阅读说明：本技术 直流网络 (Direct current network ) 是由 K.汉特 S.汉塞尔 B.库希尔 J.维斯 于 2020-03-12 设计创作，主要内容包括：本发明涉及一种直流网络,该直流网络具有电导体和布置在导体的一端的开关单元,开关单元用于分离经由导体进行的电连接,其中,开关单元包括串联连接在导体的电流路径中的至少一个可控的功率半导体,其中,-从开关单元出发,导体被分为第一和第二区段,-第一过电压保护设备连接在第一和第二区段的连接点与直流网络的第二极之间,-第二过电压保护设备连接在第二区段的远离开关单元的一端与第二极之间,-过电压保护设备分别具有电容器。(The invention relates to a direct current network having an electrical conductor and a switching unit arranged at one end of the conductor for separating an electrical connection made via the conductor, wherein the switching unit comprises at least one controllable power semiconductor connected in series in the current path of the conductor, wherein-starting from the switching unit, the conductor is divided into a first and a second section, -a first overvoltage protection device is connected between the connection point of the first and second section and a second pole of the direct current network, -a second overvoltage protection device is connected between the end of the second section remote from the switching unit and the second pole, -the overvoltage protection devices each have a capacitor.)

1. A direct current network (10) having electrical conductors (121, 122) and a switching unit (19) arranged at one end of the conductors (121, 122) for separating an electrical connection made via the conductors (121, 122), wherein the switching unit (19) comprises at least one controllable power semiconductor connected in series in a current path of the conductors (121, 122), wherein,

-starting from the switching unit (19), the conductor (121, 122) is divided into a first and a second section (141, 142, 144, 145),

-a first overvoltage protection device (181, 183) is connected between the connection point of the first and second sections (141, 142, 144, 145) and the second pole of the direct current network (10),

-a second overvoltage protection device (182, 184) is connected between an end of the second section (142, 145) remote from the switching unit (19) and the second pole,

-the overvoltage protection devices (181 … 184) each have a capacitor (30).

2. Direct current network (10) according to claim 1, having at least one load (16), a plurality of further switching units and a plurality of further electrical conductors which connect the switching units and the load (16) and which are divided into sections, wherein for the connection points of the respective two connected sections of the further conductors an overvoltage protection device is connected between the connection point and the second pole.

3. The direct current network (10) as claimed in claim 2, wherein the switching unit (19) and the further switching unit are identically constructed.

4. The direct current network (10) according to any one of the preceding claims, wherein the length or the inductance of the section (141 … 146) is selected such that an overvoltage formed when opened by the switching unit (19) remains below a breakdown voltage of the controllable power semiconductor.

5. The direct current network (10) according to any one of the preceding claims, wherein the switching unit (19) comprises a switching unit capacitor connected between a first pole and a second pole of the direct current network and having a capacitance of at least 10 μ F, in particular at least 50 μ F, in particular at least 100 μ F.

6. The direct current network (10) according to one of the preceding claims, wherein the capacitors (30) of the overvoltage protection devices (181 … 184) each have a capacitance of at least 10 μ Ρ, in particular at least 50 μ Ρ, in particular at least 100 μ Ρ.

7. The direct current network (10) according to one of the preceding claims, wherein the overvoltage protection devices (181 … 184) each have a resistance (31) for oscillation damping connected in series with the capacitor (30), in particular a resistance of less than 10 ohms.

8. The direct current network (10) according to any one of the preceding claims, wherein the overvoltage protection devices (181 … 184) each comprise a diode (32) connected in series with the capacitor (30), wherein the diodes (32) are connected for blocking a current flow from the capacitor (30) to the first pole.

9. The direct current network (10) according to any one of the preceding claims, wherein the overvoltage protection device (181 … 184) comprises a spark gap (33) connected in series with a capacitor (30).

10. The direct current network (10) according to any one of the preceding claims, wherein the overvoltage protection device (181 … 184) has a controllable power semiconductor, in particular a thyristor (34), connected in series with the capacitor (30).

11. The direct current network (10) according to any one of the preceding claims, wherein the overvoltage protection device (181 … 184) comprises an overvoltage element, in particular a varistor (36), in parallel with the capacitor (30).

12. The direct current network (10) according to any one of the preceding claims, wherein the overvoltage protection device (181 … 184) comprises a discharge resistor (35) in parallel with the capacitor (30).

Technical Field

The invention relates to a direct current network having a first pole and a second pole and at least one switching unit for separating the conductors of the first pole.

