DE102009047065A1 - Series connection of switching regulators for energy transmission in battery systems - Google Patents

Abstract

A drive system for an electric vehicle and an electric vehicle with such a drive system. A separate aspect relates to a battery module (15) for an electric vehicle and an electric vehicle with such a battery module (15). The drive system comprises an electric motor (11) and an inverter (12) for generating an alternating voltage for the operation of the electric motor (11) from a direct voltage with a predetermined fixed voltage value. According to the invention, the drive system has a DC / DC converter (14) which is designed to generate the DC voltage and has a first and a second input for connecting a battery module (15). The battery module (15) has a plurality of battery cells and a first DC / DC converter (14), which is designed to generate a DC voltage with a predetermined fixed voltage value.

Description

State of the art

It is becoming apparent that battery systems will increasingly be used in vehicles in the future. A typical drive system for hybrid and electric vehicles usually includes a battery, which feeds the electric motor via an inverter for generating AC of a frequency suitable for a desired engine speed, or of this in the generator operation z. B. is charged during braking over the inverter. The inverter is usually equipped with a smoothing capacitor on its DC side to buffer the input voltage.

Depending on the application, the battery systems must fulfill a wide variety of requirements. In a hybrid vehicle, for example, an electric motor / generator with a battery system can be added to an internal combustion engine or, in a purely electric vehicle, take on the drive tasks alone. In addition, there are a wide variety of vehicle classes, which differ massively in terms of moving mass, the required acceleration and the desired speed. Examples of different vehicle classes would be trucks, cars (divided into different classes from microcar to sedan, sports cars, delivery vehicles, etc.) or electric utility vehicles such as stacker.

A requirement for battery systems is commonly characterized as so-called P / E ratio, which indicates the ratio of power P to energy E. The power P refers to the peak power PPeak, the battery system for a period of z. B. must provide 10 s in the vehicle, the energy E on the energy content of the battery system, which can be taken from a fully charged battery at room temperature with a suitably selected constant current in one hour, so that the battery is then completely discharged (or permissible lower voltage limit has reached). For hybrid vehicles, the P / E ratio typically assumes values greater than 30, for plug-in hybrid vehicles (hybrid vehicles with external charging capability), the required P / E ratio is dependent on the required range for pure e-driving in For electric vehicles with a range of 100 km and more, it is about 3. In sports cars with electric drive, the P / E ratio can assume values of about 5, similar to the plug-in hybrid vehicles.

In order to realize the required energy content and the required performance data with the traction battery without oversizing, battery cells are required whose P / E ratio corresponds at least almost to that required for the battery system. The number n of the required battery cells depends on the capacity and the nominal voltage (average voltage over a complete discharge process) of the battery cells used. It can be determined as follows: n = E _{battery system} / ( _{single cell} capacity · rated voltage)

The n battery cells can be interconnected in various configurations in the battery system, e.g. B. as a series connection of all n battery cells, as a parallel connection of two strands with n / 2 series connected battery cells, as a parallel connection of three strands with n / 3 series connected battery cells, etc. Given a voltage range of the battery cells, this results directly in the voltage range of the battery system. When using lithium-ion cells with a voltage range of about 2.8 V (discharged) to 4.2 V (charged) results for a battery system with, for example, 100 series-connected battery cells, a voltage range of 280 to 420 V, two Strands of 50 cells each correspondingly from 140 to 210 V. Both exemplified configurations have the same energy content, but have a different voltage range as an interface to the inverter and electric motor. The inverter and the electric motor must therefore be designed completely differently for the two exemplary battery configurations. This prevents standardization of the components battery, pulse-controlled inverter, electric motor and possibly battery charger.

An electric drive system is desirable, which allows standardization of the above-mentioned components by means of an output voltage set to a fixed value.

Disclosure of the invention

The invention therefore introduces a device which can overcome at least one of the above-mentioned disadvantages of the prior art.

A first aspect of the invention introduces a drive system for an electric vehicle that includes an electric motor and an inverter for generating an AC voltage for operating the electric motor from a DC voltage having a predetermined fixed voltage value. According to the invention, the drive system has a DC / DC converter, which is designed to generate the DC voltage, and has a first and a second input for connecting a battery module.

The drive system of the first aspect of the invention allows the inverter and electric motor to be optimized for a fixed operating voltage because the DC / DC converter can always provide the fixed operating voltage regardless of the actual voltage of the battery module. This also eliminates the operation in sinking with the discharge voltages that mean a mismatch of the inverter and the electric motor over a wide voltage range. In addition, a flexible interface to the battery module is created, whose output voltage can now be within a wide range.

Preferably, the drive system has a buffer capacitor having a first electrode connected to a first input of the inverter and a second electrode connected to a second input of the inverter. The buffer capacitor buffers the input voltage of the inverter, which cushions short-term load fluctuations.

Particularly preferably, the DC / DC converter is bidirectionally designed and configured to generate a charging voltage for the battery module from the AC voltage of the electric motor. This makes it possible to return excess kinetic energy during braking via the generator effect of the electric motor in the battery.

