WO2014086432A1 - Dc voltage power switch - Google Patents

Abstract

The invention relates to a device (15) for switching direct currents in a pole of a DC voltage network, comprising two connection terminals (2, 3), between which an operational current path (4) with a mechanical switch (8) extends, said current path being bridgeable by a switch-off branch (5) in which a power switching unit (9) is arranged. The power switching unit has a series circuit of two-polar sub-modules (12) with at least one power semiconductor switch (13), which can be switched on and off, and the device comprises commutation means for commutating the current from the operational current path (4) into the shut-off branch (5). The sub-modules (12) of the power switching unit (9) form a first and a second switching direction group (10, 11), each of which is designed to shut off currents in a unidirectional switching direction. The switching direction of the first switching direction group (10) is oriented opposite the switching direction of the second switching direction group (11). The aim of the invention is to produce such a device so as to be inexpensive. This is achieved in that the first switching direction group (10) is designed to switch off load and short-circuit currents, and the second switching direction group (11) is designed exclusively to switch off load currents; and protective means (16, 17, D₁) are provided for protecting the second switching direction group (11) in the event of a short-circuit.

Description

description

DC power switch The invention relates to a device for switching

DC currents in a pole of a DC voltage network comprising two terminals that can be connected in series with the pole, between which an operating current path extends with a mechanical switch which can be bridged by a turn-off branch, in which a power switching unit is arranged comprising a series connection of two-pole submodules with at least a switchable power semiconductor switch, and commutation means for commutating the current from the operating current path into the turn-off branch, the sub-modules of the power switching unit forming first and second switching direction groups each arranged to turn off currents in a unidirectional switching direction, the switching direction the first switching direction group is oriented opposite to the switching direction of the second switching direction group.

Such a device is for example from WO

2011/057675 known. The DC voltage switch illustrated therein has an operating current path with a mechanical switch and a turn-off branch, which is connected in parallel with the operating current path. In the Abschaltzweig a series circuit of power semiconductor switches is arranged, each of which a freewheeling diode is connected in parallel in opposite directions. The switching units consisting of power semiconductor switch and freewheeling diode are arranged antiserially, so that switching direction groups are present. each

Switching group is able to carry currents in both directions, but only switch off in one direction. In the Abschaltzweig therefore two antiserial to each other arranged switching direction groups are provided, so that in the Abschaltzweig currents can be turned off in both directions. In the operating current path, commutation means are arranged in the form of an electronic auxiliary switch. in the Normal operation, an operating current flows through the operating current path and thus via the closed mechanical

Switch, since the power semiconductor switch the Abschaltzweiges represent an increased resistance for the DC current. To interrupt, for example, a short-circuit current, the electronic auxiliary switch is transferred to its disconnected position. As a result, the resistance increases in the operating current path, so that the direct current commutes in the Abschaltzweig. The fast mechanical disconnector can then be opened without current. For receiving the energy stored in the DC voltage network and to be reduced during switching Abieiter are provided, which are connected in parallel to the power semiconductor switch of Abschaltzweiges. The prior art device has the disadvantage that doubles in a switching capability of currents in both directions of the power semiconductor overhead. For every

Current direction is provided a switching group direction. Each switching group must be able to switch both the high short-circuit currents and to withstand the resulting high voltages. The additional effort required to achieve the switching capability in both directions is thus enormous. The object of the invention is therefore to provide a device of the type mentioned, which is inexpensive.

The invention solves this problem in that the first switching group for switching off load and short-circuit leakage currents and the second switching direction group is set up exclusively for switching off load currents and protection means for protecting the second switching group are provided in case of short circuit. The invention is based on the idea that short-circuit currents often only have to be switched off in one direction, whereas load currents have to be conducted and switched in both directions. In the context of the invention is therefore the previous Schaltkonzept expanded so that the necessary bidirectional load current switching capability is provided by a first and second switching direction group. However, the second switching group is designed in the context of the invention only to the requirement of the current carrying capacity of the load current. This semiconductor path designed for lower currents must therefore be protected against possible fault currents. For this purpose, protection means are provided which, for example, upon the occurrence of a short circuit protection of the second

Provide switching group. The first switching direction group is set up to operate and switch even high short-circuit currents. In the context of the invention, short-circuit currents can therefore be switched off in only one direction. The load currents, however, can be switched off in both directions. The semiconductor expense for the design of the second switching group has thus reduced considerably compared to the previously known prior art device. The switch according to the invention is therefore less expensive. In this case, the device of the invention is the most in practice requirements. Thus, within the scope of the invention, a practical low-cost power semiconductor switch is provided.

