EP3414838A1

EP3414838A1 - Dc voltage switch

Info

Publication number: EP3414838A1
Application number: EP17711631.6A
Authority: EP
Inventors: Jürgen RUPP
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2016-03-17
Filing date: 2017-03-16
Publication date: 2018-12-19
Also published as: WO2017158082A1; CN108781075A; KR20180122003A; DE102016204400A1; US20190074149A1; RU2703190C1

Abstract

The invention relates to a DC voltage switch having a first and second terminal for serial incorporation in a first pole of a DC voltage network, wherein a secondary current path having a semiconductor switch extends between the terminals, and an operating current path having a mechanical switch and, in series therewith, the primary-side winding of a transformer is arranged in parallel with the secondary current path, the secondary-side winding of the transformer is wired between a voltage source and a third terminal for incorporation into a second pole of the DC voltage network, a switch in series with the secondary-side winding of the transformer is arranged between the voltage source and the third terminal, the voltage source is connected to the first terminal via a diode and a charging resistor, there is a control device for driving the switch, which is configured to determine the voltage of the voltage source repeatedly after the mechanical switch has been opened and to switch the switch on at intervals in such a way that the voltage determined remains below a definable threshold value.

Description

description

The invention relates to a DC switch with two terminals, between which extend an operating current path with a mechanical switch and parallel to a Nebenstrom- path with a semiconductor switch. The disconnection of a direct current (DC current) is more difficult than turning off an alternating current (AC current) for feh ^¬ lendem zero crossing. While the arc that occurs when opening the contacts, when the AC current with a suitable design in the next current zero crossing goes out, he burns in the DC current over longer distances until the destruction of the switch on.

There are various concepts known to effect a safe shutdown ^¬ tion of a DC current. Such a concept is based on generating a countercurrent that compensates for the load current so that the current in a mechanical switch undergoes a zero crossing. The switch can then be opened without current, so that an arc does not arise or disappear. In another concept, the current first commutates into a semiconductor switch, from which it can be turned off without arcing.

A general problem with switching off a DC current is that the energy stored inductively in the DC network must be reduced in such a way that damage to the components of the DC network is avoided. It is known to ^¬ USAGE for voltage-limiting elements to. But these have a limited lifespan. Object of the present invention is to provide a DC voltage switch, which allows an improved degradation of the inductively stored in the DC power network energy. This object is achieved by a DC voltage switch with the features of claim 1.

The DC voltage switch according to the invention has a first and second connection for serial integration into a first pole of a DC voltage network. Between the terminals, a secondary current path with a semiconductor switch and parallel to the secondary current path extends an operating ^¬ current path with a mechanical switch and in series to the primary-side winding of a transformer. The secondary-side winding of the transformer is connected between a voltage source and a third terminal for integration in a second pole of the DC voltage network. Between the voltage source and the third terminal is a switch in series to the secondary winding of the

Transformers arranged. The voltage source is also connected through a diode and a charging resistor to the first to ^¬ circuit. Finally, a control device for controlling the switch is provided, which is configured, after opening the mechanical switch, the voltage of the

Voltage source is repeatedly determined and the switch so intermittently turn on, so that the determined voltage remains below a definable threshold. Advantageously, the inductively stored in the DC network power reduced in the inventive DC ^¬ switch directly on the switch. Otherwise Ele ^¬ ments for overvoltage limitation, such as varistors are unnecessary. When the controller has switched off the switch, the voltage rises above the voltage source with time, solan ^¬ GE nor energy is inductively stored. The controller detects the voltage across the voltage source continuously or at intervals. If a definable threshold for the voltage which is above the operating voltage of the DC voltage network is exceeded or reached, the switch is switched on. This creates a current path from the first pole of the DC network to the second pole of the DC network. This will result in a time-limited freewheeling circuit created and the voltage at the voltage source decreases.

The controller expediently switches the switch off again when the voltage drops below a further threshold value. The further threshold value may correspond to the threshold value or else be lower than the threshold value. Suitably, the further threshold is above the operating voltage of the DC voltage network.

Advantageous embodiments of the DC voltage switch according to the invention will become apparent from the dependent of claim 1 claims. In this case, the embodiment according to claim 1 can be combined with the features of one of the subclaims or preferably also with those of several subclaims. Accordingly, the following features can additionally be provided for the DC voltage switch:

- The third terminal can be connected to another ground potential instead of a second pole of the DC network.