The predetermined fixed voltage value is preferably between 370 and 430 volts (in particular for hybrid vehicles and electric vehicles as passenger cars) or between 700 and 800 volts (in particular for so-called commercial vehicles or light commercial vehicles). These voltages are particularly suitable for the specified purposes.

A second aspect of the invention introduces a battery module for an electric vehicle. The battery module has a multiplicity of battery cells and, according to the invention, a first DC / DC converter which is designed to generate a DC voltage having a predetermined fixed voltage value.

The second aspect of the invention offers the same advantages as the first aspect of the invention, but here the DC / DC converter is integrated into the battery module instead of the drive system.

The battery module preferably has a second DC / DC converter, which is connected in series or in parallel with the first DC / DC converter on the output side. This increases the flexibility and it can easily be adjusted in each case required P / E ratio largely independent of the battery cells used.

A third aspect of the invention relates to an electric vehicle with a drive system according to the first aspect of the invention or with a battery module according to the second aspect of the invention.

Brief description of the pictures

The invention is explained in more detail below with reference to illustrations of exemplary embodiments. Show it:

1 an inventive drive system with a battery module connected thereto 15 according to the prior art;

2 a battery module according to the invention 15 with a drive system according to the prior art; and

3 in two sub-figures a) and b) particular embodiments of battery modules according to the invention 15 ,

Detailed description of the pictures

1 shows an inventive drive system with a battery module connected thereto 15 according to the prior art. An electric motor 11 is to an inverter 12 connected and receives from this an AC voltage of a frequency required for each speed. In generator mode, the electric motor 11 generate an AC voltage and to the inverter 12 output, which over the bidirectional designed DC / DC converter 14 a charging current for the battery module 15 generated. At the input of the inverter 12 is a buffer capacitor 13 connected. The input voltage of the inverter 12 is from a DC / DC converter 14 generated, the input side to a battery module 15 connected to a variety of battery cells.

2 shows a battery module according to the invention 15 with a drive system according to the prior art. The battery module 15 has an internal DC / DC converter 14 which is a DC voltage with a predetermined fixed voltage value as the output voltage of the battery module 15 generated. The battery module 15 is to a conventional drive system with a buffer capacitor 13 , an inverter 12 and an electric motor 11 connected.

3 shows in two sub-figures a) and b) particular embodiments of battery modules according to the invention 15 ,

In the first example of sub-figure a), a first DC / DC converter is used 14 a second DC / DC converter 16 added. To the inputs of the two DC / DC converters 14 and 16 In each case a string of battery cells is connected, which can also be connected to each other in terms of potential, as indicated in the figure by a dashed line. The two DC / DC converters 14 and 16 are connected on the output side in series, so that the DC voltage with a predetermined fixed voltage value as the sum of the output voltages of the two DC / DC converter 14 and 16 is produced. Of course, a larger number of DC / DC converters can also be connected in series on the output side. The great flexibility of the arrangement is advantageous. Thus, it is possible that more energy is taken from a string of battery cells than other strings to compensate for differences in the state of charge of the strings. If necessary, a DC / DC converter can even be switched off completely.

The second example of the sub-figure b) essentially corresponds to that of the first one, which is why the above statement also applies to the second example in a similar way. The main differences are the first and the second DC / DC converter 14 and 16 output side connected in parallel, so that each DC / DC converter 14 . 16 must generate the DC voltage with predetermined fixed voltage value, but summed up in each case provided output power. This arrangement also offers great flexibility because one of the DC / DC converters can be temporarily shut down and disconnected from the output.

Claims (7)

A drive system for an electric vehicle, the drive system comprising an electric motor ( 11 ) and an inverter ( 12 ) for generating an alternating voltage for the operation of the electric motor ( 11 ) from a DC voltage having a predetermined fixed voltage value, characterized by a DC / DC converter ( 14 ), which is designed to generate the DC voltage, and a first and a second input for connecting a battery module ( 15 ) having. The drive system of claim 1, comprising a buffer capacitor ( 13 ), one to a first input of the inverter ( 12 ) connected first electrode and one to a second input of the inverter ( 12 ) has connected second electrode. The drive system of one of claims 1 or 2, wherein the DC / DC converter ( 14 ) is designed and constructed bidirectionally, from the AC voltage of the electric motor ( 11 ) a charging voltage for the battery module ( 15 ) to create. The drive system of any one of the preceding claims, wherein the predetermined fixed voltage value is between 370 and 430 volts or between 700 and 800 volts. A battery module ( 15 ) for an electric vehicle with a plurality of battery cells, characterized by a first DC / DC converter ( 14 ) configured to generate a DC voltage having a predetermined fixed voltage value. The battery module ( 15 ) of claim 5, characterized by a second DC / DC converter ( 16 ), which with the first DC / DC converter ( 14 ) is connected in series or in parallel on the output side. An electric vehicle with a drive system according to one of claims 1 to 4 or a battery module ( 15 ) according to one of claims 5 or 6.

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