KR102138343B1 - Multifunctional and highly integrated power converter component - Google Patents

Abstract

The present invention relates to a power converter element for a vehicle, said power converter element comprising at least one power electronic component (101-106, 201-206, C) that is functionally redundant.

Description

Multifunctional high integrated power converter element {MULTIFUNCTIONAL AND HIGHLY INTEGRATED POWER CONVERTER COMPONENT}

The present invention relates to the field of power electronic devices, in particular to power converter devices for controlling power flow in automobiles.

Inverters are used to supply electric power from a DC source to an AC-electric motor, or to provide an AC-power source from a DC source such as a lithium ion battery or fuel cell.

In the German published publication DE 10 2008 034 357 A1, for example, a DC step-up converter is disclosed, and in order to supply power to the DC/AC-inverter, the operation of the inductance in the converter is It is combined with the DC/AC-inverter input capacitor by the switch configuration. To control the high voltage-DC-bus, a smaller sized capacitor with lower probability of failure and lower cost can be used instead of an expensive bulky high voltage-DC-bus capacitor according to this method.

German patent DE 101 56 694 B4 also discloses a circuit arrangement for generating three-phase alternating current from smaller power (10 kVA to 5 mVA) power generators for supply into the power network. The circuit device consists of a generator-side diode-rectifier, a generator-side step-up converter, an intermediate circuit formed of two capacitor groups connected in series, and a network-side inverter for energy flow from the generator to the power network. It consists of a network-side diode-rectifier, a network-side step-up converter, an intermediate circuit formed of two capacitor groups connected in series, and a generator-side inverter for energy flow from the generator to the generator.

In various electric vehicle concepts, for example hybrid-, fuel cell- and electric vehicles (e.g. BEV, PHEV, FCEV, REEV), drive converters, auxiliary units and energy storage devices are completely different power electronics for the control of power flow. Devices are required. Current prior art treats this as a separate element for the associated drive converter, auxiliary unit and energy storage device. Due to this, large-scale redundant installation of power electronic devices is performed with respect to driving power.

High integration is now considered to be more important, for example in terms of the integration of power electronics in E-machines. This is more burdensome in the case of an already critical assembly space near the axis.

It is an object of the present invention to provide a power converter element which at least partially eliminates the aforementioned disadvantages.

The above object is solved by a power converter element according to the invention according to claim 1. Other preferred embodiments of the invention are set forth in the dependent claims and the following description of preferred embodiments of the invention.

The power converter element according to the present invention for a motor vehicle includes at least one power electronic component that is functionally overlapped. Such a multi-functional power converter element is preferably an electric drive-based vehicle, for example an electric vehicle (EV), a plug-in hybrid vehicle (PHEV), a fuel cell vehicle (FCEV), a mileage extending electric vehicle (REEV) or the like. Can be used in the same thing.

The power electronic component can be, for example, an active or passive power electronic device, for example a capacitor or a power electronic switch. In addition, the power electronics component may be an assembly of a plurality of power electronics elements, for example a number of IGBT-switches, which form an inverter.

The provision of at least one functionally redundant component provides common power for the power direction in which the redundant electronic component is associated with one or more auxiliary units, energy storage devices, charging sources and/or drive converters. Since it can be used as an electronic device, this has the advantage that the remaining power electronic elements can be omitted.

For example, the power electronics component used redundantly in the power converter element according to the present invention implements a power electronics device for a plurality of auxiliary units in a vehicle. This has the advantage that, for each auxiliary unit, a separate power electronic device, for example a respective rectifier, does not have to be provided, resulting in fewer power electronic components being provided.

In addition, the power electronic component used redundantly in the power converter according to the present invention can implement a power electronic device for a drive system having a plurality of long-energy storage devices. This also provides the advantage that power electronics can be saved.

Power electronic components that are redundantly used according to a preferred embodiment of the present invention are particularly used for charging and driving functions. The redundant power electronics components can be used, for example, as inverters for HV-power charging depending on the operating mode of the vehicle, or for auxiliary units such as HV-starters, flywheel accumulators, transmissions It can be used as an inverter for the operation of electric machines, or the like.

Power electronic components that are redundantly used according to embodiments are passive elements, especially intermediate circuit capacitors. Thus, for example, one intermediate circuit capacitor can be used for powering multiple auxiliary units.

A power electronic component that is redundantly used according to another embodiment includes, for example, a power electronic switch used as an inverter. Thus, for example, the power electronics switch can form an inverter for the first auxiliary unit and an inverter for the second auxiliary unit.

