DE102012222067A1 - Electronic circuit for use in inverter used for controlling three-phase motor of e.g. electric vehicle, has first, second and third electronic components designed as resistors, and fourth electronic component designed as capacitor - Google Patents

Abstract

The circuit (40) has an amplifier circuit (10) including an input connected with an end (8) of a strand (30), another input connected with a terminal of a first electronic component (2), and an output connected with a terminal of a second electronic component (3). A power amplifier circuit (15) includes an input connected with a terminal of a third electronic component (4), and an output connected with a terminal of a fourth electronic component (1), which is designed as a capacitor. The first, second and third components are designed as resistors.

Description

The present invention relates to an electronic circuit having four electronic components and an amplifier circuit and a power amplifier circuit and is adapted to dynamically increase the DC link capacitor of an inverter for an electric motor.

State of the art

It is known to assemble battery systems or batteries for use in hybrid and electric vehicles from a plurality of battery cells. In particular, so-called traction batteries, which are used within hybrid and electric vehicles for the supply of electric drives, are composed of a plurality of battery cells.

Furthermore, a large number of different inverters or inverter circuits or even converters for controlling electric motors, in particular three-phase motors or three-phase motors, are known from the prior art. For example, the DE 196 00 807 A1 an intelligent, separate half-bridge power module with at least one power transistor, with which the control of an electric motor is possible. Within the inverters of the prior art typically so-called link capacitors are installed, which have the task of attenuating the AC components caused by the inverter on a DC-HV network to which the inverter is connected.

For example, the DE 100 62 075 A1 a converter with integrated DC link capacitors which are connected to a voltage intermediate circuit of the converter.

The DC link capacitors of the prior art typically have a capacitance of 0.5 to 1.5 mF. Furthermore, they are large and expensive due to the required withstand voltage of over 400V.

Disclosure of the invention

According to the invention, an electronic circuit is provided which comprises four electronic components, which are electrically conductively connected to one another via their respective two terminals. The strand has a first and a second end. Furthermore, the electronic circuit comprises an amplifier circuit whose first input is connected to the first end of the string and whose second input is connected to the second terminal of the second electronic component. The output of the amplifier circuit is connected to the second terminal of the third electronic component. Furthermore, the electronic circuit comprises a power amplifier circuit whose first input is connected to the second terminal of the fourth electronic component and whose second input is connected to the second input of the amplifier circuit. The output of the power amplifier circuit is connected to the second terminal of the first electronic component. According to the invention, the first electronic component is designed as a capacitor, while the remaining electronic components are designed as resistors.

By such an electronic circuit, it is possible to increase the DC link capacitor of an inverter dynamically. As a result, the actually built intermediate circuit capacitor can be made smaller, whereby on the one hand costs are saved and on the other hand the installation space available for the realization of an inverter is expanded.

Preferably, the strand on a fifth electronic component, which is designed as a resistor. By choosing the size of such a resistor, the factor by which the capacitance of the DC link capacitor is multiplied can be influenced.

In a preferred embodiment, the electronic components are arranged starting from the first end of the strand according to their name ascending.

Preferably, the first end of the string is connected to an electrode of a snubber capacitor whose second electrode is connected to a constant potential. If the electronic circuit is connected, for example, to the inverter of an electric motor, among other things during the so-called recuperation, ie, the feedback of energy from the electric motor into, for example, a battery system, high-frequency voltage components can be damped by a damping capacitor.

The electrical connection between the first input of the amplifier circuit and the first end of the string preferably has a first capacitor. This first capacitor is used for decoupling the high-voltage, for example, a battery system from the first input of the amplifier circuit.

In a preferred embodiment, the power amplifier circuit further comprises two supply voltage terminals and is the same be adapted to be fed via these supply voltage terminals from a high-voltage network and to compensate for a ripple in the supply voltage provided by the high-voltage network. By such a design of the power amplifier circuit, damage from the same or from the electronic circuit can be averted. Furthermore, no expensive additional circuit must be provided for protection against fluctuations in the supply voltage within the electronic circuit.

