DE102006062101A1 - Intermediate circuit capacitor discharging device for power electronics of hybrid drive system, has potentiometer circuit designed such that intermediate circuit capacitor is discharged by potentiometer circuit - Google Patents

Abstract

The device has a potentiometer circuit (12) comprising two potentiometer connections (16, 20) and a potentiometer tapping point (28). The two potentiometer connections are electrically and conductively connected with two electrode connections (22, 24), respectively. A measurement voltage produced by a voltage (Uzk) of an intermediate circuit capacitor (Czk) lies on the potentiometer tapping point. The potentiometer circuit is designed in such a manner that the intermediate circuit capacitor is discharged by the potentiometer circuit.

Description

The The invention relates to a device for discharging the DC link capacitor the power electronics of a hybrid drive system according to claim 1.

In a hybrid propulsion system, different components work together, the above High-voltage cables are connected together. One of these components is the power electronics of the drive system. This is needed for operation an intermediate circuit capacitor as an energy buffer. In power electronics is the DC link voltage, d. H. that at the DC link capacitor applied voltage measured, for example, the correct function to check the power electronics. Farther is it important for security reasons that the DC link capacitor when switching off the drive system is discharged by a discharge device. So far, both to Measuring the DC link voltage as well as discharging the DC link capacitor used separate devices, in particular components. Thereby will the boards for the electronics of the drive system due to the different required Components relatively large, what a big one leads to required installation space, the possibly for one other vehicle component is no longer available.

It is therefore an object of the present invention, an improved Device for discharging the intermediate circuit capacitor of the power electronics to propose a hybrid drive system.

These The object is achieved by a device for discharging the DC link capacitor the power electronics of a hybrid drive system with the features of claim 1 solved. Further embodiments of the invention will become apparent from the dependent claims.

One essential idea of the present invention is to provide a Provide voltage divider circuit on the DC link capacitor, on the one hand allows a measurement of the DC link voltage and on the other hand, in particular by appropriate dimensioning so is formed, that they are for discharging the DC link capacitor suitable is. This can reduce the effort to implement a Discharge device for the DC link capacitor and measuring device for a the DC link voltage derived measuring voltage can be reduced, because fewer components needed which reduces the board space required for implementation and the cost can be reduced. The voltage divider circuit fulfilled after The invention has a dual function, namely the generation of an evaluable Measuring voltage from the DC link voltage and the discharge of the DC link capacitor.

The present invention now according to an embodiment of the invention relates to a device for discharging the link capacitor of the power electronics of a hybrid drive system, with the following features:
the DC link capacitor has a first electrode terminal and a second electrode terminal;
a voltage divider circuit is provided having a first voltage divider terminal, a second voltage divider terminal, and a voltage divider tap point;
the first voltage divider terminal is electrically conductively connected to the first electrode terminal and the second voltage divider terminal is electrically conductively connected to the second electrode terminal;
at the voltage divider tapping point, a measuring voltage generated from the voltage at the intermediate circuit capacitor is present; and
the voltage divider circuit is designed such that the intermediate circuit capacitor can be discharged by means of the voltage divider circuit.

Of the second voltage divider terminal can be connected via a ground connection be connected to the second electrode terminal.

According to one another embodiment According to the present invention, the voltage dividing circuit between the first voltage divider terminal and the voltage divider tap point have a resistor with a resistance that is a multiple, in particular at least ten times the resistance value of a Resistance between the voltage divider tapping point and the second Voltage divider terminal has. Such a design The present invention has the advantage that at the voltage divider tap point a much lower voltage than at the DC link capacitor which can be detected with less effort.

According to one another embodiment According to the invention, the voltage divider may be a plurality of in series switched individual resistors between the first voltage divider terminal and the voltage divider tap point include. For thermal and insulation reasons, this is Embodiment of advantage, since at a discharge of the DC link capacitor diverts to be converted electrical energy to a plurality of resistors, be optimized for receiving a corresponding proportion of energy can.

The individual resistors can according to a another embodiment of the invention have an identical resistance value. As a result, the discharge energy to be converted is divided equally between the resistors, ie each resistor is loaded approximately equally.

To a further embodiment of the invention between the first voltage divider terminal and the voltage divider tap point several, in particular seven individual resistors with a value that one Fraction of the total resistance corresponds, in particular a value each arranged about 14 kΩ and a resistance between the voltage divider tap point and the second voltage divider terminal may have a value that is also a fraction of the total resistance corresponds, in particular have a value of about 2 kΩ. This results in a voltage ratio between the first and second Voltage divider connection as well as the voltage divider tap point of about 2 percent, so that by such a choice of resistors one sufficient reduction of from a voltage measuring device to measuring voltage in comparison to that at the DC link capacitor applied voltage results.

