the bidirectionally blocking-capable semiconductor switching device 2 is opened, that is to say placed in the switching state "0", while the bridging device 4 remains closed, ie the alternating current is only conducted to the load M via the bridging device 4. At a time t4 during the operating phase 14, the short-circuit 12 occurs At the time t ₄ , the bidirectionally breakable semiconductor switching device 2 is closed, that is put into the switching state "1". The bridging device 4 remains closed until a time t _{5 in} addition to the bidirectionally disabling semiconductor switching device 2 and is opened at time t ₅ . The alternating current is only passed through the bidirectional blocking semiconductor switching device 2, which is also opened at the time te. From the time te, the load M is no longer supplied with the alternating current and / or the alternating voltage.

Overall, the example shows how a hybrid solid-state relay can be provided by the invention.

Reference sign list

1 device

2 bidirectionally breakable semiconductor switching device

3 protection circuit device

4 bridging device

5 first IGBT

6 second IGBT

7 first backward blocking IGBT

8 second reverse blocking IGBT

9 circuit arrangement

10 switching course

11 switching process

12 short circuit

13 switch-on phase

14 operating phase

FD freewheeling diode

G gate connection

E emitter connection

C collector connection

M load

LI, L2, L3 ladder

t time

times

Claims

claims

1. Device (1) for limiting an alternating current

and / or an alternating voltage when switching a load (M), wherein the device (1) comprises a switching device for switching the alternating voltage and / or the alternating current in a switching phase and a bypass device (4) for bypassing the switching device in an operating phase (14 ) of the load (M),

characterized in that

the switching device comprises a bidirectionally barrier-capable semiconductor switching device (2) which is designed to switch off the alternating voltage and / or the alternating current independently of a current phase angle of the alternating voltage and / or the alternating current, and the device (1) comprises a protective circuit device (3 ) for bridging the bidirectional blocking semiconductor switching device (2) from a predetermined overvoltage in the switching phase has.

2. Device (1) according to claim 1,

characterized in that

the bidirectionally blocking-capable semiconductor switching device (2) has an antiserial circuit of two IGBTs (5, 6).

3. Device (l) according to claim 1 or 2,

characterized in that

the bidirectionally breakable Halbleiterschalteinrich- device (2) has an anti-parallel connection of two backward blocking IGBTs (7, 8).

4. Device (1) according to one of the preceding claims, characterized in that

the bidirectionally blocking-capable semiconductor switching device (2) has an antiserial circuit of two power MOSFETs. Device (1) according to one of the preceding claims, characterized in that

the bidirectionally blocking-capable semiconductor switching device (2) has an antiserial circuit of two junction field-effect transistors.

Device (1) according to one of the preceding claims, characterized in that

the protective circuit device (3) is designed to bridge the bidirectionally blocking-capable semiconductor switching device (2) as of a breakdown voltage of the bidirectionally blocking-capable semiconductor switching device (2) as the predetermined overvoltage.

Device (1) according to one of the preceding claims, characterized in that

the protective circuit device (3) has a varistor. 8. Device (1) according to one of the preceding claims, characterized in that

the protective circuit device (3) has an RC element.

Device (1) according to one of the preceding claims, characterized in that

the protective circuit device (3) has a gas absorber. 10. Circuit arrangement (9) with a load (M), a

Control device and at least one device (1) according to one of the preceding claims, wherein the load (M) is electrically connected to the at least one device (1) and the control device is adapted to the respective bidirectionally barrier-capable semiconductor switching device (2) of the at least one device (1) and / or the respective bridging device (4) of the device (1) for opening and / or closing head for .

11. Method for limiting an alternating current

and / or an alternating voltage when switching a load (M),

characterized in that

when the load (M) is switched on, a bidirectionally blocking-capable semiconductor switching device (2) for conducting the alternating current and / or the alternating voltage is closed and the bidirectionally blocking-capable semiconductor switching device (2) is bridged by a bridging device (4), and thereby the load (M) in an operating phase (14) is operated and / or when switching off the load (M) the bridging means (4) by the bidirectional blocking semiconductor switching device (2) is bridged and the bidirectional blocking semiconductor switching device (2) for

instantaneous phase angle independent blocking of the AC and / or the AC voltage is opened.