DE102011006518A1 - Power supply unit e.g. high voltage battery, for drive train of e.g. electric car, has power supply elements electrically connected to each other by connector which is electrically connected to ground potential to form reference potential - Google Patents

Abstract

The supply unit e.g. high voltage battery (56), has two power supply elements i.e. battery cells (70, 72), connected between a positive connection terminal (74) and a negative connection terminal (76), where the voltage provided by the supply unit is measurable between the connection terminals. The supply elements are electrically connected to each other by a connector (68) such that the voltages provided by the supply elements are add up. The connector is electrically connected to a ground potential (50) to form a reference potential for the supply unit. An independent claim is also included for a drive train of a motor car.

Description

The present invention relates to a power supply unit, in particular for a motor vehicle, having a first and a second connection pole, between which a voltage provided by the voltage supply unit can be tapped, at least two voltage supply elements, which are connected between the connection poles and which are each designed to provide an electrical voltage wherein the power supply elements are electrically connected together by means of connection means such that the individual voltages provided by the power supply elements add up.

Furthermore, the present invention relates to a power supply network for a motor vehicle with a power supply unit of the type described above.

Finally, the present invention relates to a motor vehicle drive train with an electric machine for providing drive power and with a power supply unit of the type described above for providing electrical energy for the electric machine.

State of the art

In the field of motor vehicle drive technology, it is generally known to provide two independent DC voltage grids, wherein a high voltage electrical system in electric vehicles or hybrid vehicles provides a voltage of more than 60 V, which is galvanically isolated from a ground potential. Further, it is well known that in addition to the high voltage electrical system, a low voltage electrical system is provided for powering controllers having a voltage of less than 60V, the low voltage electrical system being connected to the ground potential. The galvanic isolation of the high voltage electrical system from the ground potential serves u. a. To prevent a user from being exposed to dangerous electrical voltages when touching a live part of the high voltage electrical system.

The low-voltage electrical system is usually connected to a ground potential of the motor vehicle, which is usually at the body potential and corresponds to the ground potential.

A disadvantage of the known high-voltage and low-voltage vehicle electrical systems is that the necessary potential separation of the high-voltage network of the ground potential is a high technical effort and is associated with high costs.

It is therefore the object of the present invention to provide a simplified voltage source that provides high voltage while providing safe protection for the user.

Disclosure of the invention

This object is achieved by a power supply unit, in particular for a motor vehicle having a first and a second terminal pole, between which a voltage provided by the power supply unit can be tapped off, at least two power supply elements, which are connected between the terminal poles and which are each formed an electrical To provide voltage, wherein the power supply elements are electrically connected to each other by means of connecting means that add the individual voltages provided by the power supply elements, wherein the connecting means are electrically connected to a ground potential to form a reference potential for the power supply unit.

Furthermore, the above object is achieved by a power supply network for a motor vehicle with a power supply unit of the type mentioned above.

Finally, the above object is achieved by a motor vehicle drive train with an electric machine for providing drive power and with a power supply unit of the above type for providing electrical energy for the electric machine.

Advantages of the invention

By the present invention, a voltage source can be provided which provides a necessary high voltage between the terminal poles, wherein the respective terminal poles have a low voltage to the ground or reference potential and thus is exposed upon contact of the terminal poles by a user this not the dangerous high voltage.

The invention has the advantage that between the terminal poles, the necessary high voltage is provided and the voltage to the ground potential is lower, in particular half as large as the voltage between the individual terminal poles, so that a user who is usually connected to the ground potential, at Only the low voltage is exposed to contact between a respective terminal pole and the Ground potential applied. On a galvanic isolation of the terminal poles of the power supply unit to the ground potential can be dispensed with such a voltage source and still ensure the necessary security.

Another advantage of the power supply unit according to the invention is that without additional technical means both a high voltage between the terminal poles and a low voltage between a respective terminal pole and the ground potential is provided.

The voltage supply unit is preferably designed as a battery, capacitor or hybrid capacitor.

It is possible in this way to resort to existing power supply units for motor vehicles to provide such a power supply unit.

It is preferred if the power supply elements are formed by individual cells or groups of cells of the battery.

As a result, the power supply unit for a motor vehicle with two independent power supply elements and the corresponding connecting poles can be provided by simple means.