In a preferred development of this embodiment, the supply voltage terminals of the power amplifier circuit are each connected to an output of a switching converter, which is connectable via at least one input to a high-voltage network and adapted to the supply voltage for the power amplifier circuit from the voltage provided by the high-voltage network produce. Switching converters are energy-saving and relatively insensitive to voltage or parameter variations, in particular in comparison with linear regulators.

In a preferred further development of this embodiment, the electrical connections between the supply voltage terminals of the power amplifier circuit and the outputs of the switching converter are each connected to an electrode of a respective second capacitor. The respective second electrodes of the second capacitors are each connected to a constant potential. Furthermore, the second capacitors are designed to provide the energy necessary for the compensation of the alternating voltage components of the high-voltage network over a predetermined duration of the power amplifier circuit. As a result, the power amplifier circuit and the remaining electronic circuit can be protected from voltage peaks of the high-voltage network.

Furthermore, an inverter is provided with an electronic circuit according to the invention. Furthermore, a motor vehicle is provided with an inverter having an electronic circuit according to the invention.

Advantageous developments of the invention are specified in the subclaims and described in the description.

drawings

Embodiments of the invention will be explained in more detail with reference to the drawings and the description below. Show it:

1 An embodiment of an electronic circuit according to the invention with four electronic components, and

2 a specific embodiment of an electronic circuit according to the invention with five electronic components.

Embodiments of the invention

In the 1 is an embodiment of an electronic circuit according to the invention 40 with four electronic components 1 . 2 . 3 and 4 shown. The electronic circuit according to the invention 40 includes four electronic components 1 . 2 . 3 . 4 , via their two connections electrically conductive together to form a strand 30 are connected. In this embodiment, the four electronic components 1 . 2 . 3 and 4 according to their name, that is according to their numbering, ascending, that is starting at the first end 8th of the strand 30 with the first of the electronic components 1 and ending with the fourth of the electronic components 4 , within the strand 30 arranged or to a strand 30 connected. In other words, each of the four electronic components 1 . 2 . 3 . 4 in each case two terminals, wherein in this embodiment, the second terminal of the first electronic component 1 with the first terminal of the second electronic component 2 connected is. The second terminal of the second electronic component 2 is connected to the first terminal of the third electronic component 3 connected while the second terminal of the third electronic component 3 with the first terminal of the fourth electronic component 4 connected is. In this embodiment, therefore, only the first terminal of the first electronic component is 1 and the second terminal of the fourth electronic component 4 connected to no other connection. By contrast, these two last-mentioned connections each have one end 8th . 9 of the strand 30 connected. The first connection of the first electronic component 1 is with the first end 8th of the strand 30 connected while the second terminal of the fourth component 4 with the second end 9 of the strand 30 connected is.

The electronic circuit 40 further comprises an amplifier circuit 10 having a first and a second input and an output. The first input of the amplifier circuit 10 is with the first end 8th of the strand 30 connected during the second input of the amplifier circuit 10 to the second terminal of the second electronic component 2 that is, between the second and the third electronic component 2 . 3 with the strand 30 connected is. The output of the amplifier circuit 10 is connected to the second terminal of the third electronic component 3 So between the third and the fourth electronic component 3 . 4 with the strand 30 connected. Furthermore, the electronic circuit includes 40 a power amplifier circuit 15 which also includes a first and a second input, as well as an output. The first input of the power amplifier circuit 15 is connected to the second terminal of the fourth electronic component 4 So with the second end 9 of the strand 30 connected. The second input of the power amplifier circuit 15 is connected to the second input of the amplifier circuit 10 connected. In other words, the second input is the power amplifier circuit 15 to the second terminal of the second electronic component 2 that is, between the second and the third electronic component 2 . 3 with the strand 30 connected. The output of the power amplifier circuit 15 is connected to the second terminal of the first electronic component 1 , ie between the first and the second electronic component 1 . 2 with the strand 30 connected. This is the first electronic component 1 as a capacitor, while the remaining electronic components 2 . 3 and 4 are designed as resistors. In other words, that's the first end 8th of the strand 30 electrically connected to the first electrode of a capacitor, the second electrode to the first terminal of the second, designed as a resistor electronic component 2 connected is.