Expediently, the protection means comprise a parallel path for bridging the second switching direction group. in the

In the event of an error, that is to say when high currents occur, according to this advantageous embodiment of the invention, the short circuit current is conducted via the parallel path, so that the second switching direction group designed to carry lower currents is protected.

According to an expedient further development, a mechanical switch is arranged in the parallel path. In the case of a short circuit, the said switch is closed, so that a low-inductive bypass path is provided for protecting the second switching direction group. In order to switch the load current with the second switching direction group, the mechanical switch is opened in the parallel path. According to a deviating variant of the invention, a diode and / or a thyristor are arranged in the parallel path. Each diode arranged in the parallel path and each thyristor arranged there has a forward direction which corresponds to the switching direction of the first switching direction group. Each diode and each thyristor is designed to carry high short-circuit currents. The short-circuit currents which can be switched off by the first switching group are thus passed through the diode and the thyristor, which are designed for these high currents and thus are not destroyed.

Expediently, the parallel path has a greater conductivity in the forward direction of the diode and / or the thyristor than the path bridged by it, including the second switching direction group. According to this further development, it is ensured that the short-circuit current is not conducted via the freewheeling diodes of the second switching direction group due to a possibly lower ohmic resistance. In other words, the power semiconductors of the parallel path have a higher conductivity than the freewheeling diodes of the second switching direction group.

The commutation means are expediently arranged in the turn-off branch and arranged to generate a circulating current which flows over the bridged section of the operating current path and the turn-off branch and which is opposite to the current in the mechanical switch. As a result of the arrangement of the commutation means in the turn-off branch, the constant operating current can be conducted in a loss-free manner over the operating path in normal operation, in which only a low-impedance mechanical switch is arranged. Power electronic auxiliary switches in the operating current path with high losses in the wake have become superfluous. The arranged in Abschaltzweig commutation are, for example, part of the power switching unit of the second switching direction group and therefore protected by the protective means from excessive currents. The commutation means are designed for the maximum fault current and expediently in the first

Switching group arranged. After commutation of the current, the mechanical switch is opened. As soon as the latter provides sufficient dielectric strength, the commutation means can be used to switch off the currents flowing via the cut-off branch. The commutation means are preferably two-pole submodules which are connected in series with one another in the turn-off branch, for example as part of the first switching direction group. In this case, each submodule has an energy store, such as a capacitor, to which a power semiconductor circuit is connected in parallel. These submodules can for example form a half or full bridge circuit. At the two submodule terminals of each submodule, either the voltage dropping on the energy store, a zero voltage and, in the case of a full bridge circuit, the inverse energy storage voltage can then be generated. In this way, circulating currents can be generated which flow in both directions in said mesh. Of course, it is within the scope of the invention also possible to arrange commutation in the form of a power electronic auxiliary switch in the operating current path. The power electronic auxiliary switch, for example, an IGBT with opposite parallel freewheeling diode. If the said IGBT is transferred to its blocking position, the resistance in the operating current path increases so that the current commutates into the turn-off branch.

According to a preferred embodiment of the invention, the submodules of the power switching unit at least partially each have a power semiconductor switch which can be switched on and off and a freewheeling diode connected in parallel in opposite directions. Such submodules do not serve as commutation means. Instead of an oppositely parallel freewheeling diode and backward conductive power semiconductor switches can be used. The two-pole submodules are arranged in series, whereby the freewheeling diodes can only conduct the current flowing via the shutdown branch in one direction. The currents can only be switched off in the forward direction of the respective power semiconductor switch. For bidirectional shutdown capability, the submodules are arranged antiserially, so that two switching direction groups are formed.