The Voltage divider circuit may according to another embodiment the invention also have a plurality of resistors, the like are dimensioned to be a power from the DC link capacitor be able to record, without being damaged to become, for example, by overheating.

According to one another embodiment The invention may further include a voltage measuring device for measuring the measurement voltage between the voltage divider tap point and the be provided second voltage divider terminal, which formed is to the voltage applied to the DC link capacitor voltage to determine the basis of the measuring voltage.

Finally, can according to a another embodiment the invention, the voltage measuring device information about resistance values of resistances comprise between the first voltage divider terminal and the Voltage divider tap point as well as between the voltage divider tap point and the second voltage divider terminal are used. Under Utilization of the proportional division ratio can thus be a unique Determining the voltage drop across the DC link capacitor respectively.

Further embodiments The invention relates to a power electronics of a hybrid drive system and a hybrid drive system comprising the device of the invention.

Further Advantages and applications The present invention will become apparent from the following description in connection with the embodiment shown in the single drawing.

In the description, in the claims, in the abstract and in the drawing those in the back cited List of reference symbols used terms and associated reference numerals used.

The Drawing shows in the only Fig. A basic circuit diagram an embodiment of the present invention.

in the Following can identical and / or functionally identical elements with the same reference numerals be provided. The absolute values given below and dimensions are only exemplary values and do not represent a limitation of Invention on such dimensions.

In the single FIGURE is a power electronics of a hybrid drive system with a first network 10 and a second network (converter circuit) 18 represented, which are coupled via a DC link with a DC _link capacitor C _ZK . In the intermediate circuit there is usually a fairly high electrical voltage, which can be dangerous for living things and therefore must be discharged when switching off the hybrid drive system.

From the first network 10 Off is via a supply voltage connection 14 the intermediate circuit capacitor C _ZK charged with a supply voltage to the intermediate _circuit voltage U _ZK . The intermediate circuit capacitor C _ZK is for this purpose between the supply voltage terminal 14 and a ground potential connection 16 connected.

To the intermediate circuit capacitor C _ZK is the converter circuit 18 connected in parallel by a first connection 20 the converter circuit 18 with a first electrode 22 of the DC _link capacitor C _ZK and a second electrode 24 of the DC link capacitor C _ZK with the ground potential connection 16 electrically conductive are connected. The converter circuit 18 is also connected to the ground potential connection with a second connection 16 connected.

The converter circuit 18 includes a voltage divider circuit 12 , which is a resistor series circuit 26 and a single divider resistor R8. Between the resistor series circuit 26 and the divider resistor R8 is a voltage divider tap point 28 intended. Furthermore, the converter circuit comprises 18 a DC link voltage measurement 30 who trained is a voltage between the voltage divider tap point 28 and the ground potential connection 16 to measure and from this the DC link _voltage U _ZK to determine. For this purpose, the DC link voltage measurement has 30 an information about the resistance values of the resistor series circuit 26 and the divider resistor R8, whereby it can conclude on the knowledge of the proportional division ratio of the voltage divider from the determined measurement voltage to the voltage U _ZK dropping at the memory device or the intermediate circuit capacitor C _ZK .

The resistor series circuit 26 may comprise a series connection of seven identical resistors R1 to R7. In the present case, seven resistors with a resistance of about 14 kΩ are used. The divider resistor R8 has a value of about 2 kΩ, so that between the voltage divider tap point 28 and the ground potential connection 16 only a voltage of about two percent of the voltage between the first terminal 20 the converter circuit 18 and the ground potential connection 16 (ie the intermediate circuit voltage U _ZK ) is present. For the resistors of the resistor series circuit 26 Resistance types are used, which withstand a high heat load. The divider resistor R8 can also be designed in this way. This can ensure that the converter circuit 18 when unloading the intermediate circuit capacitor C _ZK suffers no damage. A release of heat during discharge of the intermediate circuit capacitor C _ZK is thus not locally concentrated, but takes place in the separate individual resistors R1 to R7. As a result, overheating of individual resistors can be avoided.

When switching off the hybrid drive system should, however, for safety reasons, to reduce the high DC link voltage U _ZK and thereby maintenance personnel when performing maintenance (for example, on the first network 10 ) are not endangered by the high intermediate circuit _voltage U _ZK , the charge stored in the intermediate circuit capacitor C _ZK is reduced. Discharging is now done by the converter circuit 18 , The converter circuit 18 allows for this a current flow through the resistor series circuit 26 and the divider resistor R8, so that the charge of the intermediate circuit capacitor C _ZK and the intermediate circuit voltage U _{ZK can be} almost completely reduced.