It is further generally preferred that the voltage supply elements each have a negative pole and a positive pole, between which the respective voltage of the voltage supply elements is provided, and wherein the negative pole of the first voltage supply element is connected to the positive pole of the second voltage supply element.

In this way, a simple series connection of the voltage supply elements can be realized, whereby the voltages of the voltage supply elements add up and a high voltage is provided between the two terminal poles of the voltage supply unit.

It is further preferred if the respective other pole of the power supply elements is connected to other power supply elements, in particular with these connected in series.

By this interconnection, it is possible to realize any part voltage between the terminal poles and the reference potential with commercially available battery elements.

Furthermore, it is preferred if the respective other pole of the voltage supply elements is connected to a respective terminal pole of the voltage supply unit.

By this measure, the corresponding partial voltage of the power supply element between the terminal pole and the ground potential can be applied and interconnected without further technical effort, the power supply elements.

It is generally preferred if the voltages of the power supply elements are chosen such that they do not exceed a predefined value, in particular a safety-critical value.

By this measure can be dispensed with a galvanic isolation, without the voltages between the terminal poles and the reference potential pose a danger to a user.

According to another preferred embodiment, the voltages of the power supply elements are identical.

Thereby, a maximum high voltage between the terminal poles can be achieved, wherein the individual voltages of the power supply elements do not exceed a predefined threshold.

Alternatively, it is preferred if the voltages of the two voltage supply elements have different values, in order in particular to provide different supply voltages for different electrical consumers.

As a result, supply voltages for different voltage networks or electrical consumers of the motor vehicle can be provided without further technical measures.

Brief description of the drawings

1 schematically shows a motor vehicle with a hybrid powertrain having an internal combustion engine and an electric machine;

2 shows in schematic form a circuit diagram of a high voltage electrical system and a low voltage electrical system of a motor vehicle according to the prior art;

3 shows in schematic form a circuit diagram of a high voltage electrical system with a Voltage supply unit according to the present invention; and

4 shows in schematic form a battery with two battery cells.

Embodiments of the invention

In 1 a motor vehicle is shown schematically and generally with 10 designated. The car 10 has a drive train 12 on, in the present case an electric machine 14 and an internal combustion engine 16 for providing drive power. The powertrain 12 is used to drive driven wheels 18L . 18R of the vehicle 10 ,

The internal combustion engine 16 is over a crankshaft 20 with the electric machine 14 connected or connectable, wherein the internal combustion engine 16 and the electric machine 14 on an output shaft 22 provide a torque t that rotates at an adjustable speed. The output shaft 22 is with a gear unit 24 connected or connectable to the torque t on the driven wheels 18R . 18L transferred to. The crankshaft 20 and the output shaft 22 each have a coupling in the present case 26 . 28 on to the internal combustion engine 16 with the electric machine 14 or the electric machine 14 with the gear unit 24 connect to.

The powertrain 12 can be adapted to the vehicle 10 alone by means of the electric machine 16 to drive (electric vehicle). Alternatively, the electric machine 16 as in the present case part of a hybrid powertrain 12 be.

The crankshaft 20 is by means of the coupling 26 with a rotor of the electric machine 14 connected or connectable to a speed or torque to the electric machine 14 transferred to. The rotor of the electric machine 14 is with the output shaft 22 connected to the torque t on the gear unit 24 transferred to. The torque t is thereby the sum of that of the internal combustion engine 16 and the electric machine 14 provided individual torques.

In motor operation, the electric machine generates 14 a drive torque that drives the engine 16 , for example in an acceleration phase, supported. In regenerative or recuperation the electric machine generates 14 electrical energy, which is generally the vehicle 10 is made available.

The internal combustion engine 16 is through a fuel tank 30 fueled.

The electric machine 14 can be single-phase or multi-phase and is by means of power electronics 32 or an inverter 32 controlled and supplied with electrical energy. The power electronics 32 is with a power supply unit 34 like a DC power supply (eg battery or battery) 34 of the vehicle 10 connected and serves to one from the power supply unit 34 supplied voltage in alternating current in general or in a number of phase currents for the phases of the electric machine 14 transform judge. The power supply unit 34 is with a battery control unit 36 connected, which is adapted to the power supply of the electric machine 14 via the power electronics 32 and the state of charge of the power supply unit 34 to control. The power electronics 32 is further adapted to the recuperation operation of the electric machine 14 , the power supply unit 34 through by the electric machine 14 to charge generated electrical energy.