According to an expedient further development, the submodules of the power switching unit each have at least partially an energy store and a parallel connected to the energy storage series circuit of two switched on and off power semiconductor switches with oppositely arranged parallel thereto freewheeling diodes, wherein a submodule connection terminal with a potential point between the on and off power semiconductor switches and the other terminal are connected to a pole of the energy storage. Such submodules form a so-called

Half bridge circuit off. Submodules with a half-bridge circuit can be used with appropriate orientation as a commutating means, as already stated above.

According to a further expedient embodiment of the invention, the submodules of the power switching unit at least partially an energy storage and two parallel connected to the energy storage series circuits with two switched on and off power semiconductor switches with oppositely parallel freewheeling diode, wherein a first terminal with the potential point between the two power semiconductor switches of the first Series connection and a second submodule connection terminal is connected to the potential point between the two power semiconductor switches of the second series circuit. According to this advantageous development of the invention, the power switching unit at least partially comprises submodules with full bridge scarf - tion. Such submodules can carry and switch currents in both directions. They are also able to generate voltages in the loop formed by Abschaltzweig and operating current path, which provide in the said loop a circular current for commutating the currents from the operating current path in the Abschaltzweig.

Advantageously, the terminals of each submodule can be connected to one another via a diode or a thyristor. The diode or the thyristor therefore allows a

Bridging the submodule and thus constitute protection means integrated in the submodules.

In order to reduce a mains-stored energy to be degraded during switching, the power switching unit has varistors and / or downsistors connected in parallel to at least one submodule.

Advantageously, the varistors and / or Abieiter at least partially connected in parallel to an energy store.

In order to be able to simply put the device according to the invention into operation, it is expedient to provide a charging branch which is connected either to a ground potential or to an opposite pole polarized opposite to the pole. The charging branch is connected at its end facing away from the opposite pole or ground potential to the turn-off branch. Conveniently, an ohmic resistance is arranged in the charging branch. Further expedient embodiments and advantages of the invention are the subject matter of the following description of embodiments of the invention with reference to the figures of the drawing, wherein like reference numerals refer to like-acting components and wherein

Figure 1 shows an embodiment of a bidirectional

DC power switch schematic, Figure 2 shows a first embodiment of the device according to the invention and

Figure 3 show a further embodiment of the device according to the invention.

1 shows an already described DC voltage circuit breaker 1, which has a first terminal 2 and a second terminal 3, with which the DC voltage circuit breaker 1 can be connected in series in a non-illustrated pole of a DC voltage network. Between the terminals 2 and 3, an operating current path 4, to which a turn-off branch 5 is connected in parallel extends. In this case, a first branch point 6 and a second branch point 7 are formed. In the operating current path 4, a mechanical switch 8 is arranged.

The turn-off branch 5 has a power switching unit 9 with a first switching direction group 10 and a second switching direction group 11. Each switching direction group 10, 11 has a series connection of two-pole submodules 12, of which only one is shown for each switching direction group 10 and 11. Each submodule 12 has, for example, a power semiconductor switch 13 which can be switched on and off, to which a freewheeling diode 14 is connected in parallel in opposite directions. In parallel to the submodules 12 Abrieiter not shown figuratively arranged with which a stored in the network and released during switching energy can be reduced. If a short-circuit current now flows from the branching point 6 to the branching point 7 via the turn-off branch 5, this is conducted via the series-connected power semiconductor switches 13 of the first switching direction group 10 and via the series-connected freewheeling diodes 14 of the second switching direction group 11. A current flow in this direction can only be switched off by the switching direction group 10. For this purpose, the power semiconductor switch 13 of this group are transferred by a control signal in its blocking position. A current flows from Branch point 7 via the Abschaltzweig 5 to the branching point 6 this is performed via the series-connected power semiconductor switch 13 of the second switching direction group 11 and the series-connected freewheeling diodes 14 of the first switching direction group 10. A stream in this

