WO2008031669A1

WO2008031669A1 - Apparatus for rapid discharge of capacitors

Info

Publication number: WO2008031669A1
Application number: PCT/EP2007/057742
Authority: WO
Inventors: Arndt Wagner
Original assignee: Robert Bosch Gmbh
Priority date: 2006-09-14
Filing date: 2007-07-27
Publication date: 2008-03-20
Also published as: DE102006043950A1

Abstract

The invention describes an apparatus for the rapid discharge of capacitors (3), in particular intermediate-circuit capacitors or intermediate-circuit capacitances in an electrical system, with the aid of which the rapid discharge can take place given pre-determinable conditions and with the battery (4) disconnected via two changeover switches (10a) and (10b). The changeover switches are in this case designed in such a way that two of their switching contacts are coupled to one another via a connection (12).

Description

description

title

Device for fast discharge of capacitors

Disclosure of the invention

The invention relates to a device for the rapid discharge of capacitors with the features of claim 1, in particular of DC link capacitors or DC link capacitances in a motor vehicle electrical system

State of the art

It is known that existing in vehicle electrical systems capacitors, in particular DC link capacitors or DC link capacitances, using a suitable

If necessary, quickly unload the circuit. Such a device for the rapid discharge of capacitors in a two-voltage electrical system is described for example in DE-OS 10 2004 057 693. The discharge takes place by means of a main contactor which cooperates with a DC-DC converter, and allows the discharge of the capacitors via the DC-DC converter in the low-voltage electrical system.

Object of the invention

The invention is a very fast discharge of the DC link capacitor or the

Enable link capacitors in a vehicle electrical system after separation of the traction battery, with no losses to be caused in normal operation This object is achieved by a device having the features of claim 1. The advantage of the invention is to provide a device or circuit that provides a cost-effective way to quickly discharge the DC link capacitor or the DC link capacity in the traction board network. Thus, according to the presumed standard, the voltage in the traction vehicle electrical system can be advantageously lowered after switching off within a very short time of, for example, 5 seconds below 65 volts. This is not possible with conventional circuit arrangements since the discharge time until the traction network reaches a normally harmless voltage range is several minutes. The above-mentioned advantage is achieved by using a switching device with two changeover contacts, instead of a main contactor provided in conventional devices, which is designed such that it enables a discharge of the intermediate circuit capacitor with appropriate control. ,

Further advantages of the invention are achieved by the measures specified in the dependent claims. Advantageously, one contact each is the other

Changeover contacts connected to each other. In an advantageous Ausgestaltng the switching device is integrated into the main contactor. Further advantages are achieved by providing a current limit which limits the maximum possible current to predefinable values.

An advantageous application possibility is in the traction network of a hybrid vehicle. The charging methods for capacitors are advantageously carried out under certain conditions, thereby ensuring that the battery is disconnected.

drawing

The invention is illustrated by the figures 1 to 3 of the drawing. 1 shows a circuit for the typical structure of a conventional electrical system in a hybrid vehicle. Figure 2 shows an embodiment of the invention and in Figure 3a or 3b, the current curves for the device of the embodiment according to

Figure 2 is shown for two typical conditions.

The circuit shown in Figure 1 shows the typical structure of a vehicle electrical system for a hybrid system, as it is currently eingesetrt in vehicles, with an electric machine 1, a pulse-controlled inverter 5, a high-voltage or Traktionsnetzbatterie 4, the actual traction network 8, which is also referred to as an intermediate circuit and, by way of example, another traction network consumer 6. The further traction network consumer 6 is only symbolic of several consumers in this network. Included in the pulse inverter 5 is at least one intermediate circuit capacitor 3 with a large capacity. Typical values of the capacity are in the range of 1

Millifarad (1 mF). The DC link capacitor should symbolically also include other, possibly existing DC link capacitances. Furthermore, the circuit comprises a plurality of semiconductor circuits with control, which are summarized in simplified form as block 2.

In the other consumers 6 also more intermediate circuit capacitors can be installed according to the DC link capacitor 3. In addition to the components mentioned is still a main contactor 7, which has two make contacts 9, in the traction network 8, with which the battery can be separated at predetermined conditions. When the vehicle is turned off, the main contactor 7 is normally opened. The contacts of the main contactor 7 are then in the position shown in Figure 1. The circuit shown in Figure 1 offers no way to discharge the DC link capacitor 3.