Background

In future industrial installations, the DC network should reduce losses, ensure a direct energy exchange between converter, storage and motor, and achieve an increased robustness. This type of network may have very different cable lengths between different load outlets and power supplies (einspeisung). The short cable lengths present here result in very low longitudinal inductances in the supply lines, so that the fault currents can have a very steep rise in current. Thus, very fast fault identification and fault disconnection are required. Power semiconductors are used because mechanical disconnect switches cannot meet the requirements for switching speed. After the fault is identified, the power semiconductor switches off the fault within a few hundred nanoseconds. Since the current through the load inductance now has no free-wheeling path, a voltage may then develop across the power semiconductor, which may in some cases damage the power semiconductor. To cope with this problem, the switch may have an overvoltage limitation. Disadvantageously, the overvoltage limitation must be designed for each switch for the actual line length or feeder inductance, i.e. the switch must be adapted to the feeder present, or the switch is only allowed to be used before a specific line length, since otherwise there is a risk of insufficient overvoltage limitation.

Disclosure of Invention

The object of the present invention is to provide a dc network which alleviates or solves the problems mentioned at the outset. The above-mentioned technical problem is solved by a direct current network having the features of claim 1.

The direct current network according to the invention has an electrical conductor and a switching unit arranged at one end of the conductor for separating the electrical connections made via the conductor. The switching unit comprises at least one controllable power semiconductor connected in series in the current path of the conductor.

Starting from the switching unit, the conductor is divided into a first and a second section. In other words, the first section extends from the switching unit to a connection point of the first section and the second section. The second section extends from the connection point.

A first overvoltage protection device is connected between the junction of the first and second sections and the second pole of the dc network. That is, the conductor forms a first pole of the dc network. A second overvoltage protection device is connected between the end of the second section remote from the switching unit and the second pole. That is, the first and second overvoltage protection devices are connected in parallel; however, there are conductors having the length of the second section between their connection points with the conductor, i.e. with the first pole of the direct current network. Between the connection point of the first overvoltage protection device and the switching unit, a conductor is present having the length of the first section.

The overvoltage protection devices each have a capacitor.

The length of the first and second sections is expediently at least greater than 1m, in particular greater than 10m, in a particular embodiment greater than 50 m.

The invention advantageously achieves that the switching unit is protected by an overvoltage protection device arranged on the conductor in a spaced-apart manner in order to prevent overvoltage from building up which occurs during the opening by the switching unit and has a damaging or destructive effect on the power semiconductors. In this case, the switching unit itself only has to be designed for the overvoltage caused by the inductance of the closest section, i.e. the first section. In contrast, the inductance of the second section no longer plays a role for this.

It is recognized for the invention that instead of the adaptation of the switching unit, an adaptation of the conductor in the form of an overvoltage protection device can be used. Therefore, it is preferred that similar protection devices and similar switching units can be used in the dc network. That is, although more components are used compared to a network using adapted switching cells, only similar components are used for this purpose, which leads to a reduction in the overhead and an increase in the reliability. This allows a better planning and control of the dc network.

An overvoltage protection device with a capacitor between the poles of the dc network advantageously provides voltage stability and regulation reserve. Since this capacitor forms an oscillatable system with the line inductance, there is a series resistance as damping.

Advantageous embodiments of the dc network according to the invention result from the dependent claims of claim 1. The embodiments according to claim 1 can be combined with features of one of the dependent claims or, preferably, also features from a plurality of dependent claims. Accordingly, the following features may additionally be provided:

the direct current network may comprise one or more loads, a plurality of further switching units and a plurality of further electrical conductors, wherein the further conductors connect the switching units and the loads. The further conductors are likewise divided into sections, wherein, for the connection points of the respective two connected sections of the further conductors, an overvoltage protection device is connected between the respective connection point and the second pole. In other words, in the vast dc networks, these further switching cells are also protected against excessive overvoltages by embedding overvoltage protection devices in the conductors.

Preferably, in the dc network, the switching unit and the further switching unit are identically constructed. In other words, only one type of switching unit designed for the maximum voltage to be blocked is used. The length of the segments or the inductance is expediently selected such that the overvoltage which forms when one of the switching units is switched off remains below the breakdown voltage of the controllable power semiconductor. In general, that is to say for the purpose of disconnection in a dc network, it is advantageous to use only two different types of components, namely one switching unit and one overvoltage protection device.