Direction can only be switched off by the second switching direction group. For this purpose, the power semiconductor switches 13 of the second switching group 11 are transferred to their disconnected position. In order to commutate the current from the operating current path 4 in the Abschaltzweig 5 and thus on the power switching unit 9, figuratively not shown commutating means are provided. These include, for example, an auxiliary switch arranged in the operating current path, which also forms two switching direction groups, so that its power semiconductor switches 13 block a current flow in both directions and thus ensure commutation in the shutoff branch. The fast mechanical switch 8 can then be opened and then the current through the power switching unit 9 are turned off. In addition, it is also possible for the commutation means to be arranged in the turn-off branch 5 and to generate this voltage, in which mesh formed from the operating current path 4 and the turn-off branch 5 is set up. Two-pole submodules, each having an energy store and a power semiconductor circuit, which preferably form a full bridge circuit with one another, serve to generate a voltage. At the two terminals of each submodule either the voltage dropping across the energy store, a zero voltage or the inverse energy storage voltage can now be generated. Thus, a circulating current can be generated in the said mesh, which is opposite to the current flowing over the operating current path 4. It comes to the commutation of the total current in the Abschaltzweig 5. In the context of the invention, however, other commutation means not mentioned here are used.

FIG. 2 shows an exemplary embodiment of the device 15 according to the invention, which has all the features of the DC voltage 1, so that the statements made here also apply here, with the difference that the second switching group 11 is set up only for switching and conducting load currents. Thus, the first switching group 10, for example, a maximum withstand voltage, which corresponds to twice the rated voltage. The maximum turn-off current of the first switching group 10 is for example eight times the rated current. The second switching group 11, for example, has a maximum withstand voltage, which corresponds to 1.2 times the rated voltage, wherein the maximum cut-off current is equal to the rated current. Thus, the number of submodules to be connected in series and the number of power semiconductor switches to be connected in parallel per submodule with respect to the first switching direction group 10 in the second switching direction group 11 can be considerably reduced. This results in a considerable cost savings in the wake. In order to protect the second switching group 11 from destruction by high short-circuit currents, protection means are provided which in this case comprise a parallel path 16 in which a mechanical switch 17 is arranged.

With the device 2 according to the invention load currents can now be switched off and performed in both directions. First, the load current is determined using the above described

Commutation commuted in the Abschaltzweig 5. If the load current flows from the terminal 3 to the terminal 2, it is switched off by the second switching group 11. The first switching direction group 10 takes over the switching off of load currents flowing from the terminal 2 to the terminal 3.

It is assumed in the context of the invention that short-circuit currents flow only from the connection terminal 2 to the connection terminal 3. If a short circuit occurs in this direction behind the device 15, then the mechanical switch 17 closes and thus protects the electronic power components of the second switching group 11. Current is switched off by the first circuit group 10.

If a load current flowing from terminal 3 to terminal 2 is to be switched off, then the

 Switch 17 open. The current commutes into the second switching group 11 and can be switched off by this.

FIG. 3 shows a further exemplary embodiment of the device according to the invention, which essentially corresponds to the exemplary embodiment shown in FIG. 2, but in the parallel path 16 a diode Di is arranged instead of a mechanical switch. The diode Di has a forward direction which is opposite to the switching direction of the second switching direction group 11. In other words, the diode Di has the same forward direction as the series-connected freewheeling diodes 14 of the second switching direction group 11. However, it is a prerequisite that the path across the diode Di is lower impedance than the path through the freewheeling diodes 14. In other words the diode Di has a greater conductivity than the series connection of the freewheeling diodes of the second switching direction group 11.

In general, however, a single diode Di in the parallel path 16 or a single mechanical switch or a single thyristor will not be sufficient, so that a series connection of such components in the parallel path 16 is arranged. This series connection of thyristors, for example, can be integrated into the submodules of the second switching direction group 11, so that compact components are provided. This also reduces the insulation and design effort.

According to a preferred embodiment, the submodules 12 of the power switching unit 9 are equipped with an energy store and a power semiconductor circuit, which together form a half or preferably a full bridge circuit. Each submodule can be placed between its submodule Terminals each have a as oriented in Figure 3 diode or an equally oriented thyristor. According to this embodiment of the invention, the protection means are integrated into the series-connected two-pole submodules of the second switching direction group 11.