- Parallel to the secondary side of the transformer, a second resistor may be connected. This resistance is sawn vorzugt dimensioned so that at least the maximum ERS ^¬ switching current can flow at rated voltage.

- Parallel to the secondary side of the transformer, a Di ^¬ ode be switched.

- The secondary current path may comprise two antiseries switched HL-switch and the main current path, the primary side ei ^¬ nes another transformer. In this way, the ^DC voltage ^¬ switch can be designed as a bidirectional switch. In other words, the switch is thereby enabled to turn off DC in both directions. It is expedient if the secondary ^{sides of} the transformers are connected in series and that of the secondary side the transformer remote terminal of the secondary side of the further transformer is connected via a further switch to the third terminal. - The voltage source preferably comprises an energy storage ^¬ device, in particular a capacitor. A capacitor is particularly suitable for quickly releasing the necessary energy to compensate for a short-circuit current or a normal operating current in the DC network and thus to force a zero crossing of the current.

- The power source may as a separate device may be provided with play ^¬ as a separate condenser, which work independently of other components of the Gleichspannungsnetz- is connected to the transformer. This can ensure a standby voltage source independent of Other pe ^¬ gen conditions, for example by a separate charging circuit for the power source. The voltage source can be designed as part of a further circuit, for example as an intermediate circuit capacitor of an inverter which, for example, is otherwise related to the DC network. As a result, existing resources of the structure are reused and thus achieved a total of savings on components.

- The mechanical switch can have a switching time of less than 5 ms. Because the current zero-crossing is due to the discharge of an energy storage device, the period of time within the half takes place, a current zero crossing, typischerwei ^¬ se is limited to only a few milliseconds. Advantageously, the mechanical switch can open within this time to e ^{¬ ¬} ne safe suppression or erasure of the arc to be ^¬ act.

- The device may be configured such that the secondary-side winding of the transformer is short-circuited. For example, one with a semiconductor switch or a fast mechanical switch provided connection between the coil ends of the secondary-side winding of the transformer. By short-circuiting the secondary winding of the transformer, the inductance of the primary side winding of the trans ^¬ formators is reduced to a very low value, and thus advantageously reduces the influence of the primary-side winding of the transformer on the characteristics of the direct voltage network.

Preferred, but in no way limiting Ausführungsbei ^¬ games for the invention will now be explained in more detail with reference to the figures of the drawing. The features are shown cal ^¬ matized and show it

FIG. 1 shows a unidirectional DC voltage switch in a section of a DC voltage network;

Figure 2: a bidirectional DC voltage switch in a section of a DC network.

FIG. 1 shows, as an exemplary embodiment of the invention, a DC voltage switch 12 in a section of a DC voltage network 10. The DC voltage network 10 is supplied from a DC voltage source 11 and thus supplied with a DC voltage. In the DC ^¬ network 10 may be a network in the HVDC power supply or, for example, a network in a vehicle, such as a locomotive or a motor coach or at the inlet area in a network for electrically powered vehicles. Basically, the principle is applicable at all voltage levels from low voltage to medium voltage to high voltage. Between the load, not shown, and the DC voltage source 11, the DC voltage switch 12 is arranged. The DC voltage switch 12 is connected in series with a first and second connection terminal 121, 122 into a first pole 111 of the DC voltage network 10. A third connecting terminal 123 is connected to a second pole of the DC clamping voltage ^¬ network 10th

Between the first and second connection terminals 121, 122, the DC voltage switch 12 has a series connection of the primary-side winding of a transformer 14 and a mechanical switch 13. This series connection represents the main current path through which the current flows in the normal operation of the DC network 10. The mechanical

Switch 13 and the primary winding of the transformer 14 wei ^¬ sen only a very low resistance and therefore cause only very small losses. Parallel to the series ^{scarf ¬} tion a main switch 15 is arranged in the form of an IGBT, which is a secondary current path, which is not or only slightly flows through the current during normal operation, since the IGBT also turned on a significantly higher resistance or voltage drop than the mechanical switch 13 on ^¬ points. The DC switch 12 further includes a freewheeling path via a freewheel diode 19 as a connection between the second and third terminal 122, 123. The free ^¬ running path is optional, and is then blocked if the energy stored in line inductance 1111, for example, in cables for quickly interrupted current may possibly lead to destruction.