The power converter element may also include one or more controlled switches, which selectively connect redundant power electronic components to an auxiliary unit or charging source. Due to this, redundant power electronic components can be used for operating mode charging and for operating mode driving. This offers the advantage that a high charging power of> 20 kW is possible with a small number of additional elements. Thus, for example, a wired charging unit can be implemented as part of a power converter element according to the invention.

The redundant power electronic components of the power converter according to the invention can be used as power electronics for auxiliary units such as, for example, HV-starters, flywheel accumulators, electric machines for transmission operation, E-turbos or air conditioning compressors. Can. In addition, the power electronic components used redundantly in the power converter according to the present invention may be used as power electronic devices for energy sources such as HV-power charging or 12/V/48V-energy storage devices. In addition, the power electronic components used redundantly in the power converter according to the present invention may work together with a drive converter, which is connected to or regenerated to an electric machine driving the drive train of a vehicle to convert the energy obtained.

In a preferred embodiment, the power converter element according to the present invention implements a central and highly integrated power electronics device of multiple auxiliary units or energy sources. For example, each required inverter- and DC/DC-converter module can be installed in the same assembly space. Thereby assembly steps such as a multi-auxiliary unit and dual-long-term energy storage device of the power converter element according to the invention can be carried out.

The power converter element can also modularly implement power electronics for multiple auxiliary units and/or energy sources. Within this assembly step of the power converter element according to the invention a number of, for example 3 to 4, configurations can be implemented according to the module principle.

Embodiments of the present invention are described by way of example with reference to the accompanying drawings.

1 schematically shows a first embodiment of a power converter element according to the invention for an automobile.
2 schematically shows a second embodiment of a power converter element according to the invention for an automobile.
3 schematically shows a third embodiment of a power converter element according to the invention for an automobile.

A first embodiment of a power converter element according to the invention for an automobile is shown in FIG. 1. The power converter element 1 according to the invention of this embodiment comprises two DC/AC-converters 10, 20. The DC/AC-converter 10 is composed of six power electronic switches 101-106 (for example, IGBT-switch), connected to an intermediate circuit capacitor C, and the capacitor is a DC/AC-converter ( 10) is connected to the DC/AC-converter 20, the high voltage battery 2 and the drive converter 3 at a common DC voltage level. Since the high voltage battery 2 may be, for example, a lithium ion storage battery having a 400V voltage, the HV-topology (voltage level) of the high voltage network is designed as a 400V-system. The drive converter 3 converts the electric direct-current voltage provided by the high-voltage battery 2 into an AC voltage driving the electric machine 4, which is connected to the drive train of the vehicle (not shown).

The DC/AC-converter 10 integrated in the power converter element 1 according to the present invention converts the DC voltage provided by the high voltage battery 2 into a three-phase AC voltage, and the AC voltage includes two switches S1. , S2) is supplied to the auxiliary unit (31). The auxiliary unit 31 is, for example, an HV-starter with 20 kW power consumption, a flywheel storage battery with 20 kW power consumption, or an electric machine for operating the transmission.

For example, the DC/AC-converter 10 is selectively connected to the auxiliary unit 31 by means of switches S1 and S2, which may be simple switches such as contactors, or alternatively charging of the high voltage battery 2 It is connected to the connection portion (33, 34) provided for. The charging connections of this embodiment are, for example, a connection 33 for HV-power charging or a connection 34 for 12V/48V-MiniHEV (low voltage vehicle electrical system). The connection part 33 for HV-power charging is connected to the DC/AC-converter 10 through the DC/DC-converter T1 and the filters L1 and C1. The 12V/48V-MiniHEV 34 is connected to the DC/AC-converter 10 through the power electronic switch element 30, the DC/DC-converter T2 and the filters L2, C2. The 12V/48V-MiniHEV charging connection 34 allows the high voltage network to be connected to a low voltage network, particularly to a low voltage battery (not shown). The switch element 30 can include, for example, two MOSFET or IGBT line switches, which can regulate current and voltage in the 12/48V network on the right side of the current transformer T2. The exact number and wiring of the elements of the switch element 30 are not shown, only the switch element 30 is shown. The connection portion 33 for HV-power charging is connected to the drive converter 3 and is used for regenerative charging of the high voltage battery 2.