Within the scope of the invention, it is possible to save a considerable part of the power electronics if the device according to the invention has to switch off fault currents in only one direction.

Claims

claims

1. Device (15) for switching DC currents in a pole of a DC network comprising

two terminals (2,3) between which an operating current path (4) with a mechanical switch (8) extends,

 - Which can be bridged by a Abschaltzweig (5),

 - In which a power switching unit (9) is arranged, which has a series connection of two-pole submodules (12) with at least one switched on and off power semiconductor switch (13), and

 Commutation means for commutating the current from the operating current path (4) into the turn-off branch (5),

- wherein the submodules (12) of the power switching unit (9) form a first and a second switching direction group (10,11), which are each arranged for switching off currents in a unidirectional switching direction, the switching direction of the first switching direction group (10) entge - oriented to the switching direction of the second switching direction group (11) is oriented,

d a d u r c h e c e n c i n e s that

the first switching direction group (10) for switching off load and short-circuit currents and the second switching direction group (11) is set up exclusively for switching off load currents and protection means (16, 17, Di) for protecting the second switching direction group (11) are provided in the event of a short circuit.

2. Device (15) according to claim 1,

d a d u r c h e c e n c i n e s that

the protection means comprise a parallel path (16) for bridging the second switching direction group (11).

3. Device (15) according to claim 2,

d a d u r c h e c e n c i n e s that

in the parallel path (16) a mechanical switch (17) is arranged.

4. Device (15) according to claim 2,

d a d u r c h e c e n c i n e s that

in the parallel path (16) a diode (Di) and / or a thyristor are arranged.

5. Device (15) according to claim 4,

d a d u r c h e c e n c i n e s that

the parallel path (16) has a greater conductivity in the direction of passage of the diode (Di) and / or the thyristor than the path bridged by it, including the second switching direction group (11).

6. Device (15) according to one of the preceding claims, characterized in that a

the commutation means are arranged in the turn-off branch (5) and are arranged to generate a circulating current flowing over the bridged section of the operating current path (4) and the turn-off branch (5), which is opposite to the current in the mechanical switch (8).

7. Device (15) according to one of the preceding claims, characterized in that a

the submodules (12) of the power switching unit (9) at least partially each have a power semiconductor switch (13) which can be switched on and off and a freewheeling diode (14) connected in parallel thereto in opposite directions.

8. Device (15) according to one of the preceding claims, characterized in that a

the submodules (12) of the power switching unit (9) at least partially each have an energy store and a parallel connected to the energy storage series circuit of two switched on and off power semiconductor switches (13) with parallel arranged parallel freewheeling diodes (14), wherein a submodule connection terminal with a Potential point between the switchable and disconnectable power semiconductors terschaltern (13) and the other submodule connection terminal are connected to a pole of the energy store.

9. Device (15) according to one of the preceding claims, characterized in that a

the submodules (12) of the power switching unit (9) have at least partially an energy store and two series circuits connected in parallel to the energy store, each with two turnable power semiconductor switches (13) with reverse freewheeling diode (14) in opposite directions, wherein a first submodule connection terminal with the potential point between the two power semiconductor switches (13) of the first series circuit and a second submodule connection terminal to the potential point between the two power semiconductor switches (13) of the second series circuit is connected.

10. Device (15) according to claim 8 or 9,

d a d u r c h e c e n c i n e s that

the submodule connection terminals of each submodule (12) can be connected to one another by a thyristor and / or a diode.

11. Device (15) according to one of the preceding claims, characterized in that a

the power switching unit (9) varistors and / or Abieiter in parallel with at least one sub-module (12) summarized.

12. The device (15) according to any one of the preceding claims, e e n e c e e n e d d e r c h

a charging branch connected to a ground potential or to a polar pole opposite to the pole.

13. Device (15) according to one of the preceding claims, characterized in that a

in the charging branch an ohmic resistance () is arranged.