In the 2 is a specific embodiment of an electronic circuit according to the invention with five electronic components 1 . 2 . 3 . 4 and 5 shown. This electronic circuit according to the invention 40 is a continuation of the in the 1 shown embodiment of an electronic circuit according to the invention 40 , The identically named components in 2 So correspond to those of the first embodiment of 1 so that what is said there regarding these components on the second embodiment of 2 is to be transferred. In the embodiment of 2 has the electronic circuit 40 a fifth electronic component 5 which is also designed as a resistor and between the fourth electronic component 4 and the second end 9 of the strand 30 is arranged. Further, in this embodiment, both the amplifier circuit 10 as well as the power amplifier circuit 15 designed as an operational amplifier circuit. In this case, the first input of the amplifier circuit corresponds 10 the non-inverting input of the amplifier circuit 10 training operational amplifier circuit, during the second input of the amplifier circuit 10 the inverting input of the amplifier circuit 10 training operational amplifier circuit corresponds. The first input of the power amplifier circuit 15 corresponds to the non-inverting input of the power amplifier circuit 15 forming the operational amplifier circuit, while the second input of the power amplifier circuit 15 the inverting input of the power amplifier circuit 15 training operational amplifier circuit corresponds.

In this embodiment, the first end 8th of the strand 30 purely by way of example with a first electrode of an optional damping capacitor 23 connected, the second electrode with a constant potential, in this embodiment, the local ground of the electronic circuit 40 connected is. Furthermore, the electrical connection between the first input of the amplifier circuit 10 and the first end 8th of the strand 30 an optional first capacitor 28 on. In other words, that's the first end 8th of the strand 30 with an electrode of an optional first capacitor 28 whose second electrode is connected to the first input of the amplifier circuit 10 connected is. Between this second electrode and the amplifier circuit 10 itself is the first input of the amplifier circuit 10 optionally connected to a terminal of a resistor whose other terminal is connected to ground.

In the embodiment of 2 has the power amplifier circuit 15 purely by way of example two supply voltage terminals, which in this embodiment correspond to the supply voltage terminals of the operational amplifier of the operational amplifier circuit. Further, the power amplifier circuit 15 in this embodiment, optionally designed to be powered by its supply voltage terminals from a high-voltage network and to compensate for a ripple in the supply voltage provided by the high-voltage network. In other words, the power amplifier circuit is 15 In this embodiment, it is designed to compensate for an AC voltage which is undesirably superimposed on a DC voltage provided by a high-voltage network, and thus damage to the electronic circuit 40 avert. In this embodiment, the supply voltage terminals of the power amplifier circuit 15 with the outputs of an optional switching converter 19 , So connected to an optional DC / DC converter. This switching converter 19 has two inputs in this embodiment. The first input of the switching converter 19 is at a constant potential, in this embodiment, the local ground of the electronic circuit 40 connected. The second input of the switching converter 19 is with the first end 8th of the strand 30 as well as with the first electrode of the damping capacitor 23 connected. Furthermore, the second input of the switching converter 19 with a high-voltage network, For example, connectable to a high-voltage battery. The switching converter 19 is adapted to the supply voltage for the power amplifier circuit 15 from the voltage provided by the high-voltage network. In other words, the switching converter is 19 adapted to the voltage provided by the high-voltage network in the supply voltage of the power amplifier circuit 15 to transform and to supply this.

Furthermore, the electrical connections between the supply voltage terminals of the power amplifier circuit 15 with the outputs of the switching converter 19 each with an electrode of an optional second capacitor 24 whose respective second electrodes each have a constant potential, in this embodiment the local ground of the electronic circuit 40 are connected. In other words, the supply voltage terminals of the power amplifier circuit 15 each with a first electrode each of an optional second capacitor 24 while the second electrodes of these optional second capacitors 24 each with the local ground of the electronic circuit 40 are connected. The optional second capacitors 24 are designed to the energy necessary for the compensation of the AC components of the high-voltage network, over a predetermined period of time, the power amplifier circuit 15 provide. So it comes to fluctuations in the of the high-voltage network or of the switching converter 19 for the power amplifier circuit 15 provided supply voltage, these can be through the second capacitors 24 be compensated.