A charging front 5 is also connected to the high voltage-to-DC voltage level of the power converter according to the invention, the charging front being designed with, for example, 11, 22 or 44 kW power consumption, the charging front being (not shown) ) It is used for charging the high voltage battery 2 through the charging connection 6 by an external three-phase current source.

In the power converter element 1 of this embodiment, the power electronic switches 101-106 of the DC/AC-converter 10 are for two different functions, respectively, depending on the position of the switches S1, S2, ie on the one hand DC/AC-converter 10 is connected to charging connections 33, 34 and DC/AC-converter 10 is assisted in the operating mode "charging" used for charging of high voltage battery 2 or on the other hand It is used in the operating mode "drive" which is connected to the unit 31 and used for the operation of the auxiliary unit 31. This can be prevented from providing respective power electronic devices for each of these functions.

Another DC/AC-converter 20 integrated in the power converter element 1 according to the invention together with the DC/AC-converter 10 comprises six power electronic switches 201-206 (eg IGBT-switches) ), connected to the same intermediate circuit capacitor C, and the DC/AC-converter 10 also uses the intermediate circuit capacitor. Another DC/AC-converter 20 converts the DC voltage provided by the high voltage battery 2 into a three-phase AC voltage, and the AC voltage is supplied to another auxiliary unit 35. Another auxiliary unit 35 is, for example, an air-conditioning compressor of an automobile or an E-turbo with 5 kW power consumption. As the two DC/AC-converters 10 and 20 are integrated in a common central power converter element 1, the intermediate circuit capacitor C is a passive power electronic component that is used redundantly. Providing a respective capacitor for each of the two DC/AC-converters 10 and 20 can be omitted, which is installed in which each power electronic device is distributed for two auxiliary units 31 and 35. It is the case.

2 shows a second embodiment of a power converter element according to the invention for a motor vehicle. As long as this embodiment of Fig. 2 corresponds to the embodiment of Fig. 1, the elements have the same reference numerals, and repeated descriptions are omitted. The difference between the power converter element 1 of the second embodiment and the power converter element of the first embodiment is that the DC/AC-converter 20 has a higher voltage than other auxiliary units 35 (FIG. 1) unlike in the embodiment of FIG. It is not to connect to a network, but to provide an energy storage device 32 implemented as a low-side energy storage device having a power of, for example, 50 kW. The energy storage 32 is connected to the DC/AC-converter 20 via three chokes L3, L4, L5, for example to an auxiliary unit 31 or an electric machine 4 connected to a drive train. Can provide power. The power electronic switch 201-206 of the DC/AC-converter 20 of the embodiment of FIG. 2 acts as a DC/DC-converter with chokes L3, L4, L5. Thus, the power converter element according to the present invention uses power electronic components (herein the power electronic switches 201-206 of the embodiments of FIGS. 1, 2 and 3) for different functions depending on the configuration of the power converter element, eg For example, it is possible to use it as a DC/AC-converter (according to the embodiment of Fig. 1) or as a DC/DC-converter (according to the embodiment of Figs. 2 and 3). In addition, the power converter element 1 of this embodiment makes it possible to implement a power electronic device for a drive system with a large number of long-energy storage devices by means of redundant intermediate circuit capacitors (C).

Modification of the power converter element of FIG. 1 is possible. Therefore, for example, the DC/DC-converter T2 for a 12/48V-power system can be omitted.

The HV-topology (voltage level) of the power converter according to the invention can be based on any system voltage, for example a 400V-system (FIGS. 1 and 2) or an 800V-system. You can also consider mixed topologies of 400V- and 800V systems.

Figure 3 shows a third embodiment of a power converter element according to the invention for a motor vehicle, in which the power converter element 1 is operated in a number of energy storage systems/800V-hybrid systems. As long as this embodiment of Fig. 3 corresponds to the embodiment of Figs. 1 and 2, the elements have the same reference numerals, and repeated descriptions are omitted. The difference between the power converter element 1 of the third embodiment and the power converter element of the first and second embodiments is that the HV-topology is designed as an 800V-system, that is, the second AC/DC of the power converter element 1 -The converter connects a high voltage battery with a voltage level of 800V. The 400V-sub system 37 is also connected in the embodiment of FIG. 3 after the low side energy storage 36 at a voltage level of 800V.