Starting from the first of the terminals 121, which faces the primary winding of the transformer 14, a further connection via a diode 163 and a charging resistor 162 to a capacitor 161 is present. The off-terminal of the capacitor 161 is connected to the third terminal 123. The potential point between the capacitor 161 and the charging resistor 162 is connected to the secondary winding of the transformer ^¬ sector 14. From this, a switch 152 is arranged in the form of an IGBT, whose second terminal is connected to the third terminal 123 and thus to the second pole of the DC power network 10. In norma ^¬ len operation case, the switch is turned off and 152, so that the capacitor 161 can not discharge. The capacitor 161 is constantly charged in normal operation.

By choosing the transmission ratio in the transformer 14, the necessary voltage for the capacitor 161 and thus the exact design of the components can be determined. The components can be optimized, for example, for a fast off ^¬ circuit or for small sizes. For the turns ratio between the primary side and the secondary side of the transformer 14, values between 0.01 and 0.1 are suitably used. On the secondary side only one voltage is required, which is greater than the voltage drop across the ^¬ semiconductors to be commutated in the current, which is at a low voltage below 10V application. The required capacity of the capacitor 161 and the height of the necessary charging voltage resulting from the voltage of the direct voltage network 10 and the gear ratio of the trans ^¬ formators fourteenth

First of all the current flows in normal operation by the mechanical switch 13. To initiate the shutdown operation gear turns a control 17 for the DC ^¬ switch 12 first the power switch 15 a. Because of the larger on-state resistance, only a small portion of the current will initially commute from the mechanical switch 13 to the main switch 15. To force this commutation, the switch 152 is turned on, causing the capacitor 161 to discharge via the transformer 14. As a result, a voltage in the main current ^{path is} generated with the mechanical switch 13, so that the current commutes completely into the main ^{scarf ¬} ter 15. Then, the mechanical switch 13 is opened normally and the switch 152 is closed again. In the last step, the main switch 15 must now be switched off so that the current flow is completely interrupted. The stored energy in the grid inductance 1112 may discharge via the freewheeling diode 19. The energy of the line inductance in 1111 would produce a high overvoltage at the input of the DC switch ^¬ 12th In order to reduce this energy and to limit the voltage, the switch 152 is now periodically switched on and off again. Thus, the energy in the charging resistor 162 is converted into heat and the current flow through the network inductance 1111, diode 163 and La ^¬ dewiderstand 162 degraded. In the pauses between pulses, when the switch 152 is switched off, the current can continue to flow into the capacitor 161, so that there is no rapid current ^drop . During the times when the switch 152 is turned on, the capacitor 161 is then discharged again to limit the voltage.

A second embodiment of the invention is shown in ^FIG . In contrast to the DC voltage switch 12 of FIG. 1, the DC voltage switch 20 according to FIG. 2 is designed to be able to operate bidirectionally, ie to be able to switch off a current flow in both directions. Matching components of the two DC voltage switches 12, 20 are provided with the same reference numerals. The DC voltage switch 20 is in turn connected in series with a first and second connection terminal 121, 122 in the first pole 111 of the DC voltage network 10. A third terminal 123 is connected to the second pole of the DC clamping voltage ^¬ network 10th

Between the first and second connection terminal 121, 122, the DC voltage switch 20 has a series connection of the primary-side winding of the transformer 14, the mechanical switch 13 and the primary-side winding of a further transformer 24. This series connection represents the main current path through which the current flows in the normal operation of the DC network 10. Parallel to the Se ^¬ rienschaltung another series circuit of the main switch 15 and the anti-serially arranged further main switch 25 is arranged, which represents the Nebenstrompfad. pa- Rallel to the main switch 15 163 diode is connected, which may be integrated as a component in the main switch 15. Parallel to the other main switch 25 diode 263 geschal ^¬ tet, which may be integrated as a component in the other main switch 25.

The DC voltage switch 12 further comprises a freewheeling path via a freewheeling diode 19 as a connection between the second and third connection terminal 122, 123 and a further freewheeling path with a further freewheeling diode 191 between the first and third connection terminal 121, 123.

Starting from the potential point between the main switch 15 and the other main switch 25, a connection via the charging resistor 162 to the capacitor 161 is present. The off-terminal of the capacitor 161 is connected to the third terminal 123.