The switching unit may comprise a switching unit capacitor connected between the first and second poles of the direct current network and having a capacitance of at least 10 μ F, in particular at least 50 μ F, in particular at least 100 μ F. Thus, the switch itself also has the inherent ability to absorb over-voltages induced by a particular conductor without damage.

The capacitors of the overvoltage protection device can each have a capacitance of at least 10 μ F, in particular at least 50 μ F, in particular at least 100 μ F. A sufficiently large capacitance acts on the voltage stably enough to effectively relieve the load of the switching unit.

The overvoltage protection devices may each have a resistor connected in series with a capacitor for oscillation damping, in particular may have a resistance of less than 10 ohms. In this way, oscillations are avoided in the oscillatable system formed by the capacitor and the line inductance, wherein at the same time the possibility of a rapid charging of the capacitor is ensured due to the low resistance.

The overvoltage protection device may comprise a diode connected in series with the capacitor, wherein the diode is connected such that a current flow from the capacitor to the first pole of the direct current network is blocked. This connection enables energy to be absorbed quickly by the capacitor in the event of a break in the event of a short circuit. Further, the discharge is suitably allowed, but decelerated by the resistance.

The overvoltage protection device may comprise a spark gap connected in series with a capacitor. Which, when an inadmissibly high voltage is built up across the resistor, produces a low-ohmic current path which enables energy to be quickly absorbed by the capacitor.

The overvoltage protection device may have a controllable power semiconductor, in particular a thyristor, connected in parallel with a resistor. This enables a low-ohmic current path to be switched on.

The overvoltage protection device may comprise an overvoltage element, in particular a varistor, in parallel with the capacitor. Furthermore, a discharge resistance can be present in parallel with the capacitor, wherein the discharge resistance is in particular greater than 1kOhm, in particular greater than 10kOhm or greater than 100 kOhm. The discharge of the capacitor is supported in this way by discharging energy in the event of an excessively high voltage at the capacitor and making the overvoltage protection device ready for use again quickly upon repeated triggering.

The switching device may comprise a second power semiconductor, wherein the two power semiconductors are connected in anti-series or anti-parallel. The power semiconductor may be an IGBT, for example.

Drawings

Further advantages and features result from the following description of an embodiment with the aid of the drawing. In the drawings, like reference numerals refer to like elements and functions.

Figure 1 shows a dc network with switching cells for separating electrical conductors and an overvoltage protection device,

fig. 2 to 6 show variants of the overvoltage protection device.

Detailed Description

Fig. 1 schematically shows a dc network 10. The dc network 10 includes a dc voltage source 11 and a load 16, which are interconnected by electrical conductors 121.. 123. Here, the two first conductors 121, 122 together form a first pole of the direct current network 10, while the third conductor 123 forms a second pole. The two first conductors 121, 122 are connected to each other in series, wherein a switching unit 19 is arranged at the connection point thereof.

The switching unit 19 serves as an interrupter for the electrical connection from the direct voltage source 11 to the load 16. For example, if a fault, i.e. a short circuit, occurs in the region of the load 16 and a very high current flows from the dc voltage source 11 to the short-circuit point, an interruption may be necessary. The switching unit 19 comprises at least one power semiconductor which is connected in series between the two first conductors 121, 122 and can interrupt the current path through these conductors. In an alternative embodiment, the switching unit 19 may also comprise two power semiconductors connected in series in opposite directions.

Since there is no free-wheeling path for the current when the current path is interrupted by the switching unit 19, an excessively high voltage develops on the switching unit 19, i.e. on the power semiconductor, shortly after the interruption. The magnitude of this excess voltage is particularly relevant to the magnitude of the inductance storing the electrical energy. The size of the inductance is in turn decisively determined by the inductance of the two first conductors 121, 122 adjacent to the switching unit. The longer these conductors 121, 122 are, the greater their inductance is. In order to avoid the need to adapt the switching unit 19 to the conductor length, the two first conductors 121, 122 are divided into sections 141.. 146. Here, in this example, the segments 141.. 146 are selected such that the conductor length of each segment 141.. 146 does not exceed 100 m. Thus, the maximum inductance of each of the sections 141.. 146 is determined. In an alternative embodiment, the section 141.. 146 is selected according to a defined maximum inductance of, for example, 50 μ H. In this variant, it is advantageously not necessary to pay attention to whether the conductors 121, 122 are similar or whether different electrical conductors are used, in order to maintain the maximum inductance of each segment 141.. 146.