The power supply unit 34 , the power electronics 32 and the battery control unit 36 are part of a high voltage electrical system 38 of the motor vehicle 10 ,

The car 10 also has a low voltage supply unit 40 (eg battery), which is a low voltage electrical system 42 of the motor vehicle 10 supplied with a corresponding voltage. The high voltage electrical system 38 is by means of a DC-DC converter 44 with the low voltage on-board network 42 connected to electrical energy between the two electrical systems 38 . 42 exchange.

2 shows in schematic form a circuit of the high voltage electrical system 38 and the low voltage on-board network 42 as known from the prior art.

The high voltage electrical system 38 is through a battery 46 or DC voltage source 46 supplied with electrical energy. The DC voltage source 46 has a positive and a negative pole, between which the corresponding high voltage 48 provided. The DC voltage source 46 may also be formed as a capacitor, in particular as a double-layer capacitor or as a hybrid capacitor with properties of a capacitor and a battery.

The low voltage on-board network 42 is with a ground potential 50 connected as the reference potential for the low-voltage electrical system 42 serves. This ground potential 50 usually lies on the body potential and corresponds to the earth potential.

The high voltage electrical system 38 is of the ground potential 50 galvanically isolated, so that voltages 52 . 54 between the individual poles of the battery 46 and the ground potential 50 are undefined, but typically half the value of the high voltage 48 the battery 46 correspond.

A user with one of the two high voltage potentials 52 . 54 comes into contact and is at ground potential 50 is located, shifts the high voltage potential 52 . 54 such that the touched part is also at earth potential 50 is moved. In other words, a ground potential turns on contact with the corresponding conductor and the other pole of the high-voltage on-board electrical system 38 gets to the appropriate high voltage 48 set high or lowered. A disadvantage of the known high-voltage on-board networks is that the necessary potential separation to secure the user is a high technical effort and is associated with high costs.

3 shows in schematic form the low voltage electrical system 42 and the high voltage on-board electrical system 38 with a power supply unit according to the invention.

The power supply unit of the high voltage on-board electrical system 38 is in 3 shown schematically and generally designated 56. The high voltage electrical system 38 and the low voltage electrical system 42 are essentially identical to the corresponding on-board networks 2 , The same elements are designated by the same reference numerals, with only the differences being explained here.

The power supply unit 56 has a first power supply element 58 and a second power supply element 60 on. The energy supply elements 58 . 60 each have a positive and a negative voltage pole, between each of which an electrical voltage 62 . 64 is provided. The energy supply elements 58 . 60 are connected in series, so that the electrical voltages 62 . 64 to a total tension 66 Add the high voltage on-board network 38 with the appropriate voltage 66 provided. In this case, the negative voltage pole of the first energy supply element 58 with the positive voltage pole of the second power supply element 60 by connecting means 68 electrically connected. The connecting means 68 are electrical with the ground potential 50 connected to the power supply unit 56 forms a reference potential.

Because of the ground potential 50 with the connecting means 68 is electrically connected, are those of the power supply elements 58 . 60 provided electrical voltages 62 . 64 opposite the ground potential 50 so that a user using an electrical element of the high voltage electrical system 38 in contact device, only a low voltage 62 . 64 which is less than the total voltage 66 of the high voltage on-board electrical system 38 , is suspended.

The tensions 62 . 64 the energy supply elements 58 . 60 are preferably chosen so that they are below a critical, health-endangering value of usually 60V. Unless the tensions 62 . 64 can be selected with the power supply unit 56 the high voltage on-board electrical system 38 be supplied with a high voltage of up to 120V. In such a connection of the ground potential 50 with the power supply unit 56 can be dispensed with a potential separation without additional security measures must be taken.