The potential point between the capacitor 161 and the charging resistor 162 is connected to the secondary winding of the transformer 14 ^¬ gate. From this continuing the switch 152 is arranged, whose second terminal is connected to the third terminal 123 and thus to the second pole of the ^DC voltage network ^¬ 10. Between the switch 152 and the capacitor 161, a diode 271 is arranged parallel to the secondary winding of the transformer 14.

The potential point between the capacitor 161 and the charging resistor 162 is further connected to the secondary winding of the further transformer 24. From this further, a further switch 252 is arranged, whose second terminal is connected to the third terminal 123 and thus to the second pole of the DC network 10. Between the further switch 252 and the capacitor 161, a diode 272 is arranged parallel to the secondary winding of the further transformer 24. In other words, the bidirectional DC voltage switch 20 comprises two anti-series connected unidirectional DC voltage switches 12, the elements of mechanical switch 13, charging resistor 162 and capacitor 161 being needed only once.

When turning off a current from left to right, i. from the side of the grid inductance 1111, the pulse generation by the switch 152 and the transformer 14 is used for the generation of the commutation voltage and for the reduction of the energy in the grid inductance 1111. Free-wheeling diode 19 serves to reduce the energy in the network inductance 1112.

When a current is switched off from right to left, the pulse generation by the further switch 252 and the further transformer 24 is used for the generation of the commutation voltage and for the reduction of the energy in the network inductance 1112. The freewheeling diode 191 is used to reduce the energy in the network inductance 1111. The two diodes 271, 272 parallel to the secondary windings of the transformers 14, 24 serve as a freewheeling circuit for the leakage inductances and can also be replaced by resistors, analogous to the unidirectional DC voltage switch 12th

Claims

claims

1. DC voltage switch (12, 20) with a first and second terminal (121, 122) for serial integration in a first pole (111) of a DC network (10), where ^¬ at

- Between the terminals (121, 122) extends a Nebenstrompfad with a semiconductor switch (15) and

an operating current path with a mechanical switch (13) is arranged parallel to the secondary current path and in series therewith the primary-side winding of a transformer (14),

- the secondary-side winding of the transformer (14) Zvi ^¬ rule a voltage source (161) and a third terminal (123) for connecting to a second pole (112) of the direct voltage network is connected (10)

a switch (152) is arranged in series between the voltage source (161) and the third connection (123) to the secondary-side winding of the transformer (14),

the voltage source (161) is connected to the first terminal (121) via a diode (163) and a charging resistor (162),

- A control device (17) for controlling the switch (152) is provided, which is configured after the opening of the mechanical switch (13) to determine the voltage of the voltage source (161) repeatedly and the switch

(152) so intermittently turn on, so that the ermit ^¬ telte voltage remains below a definable threshold.

2. DC voltage switch (12, 20) according to claim 1 with a parallel to the secondary side of the transformer (14) switched ^¬ th second resistor.

3. DC voltage switch (12, 20) according to claim 1 or 2 with a parallel to the secondary side of the transformer (14) connected diode (271).

4. DC voltage switch (12, 20) according to one of the preceding claims, wherein

- The secondary current path comprises an antiserial to the semiconductor switch (15) connected further semiconductor switch (25), - The main current path comprises the primary side of another Transfor ^¬ mators (24).

5. DC voltage switch (12, 20) according to claim 4, wherein

the secondary sides of the transformers (14, 24) are connected in series,

- Of the secondary side of the transformer (14) ^{abgewand ¬} te connection of the secondary side of the further transformer (24) via a further switch (252) to the third terminal (123) is connected.

6. DC voltage switch (12, 20) according to any one of the preceding claims, wherein the voltage source (161) comprises a capacitor (161).

7. DC voltage switch (12, 20) according to claim 6, wherein the capacitor (161) is connected to a device for charging the capacitor (161).

8. DC voltage switch (12, 20) according to one of the preceding claims, wherein the mechanical switch (13) a

Switch with a switching time of less than 5 ms.

9. DC voltage switch (12, 20) according to any one of the preceding claims with a switch for shorting the secondary-side winding of the transformer (14).

10. DC voltage switch (12, 20) according to any one of the preceding claims, wherein the voltage source (161) is an intermediate circuit capacitor of an inverter.

11. HVDC network with a DC voltage switch (12, 20) according to one of the preceding claims.

12. vehicle, in particular rail vehicle with a ^DC voltage ^{switch ¬} (12, 20) according to one of the preceding claims.