In addition, during operation of the hybrid drive system, the intermediate circuit _voltage U _ZK at the intermediate circuit capacitor C _ZK (and thus the charge state of the intermediate circuit capacitor C _ZK ) by means of the intermediate _circuit measurement 30 be monitored. This exploits that the voltage divider circuit with the resistor series circuit 26 and the divider resistor R8 a predetermined proportional dividing ratio between the voltage drop between the first terminal 20 the converter circuit 18 and the voltage divider tap point 28 as well as the voltage divider tap point 28 and the ground potential connection 16 has. The voltage dropping across divider resistor R8 is thus proportional to the voltage drop across DC link capacitor C _ZK .

In summary, it should be noted that the intermediate circuit capacitor C _ZK can be discharged by switching off the system by a discharge device by the invention. This can be done by one or more resistors. At the same time, an intermediate circuit voltage can be measured with the invention. For this purpose, a voltage is divided down via a voltage divider. This voltage divider can be used at the same time as a discharge circuit with skillful dimensioning.

The Advantages of this invention consist on the one hand in a cost reduction and on the other hand in a space saving on a power electronics board, on which the essential components of the invention are mounted. Further, for the discharge of the DC link capacitor no separate device needed in the form of a special discharge circuit.

10

first network

12

Voltage divider circuit

14

Supply voltage connection

16

Ground potential terminal

18

second Network (converter circuit)

20

first connection of the converter circuit 18

22

first electrode

24

second electrode

26

Resistor series circuit

28

Spannungsabgriffspunkt

30

Between circuit voltage measurement

C _ZK

Link capacitor

U _ZK

Intermediate circuit voltage

R1-R7

individual resistors

R8

dividing resistor

Claims (10)

Device for discharging the intermediate circuit capacitor (C _ZK ) of the power electronics of a hybrid drive system, having the following features: - the intermediate circuit capacitor (C _ZK ) has a first electrode connection ( 22 ) and a second electrode terminal ( 24 ) on; A voltage divider circuit ( 12 ) is provided, which has a first voltage divider terminal ( 20 ), a second voltage divider terminal and a voltage divider tap point ( 28 ) having; The first voltage divider terminal ( 20 ) is connected to the first electrode terminal ( 22 ) electrically conductively connected and the second voltage divider terminal is connected to the second electrode terminal ( 24 ) electrically conductively connected; At the voltage divider tap point ( 28 ) is applied from the voltage (U _ZK ) at the DC link capacitor (C _ZK ) generated measurement voltage; and - the voltage divider circuit ( 12 ) is designed such that the intermediate circuit capacitor (C _ZK ) by means of the voltage divider circuit ( 12 ) can be unloaded. Device according to Claim 1, characterized in that the voltage divider circuit ( 12 ) between the first voltage divider terminal ( 20 ) and the voltage divider tap point ( 28 ) has one or more resistors with a resistance which is a multiple, in particular at least ten times, the resistance value of a resistor between the voltage divider tap point ( 28 ) and the second voltage divider terminal ( 16 ) having. Device according to claim 1 or 2, characterized in that the voltage divider ( 12 ) a plurality of series-connected individual resistors (R1-R7) between the first voltage divider terminal ( 20 ) and the voltage divider tap point ( 28 ). Device according to claim 3, characterized in that that the individual resistances (R1-R7) one have the same resistance. Device according to one of claims 1 to 4, characterized in that between the first voltage divider terminal ( 20 ) and the voltage divider tap point ( 28 ) several, in particular seven individual resistors (R1-R7) having a value which corresponds to a fraction of the total resistance, in particular a value of approximately 14 kΩ, are arranged, and a resistance between the voltage divider tapping point ( 28 ) and the second voltage divider terminal ( 16 ) has a value which also corresponds to a fraction of the total resistance, in particular a value of about 2 kΩ. Device according to one of claims 1 to 5, characterized in that the voltage divider circuit ( 12 ) has a plurality of resistors (R1-R8) sized to receive power from the link capacitor (C _ZK ) without being damaged. Device according to one of claims 1 to 6, characterized in that further comprises a voltage measuring device ( 30 ) for measuring the measurement voltage between the voltage divider tap point ( 28 ) and the second voltage divider terminal ( 16 ) is provided, which is designed to determine the voltage applied to the intermediate circuit capacitor (C _ZK ) voltage on the basis of the measurement voltage. Apparatus according to claim 7, characterized in that the voltage measuring device ( 30 ) comprises information about resistance values of resistors connected between the first voltage divider terminal ( 20 ) and the voltage divider tap point ( 28 ) and between the voltage divider tap point ( 28 ) and the second voltage divider terminal ( 16 ) are used. Power electronics of a hybrid drive system comprising a device ( 18 ) according to one of claims 1 to 8. Hybrid drive system comprising a device ( 18 ) according to one of claims 1 to 8.