The predetermined duration is determined by the dimensioning of the second capacitors 24 set or fixed. In this embodiment, it corresponds purely by way of example to a few milliseconds. But it can also be set differently, for example longer or shorter.

The damping capacitor 23 , the first capacitor 28 and the second capacitors 24 are for the execution of an electronic circuit according to the invention 40 optional. It can also electronic circuits according to the invention 40 without such capacitors 23 . 24 . 28 , or with other such capacitors 23 . 24 and 28 , for example, in other than the positions selected here within the electronic circuit 40 can be arranged realized. Furthermore, the realization of the amplifier circuit 10 as well as the power amplifier circuit 15 by operational amplifier circuits in the embodiment of FIG 2 chosen purely by way of example. Furthermore, the power amplifier circuit 15 via their supply voltage connections also be connected directly to a high-voltage network or to another supply source, so that an electronic circuit according to the invention 40 also without switching converter 19 can be realized.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19600807 A1 [0003]
• DE 10062075 A1 [0004]

Claims (10)

Electronic switch ( 40 ), comprising - four electronic components ( 1 . 2 . 3 . 4 ), which are electrically conductively connected to each other via their respective two terminals ( 30 ), the strand ( 30 ) a first and a second end ( 8th . 9 ), - an amplifier circuit ( 10 ), whose first entrance to the first end ( 8th ) of the strand ( 30 ) and its second input to the second terminal of the second electronic component ( 2 ), the output of the amplifier circuit ( 10 ) with the second terminal of the third electronic component ( 3 ), - a power amplifier circuit ( 15 ), whose first input to the second terminal of the fourth electronic component ( 4 ) and its second input to the second input of the amplifier circuit ( 10 ), the output of the power amplifier circuit ( 15 ) with the second terminal of the first electronic component ( 1 ), characterized in that the first electronic component ( 1 ) is designed as a capacitor, while the remaining electronic components ( 2 . 3 . 4 ) are designed as resistors. Electronic switch ( 40 ) according to claim 1, wherein the strand ( 30 ) a fifth electronic component ( 5 ), which is designed as a resistor. Electronic switch ( 40 ) according to one of the preceding claims, wherein the electronic components ( 1 . 2 . 3 . 4 . 5 ) starting from the first end ( 8th ) of the strand ( 30 ) are arranged in ascending order according to their name. Electronic switch ( 40 ) according to one of the preceding claims, wherein the first end ( 8th ) of the strand ( 30 ) with an electrode of a damping capacitor ( 23 ) whose second electrode is connected to a constant potential. Electronic switch ( 40 ) according to one of the preceding claims, wherein the electrical connection between the first input of the amplifier circuit ( 10 ) and the first end ( 8th ) of the strand ( 30 ) a first capacitor ( 28 ) having. Electronic switch ( 40 ) according to one of the preceding claims, wherein the power amplifier circuit ( 15 ) further comprises two supply voltage terminals and is adapted to be fed via these supply voltage terminals from a high-voltage network and to compensate for a ripple in the supply voltage provided by the high-voltage network. Electronic switch ( 40 ) according to claim 6, wherein the supply voltage terminals of the power amplifier circuit ( 15 ) each with an output of a switching converter ( 19 ), which is connectable via at least one input to a high-voltage network and is adapted to the supply voltage for the power amplifier circuit ( 15 ) from the voltage provided by the high-voltage network. Electronic switch ( 40 ) according to claim 7, wherein the electrical connections between the supply voltage terminals of the power amplifier circuit ( 15 ) with the outputs of the switching converter ( 19 ) each having a respective electrode of a second capacitor ( 24 ), whose respective second electrodes are each connected to a constant potential, the second capacitors ( 24 ) are adapted to the energy necessary for the compensation of the AC components of the high-voltage network over a predetermined period of the power amplifier circuit ( 15 ). Inverter with an electronic circuit ( 40 ) according to one of claims 1 to 8. Motor vehicle with an inverter according to claim 9.

Images