An overvoltage protection device 181.. 184 is arranged at the connection between each two adjacent segments 141.. 146. The overvoltage protection device 181 … 184 is connected between a connection point located in the two first conductors 121, 122 and thus being part of the first pole of the dc network 10 and a second pole in the form of a third conductor 123. That is, the overvoltage protection devices 181, 182 in the first conductor 121 are connected in parallel, except for the inductance 152 of the second section 142 located in the middle. Likewise, the overvoltage protection devices 183, 184 in the second conductor 122 are connected in parallel, with the exception of the inductance 155 of the fifth central section 145.

The overvoltage protection device 181.. 184 ensures that the formation of overvoltages in the conductors 121, 122 is prevented or delayed in sections when the current flow is interrupted by the switching unit 19. It is thereby achieved that the overvoltage occurring at the switching unit 19 is limited to acting on the inductance of the segments 141, 144 located directly at the switching unit 19. The switching unit 19 is expediently designed for such overvoltages. That is to say, it is thereby achieved that the switching unit 19 can also be used without adaptation when the adjacent electrical conductors 121, 122 are significantly longer than is permissible for the largest inductance value for the switching unit 19. That is, instead of changing the switching unit 19, the design of the conductors 121, 122 is adjusted, and the conductors 121, 122 are provided with overvoltage protection devices 181.. 184. The switching cells themselves have overvoltage protection, not shown, which is sufficient for the line length or inductance of adjacent switching cells, for example for an inductance of 100 muh.

A real dc network 10 in an industrial environment is generally more complex and comprises a plurality of loads 16, a plurality of electrical conductors 121.. 123, which partly have different lengths, and a plurality of switching units 19. Furthermore, it may also have branches. The dc network 10 of fig. 1 can therefore be regarded as a simplified segment of a real dc network. However, the invention also makes it possible to use only a single-structure switching unit 19 in a wide range of dc networks 10. The overvoltage protection device 181.. 184 also preferably has only one configuration.

Fig. 2 to 6 show possible variants of the structure of the overvoltage protection device 181.. 184. In principle and as the simplest variant of embodiment, the capacitor 30 is sufficient as an overvoltage protection device 181.. 184. Capacitor 30 provides voltage stability and regulation reserve. However, the series resistor 31 is advantageous as a damping since this capacitor 30 forms an oscillatable system with the line inductance 151.. 156. Such an overvoltage protection device 20 is shown in fig. 2.

Fig. 3 shows an extended overvoltage protection device 21 according to the embodiment of fig. 2, in which a diode 32 is present in parallel with the series resistor 31. The diode 32 allows the capacitor 30 to absorb energy very quickly, which is limited in the embodiment according to fig. 2 by the series resistance 31. Especially when short circuits are broken, it is important that the energy is absorbed very quickly. However, the discharge continues to decay through the series resistor 31.

Fig. 4 shows an alternative to the use of a diode 32. In the overvoltage protection device 22 according to fig. 4, a spark gap (funkenstrcke) 33 is arranged in parallel with the series resistor 31 for providing a low-ohmic current path in the event of an inadmissibly high voltage being generated across the series resistor 31. If the voltage across the spark gap 33 becomes sufficiently small, the arc in the spark gap 33 is extinguished again. The discharge of the capacitor 30 takes place again via the series resistor 31.

Another alternative is shown in fig. 5. In this overvoltage protection device 23, a low-ohmic current path can be switched via the triggered semiconductor component, for example in this example via a thyristor 34. If the current through thyristor 34 is here less than its holding current, thyristor 34 becomes high-ohmic again. The discharge of the capacitor 30 takes place again via the series resistor 31.

In the overvoltage protection device 24 according to fig. 6, the discharging of the capacitor 30 is supported by a discharge resistor 35 and an overvoltage element, for example a varistor 36 shown here, in order to dissipate energy when the voltage across the capacitor 30 is too high and to make the protection circuit ready for use again quickly upon repeated triggering. Here, the discharge resistor 35 and the varistor 36 are arranged in parallel with the capacitor 30. In this example, a diode 32 is arranged in series with the capacitor 30. However, this example can also be combined with the embodiments of fig. 3 to 5, i.e. here, a series resistor 31 or a spark gap 33 can also be used in series with the capacitor 30.

List of reference numerals

10 DC network

121 … 123 electric circuit

Section 141 … 146

Inductance of segment 151 … 156

11 d.c. voltage source

19 switch unit

16 load

181 … 186 overvoltage protection device

20 … 24 variant of overvoltage protection device

30 capacitor

31 series resistance

32 diode

33 spark gap

34 thyristor

35 discharge resistor

36 rheostat