In 4 is the power supply unit 56 represented in a preferred embodiment as a high voltage battery. The high voltage battery 56 has two battery cells 70 . 72 on, by means of the connecting means 68 electrically connected to each other. The high voltage battery 56 has a positive terminal pole 74 and a negative terminal pole 76 on, between which the total voltage 66 provided. The battery cells 70 . 72 each have a positive pole 78 and a negative pole 80 on, between which the tensions 62 . 64 are provided. The connecting means 68 are at ground potential 50 electrically connected. Alternative to the battery cells 70 . 72 can between the connecting poles 74 . 76 and the connecting means 68 Also be connected groups of battery cells, which are in particular electrically connected in series.

Because of the battery cells 70 . 72 over the connecting means 68 electrically connected to each other, the individual voltages add up 62 . 64 to the total tension 66 between the positive terminal pole 74 and the negative terminal pole 76 the battery 56 drops. Since a battery usually consists of several battery cells, is a division of the battery 56 in the two battery cells 70 . 72 inexpensive and can be realized with little technical effort, the battery internal electrical connection 68 the battery cells 70 . 72 with each other by simple means with the ground potential 50 can be connected. This ensures that the user at a touch of individual system components maximum of a simple harmless voltage that of each of the battery cells 70 . 72 provided tension 62 . 64 corresponds, is suspended.

Such a power supply unit may preferably be used for hybrid drive systems. In principle, however, such a power supply unit is applicable to all high voltage systems.

Claims (11)

Power supply unit ( 56 ) in particular for a motor vehicle ( 10 ) with: - a first connection pole ( 74 ) and a second terminal pole ( 76 ), between which one of the power supply unit ( 56 ) provided voltage ( 66 ), - at least two power supply elements ( 58 . 60 ; 70 . 72 ), which between the terminal poles ( 74 . 76 ) are connected and which are each adapted to an electrical voltage ( 62 . 64 ), the power supply elements ( 58 . 60 ; 70 . 72 ) by means of connecting means ( 68 ) are electrically connected to each other in such a way that the voltage from the power supply elements ( 58 . 60 ; 70 . 72 ) provided individual tensions ( 62 . 64 ), characterized in that the connecting means ( 68 ) electrically with a ground potential ( 50 ) are connected to a reference potential for the power supply unit ( 56 ) to build. A power supply unit according to claim 1, wherein the power supply unit ( 56 ) as a battery ( 56 ), Capacitor or hybrid capacitor is formed. Power supply unit according to claim 2, wherein the power supply elements ( 58 . 60 ; 68 . 70 ) individual cells ( 70 . 72 ) or groups of cells ( 70 . 72 ) of the battery ( 56 ) form. Power supply unit according to one of claims 1 to 3, wherein the power supply elements ( 58 . 60 ; 70 . 72 ) each have a positive pole ( 78 ) and a negative pole ( 80 ), between which the respective voltage ( 62 . 64 ) of the power supply elements ( 58 . 60 ; 70 . 72 ) and wherein the negative pole ( 80 ) of the first power supply element ( 58 ; 70 ) with the positive pole ( 78 ) of the second power supply element ( 60 ; 72 ) connected is. Power supply unit according to claim 4, wherein the respective other pole of the power supply elements ( 58 . 60 ; 70 . 72 ) is connected to other power supply elements, in particular with these in series. Power supply unit according to claim 4, wherein the respective other pole of the power supply elements ( 58 . 60 ; 70 . 72 ) each having a connection pole ( 74 . 76 ) of the power supply unit ( 56 ) connected is. Voltage supply unit according to one of claims 1 to 6, wherein the voltages ( 62 . 64 ) of the power supply elements ( 58 . 60 ; 70 . 72 ) are chosen so that they do not exceed a predefined value, in particular a safety-critical value. Voltage supply unit according to one of claims 1 to 7, wherein the voltages ( 62 . 64 ) of the power supply elements ( 58 . 60 ; 70 . 72 ) are identical. Voltage supply unit according to one of claims 1 to 7, wherein the voltages ( 62 . 64 ) of the two power supply elements ( 58 . 60 ; 70 . 72 ) have different values, in particular to provide different supply voltages for different electrical consumers. Power supply network ( 38 ) for a motor vehicle ( 10 ) with a power supply unit ( 56 ) according to one of claims 1 to 9. Automotive powertrain ( 12 ) with an electric machine ( 14 ) for providing drive power and with a power supply unit ( 56 ) according to one of claims 1 to 9 for providing electrical energy for the electric machine ( 14 ).

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