The advantage of the hybrid-800V-system is that it does not require a complete reconstruction of all HV-elements to 800V. The main drive elements can be based on a dense 800V-system, while being flexible for other auxiliary drives or E-machines near the transmission. In addition, the dual battery system can implement redundant use of power electronic switches for driving and charging, and an optimal design can be implemented in terms of the number of passive elements in the 400V/800V-hybrid system.

Different structural shapes can also be considered in connection with this third embodiment. Thus, for example, the connection of the drive/auxiliary unit 31 (FIG. 3), for example the HV-starter or generator, the electric machine for operating the transmission, the connection of the E-turbo or flywheel storage battery, can be omitted. Also, the DC/DC-converter (T2) for the 12/48V-power system can be omitted. Additionally, a DC/DC-converter for low-side energy storage (batteries on the traction network and in the low-side network), or a DC/DC-converter for low-side energy storage may be provided (800V- on the traction network). Battery and 400V-battery in low-side network). Instead of a high output DC/DC-converter for low side energy storage (batteries on the traction network and in the low side network), a triport with two low side voltage levels may also be used.

In the power converter elements shown in Figs. 1, 2 and 3, the integration of the multi-functional integrated and high-power charging unit in the same assembly space is considered particularly desirable. High integration is therefore considered more desirable in terms of reduction of power electronic devices and passive components by the method of the present invention. Particularly, it is desirable to use the power electronic switches repeatedly when driving and charging the operation mode, and in this case, a high charging power of> 20 kW is possible with a small number of additional elements. For example, passive components (choke and intermediate circuit capacitors) required by the DC/DC-converter, charging unit and power controller can be reduced. The electric potential of the power-dense drive system is improved and utilized by the individual individual elements by this method.

The switch configuration for the switches shown here can be controlled by control signals, which are formed on the basis of multiple control modes and feedback signals by the controller in a manner known to those skilled in the art.

1 Power converter element
2 high voltage battery
3 drive converter
4 electric machines
5 filling shear
6 Charging connection for charging shear
10 DC/AC converter
101-106 Power Electronic Switch
20 DC/AC converter
201-206 power electronics switch
L1-L5 choke
T1, T2 DC/DC converter
C1, C2 capacitors
S1, S2 switches
C intermediate circuit capacitor
31 auxiliary units
32 Energy storage
Connection for 33 HV-power charging
34 Connection for 12V/48V-MiniHEV
35 auxiliary units
36 low-side energy storage
37 400V-sub system

Claims (11)

As a power converter element 1 for an automobile, the power converter element includes at least one power electronic component (101-106, 201-206, C) and at least one controlled switch (S1, S2) that are functionally used in duplicate. Including,
The redundant power electronic components 101-106, 201-206, and C are used for the charging function of the high voltage battery 2 and the operation of the auxiliary unit 31, and the high voltage battery 2 is used for the vehicle. The electric machine 4 connected to the drive train is intended to be driven through the drive converter 3,
The control switch (S1, S2) is a power converter element that is to selectively connect the redundant power electronic components (101-106, 201-206, C) to the auxiliary unit 31 or the charging connection (33, 34) . The power converter element according to claim 1, wherein the redundant power electronic components (101-106, 201-206, C) implement a power electronic device for a plurality of auxiliary units of a vehicle. The power electronic device according to claim 1 or 2, wherein the redundantly used power electronic components (101-106, 201-206, C) have a plurality of long-energy storage devices (2, 36). Power converter device that implements. delete The power converter element according to claim 1 or 2, wherein the redundant power electronic components (101-106, 201-206, C) are passive elements (C). 3. The power electronic component according to claim 1 or 2, wherein the redundant power electronic components include power electronic switches (101-106, 201-206, C), which are used as inverters (10, 20). Power converter element. delete The power electronic component (101-106, 201-206, C) of claim 1 or claim 2, wherein the HV-starter, flywheel storage battery, electric machine for operating the transmission, E-turbo, and air conditioning compressor , HV-powered charging, 12V/48V-energy storage, or power converter elements used as power electronics for drive converters. The power converter element according to claim 1 or 2, wherein the power electronic devices of a plurality of auxiliary units (31, 35) or energy sources (2, 36) are centrally and highly integrated. Power electronics according to claim 1 or 2, for a plurality of auxiliary units (31, 35), an energy source (2, 36), or a plurality of auxiliary units (31, 35) and an energy source (2, 36). Power converter device that implements the device in a modular manner. The power converter element according to claim 1, wherein said charging connections (33, 34) are connections (33) for HV-power charging or connections (34) for low voltage vehicle electrical systems.

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