FIG. 2 shows an exemplary embodiment of the invention which offers a possibility of discharging the intermediate circuit 8 or the intermediate circuit capacitor 3 as well as any additional DC link capacitances which may be present quickly and safely. For this purpose, instead of the two make contacts 9 of the main contactor 7 of Figure 1 switching means 10 with two changeover contacts 10a and 10b connected in accordance with the circuit shown. Depending on a contact of the changeover contacts 10a and 1 Ob are connected via a connection 12 to each other. The changeover of the changeover contacts, for example, by the appropriately modified contactor 7 or via a corresponding control ..

Alternatively, a short circuit switch, which is arranged parallel to the capacitor 3, could be used. Then, however, it would have to be ensured that such a switch is never closed as long as the main contactor 7 is closed. With the solution according to the invention according to Figure 2, this is ensured in a simple manner. - A -

In the connection between the capacitor 3 and the associated changeover contact 1 Whether the contactor 7, so the path that short-circuits the capacitor 3 when the contact 1 is closed, optionally further circuit components 11 may be used, in particular current-limiting elements such as resistors, inductors or a combination of resistors and / or inductors. The

Circuit components 11 may be semiconductor devices. The circuit components which enable a rapid discharge of the intermediate circuit capacitor 3 or the existing DC link capacitances, that is to say in particular the switching means 10 or the changeover contacts 10a and 10b and / or the circuit components 11, can also be present in the already existing one, for example

Main contactor 7 are integrated. The changeover contacts can also be designed as electronic switches and in particular comprise insulated gate bipolar transistors IGBT.

With the circuit shown in Figure 2 can be a device for fast

Discharge of capacitors realize that can be used in any electrical network. In this case, the electrical network, preferably a high-voltage network or a traction network, including the capacities therein in a motor vehicle, can be quickly discharged or short-circuited. A mechanical lock that prevents the incorrect activation of the

Battery is short-circuited, can be installed. The traction network is for example part of a power supply in a hybrid vehicle.

In the figures 3 a and 3b current waveforms for two different switching states of the changeover contacts 10 are indicated which illustrate how the rapid discharge of

DC link capacitors or the DC link capacitor 3 works. In normal operation, shown in Figure 3b, the battery is switched on and the current flows, as shown by the arrows, over the closed changeover contact 10a and the closed changeover contact 10b to the DC link capacitor 3. If the battery 4 is switched off, the changeover contacts 10a and 10b open.

At the same time, a connection is established between the changeover contacts 10a and 1b via which the intermediate circuit capacitor 3 is discharged. By simultaneously switching the changeover contacts 10a and 10b, it is possible to achieve fast discharge of the intermediate circuit capacitor as the battery 4 is switched off.

Claims

claims

1. Device for the rapid discharge of capacitors, in particular at least one intermediate circuit capacitor or a DC link capacitance in an electrical network, wherein the capacitors, in particular the DC link capacitor via switching means with an electrical

Charge memory, in particular a battery, are connectable, characterized in that the switching means (10) at least two changeover contacts (10a, 10b), which are switchable in a predeterminable manner and cause a corresponding discharge of the capacitor (3).

2. Device for rapid discharge of capacitors according to claim 1, characterized in that in each case a contact of the changeover contact (10a) and the changeover contact (10b) is connected to each other via a connection (12).

3. Apparatus according to claim 1 or 2, characterized in that the

Switching means switching means (10) comprise a contactor (7).

4. Device for rapid discharge of capacitors according to claim 1, 2 or 3, characterized in that the intermediate circuit capacitor via an inverter (5) with an electrical machine (1) is in communication.

5. Device according to one of the preceding claims, characterized in that the electrical network is a traction network.

6. A device for rapid discharge of capacitors according to claim 5, characterized in that the traction network is part of a power supply in a hybrid vehicle.

7. Device for the rapid discharge of capacitors according to one of the preceding claims, characterized in that in the connection between the DC link capacitor (3) and the switching means, the means (10) for current limiting (11) are connected, which comprise at least one resistor and / or at least one inductance.

8. Device for the rapid discharge of capacitors according to one of the preceding claims, characterized in that the switching means (10) are electronic switches and in particular Insulated Gate bipolar transistors comprise IGBT.

9. A method for rapid discharge of capacitors with a device according to one of the preceding claims, characterized in that the changeover of the changeover contacts takes place so that in each case both changeover contacts are switched.

10. A method for rapid discharge of capacitors according to claim 8, characterized in that the rapid discharge takes place only when disconnected battery (4).