Field of the Invention
The present invention relates to a test arrangement for an energy storage device having at least one energy storage module with a plurality of energy storage units, having an AC/DC converter which is connected on the input side to a power supply, and the use of such a test arrangement in a test and forming system.
The Prior Art
Current cell testers mainly work with inefficient linear charging regulators and convert all the charging energy into heat. This results in high costs for powerful cooling systems and high energy costs in the production and testing of batteries, e.g. for forming, quality checking, endurance tests, emulation, etc.
Occasionally, switching converters which are capable of feeding back energy are also used for cell testers; these are complex, expensive and have a poor efficiency as they have to provide a very high voltage ratio, e.g. step up from 3V to 400V. A switching converter for testing batteries is shown, for example, in WO 97/07385 A2, in which a number of bidirectional DC/DC converters are connected to an AC/DC converter.
It is an object of the present invention to specify an efficient, cost-effective and at the same time flexibly usable or configurable test arrangement.
According to the invention, this object is achieved in that the AC/DC converter is connected on the output side to at least one bidirectional isolated module DC/DC converter, wherein the output of the bidirectional isolated module DC/DC converter is connected to a plurality of parallel-connected cell DC/DC converters and the outputs of the cell DC/DC converters are brought out as outputs of the test arrangement. This hierarchical structure of the test arrangement by means of isolated DC/DC converters enables the test arrangement to be configured extremely flexibly; in particular, widely differing expansion stages are possible therewith. Equipment ranging from individual energy storage units to individual energy storage modules and complete energy storage devices can be tested and formed therewith without having to change the internal structure of the test arrangement. In doing so, the configuration can be changed very easily by means of controllable switches.
Basically, as is known, the efficiency of a converter improves with higher power level and with higher voltage level. In the present hierarchical structure of the test arrangement, the AC/DC converter has an efficiency of ˜92%, the module DC/DC converters an efficiency of ˜85%, and the cell DC/DC converters an efficiency of ˜75%. Whenever possible, an attempt is therefore made to provide the energy for testing and emulation by the highest converter stage (AC/DC converter), which is possible thanks to the present structure. For many test cases, in particular when used as a test and emulation system for batteries, all energy storage units (e.g. the battery cells) are tested with the same setpoint over a long time. For example, in a charging cycle, all energy storage units can be supplied by the highest converter stage (AC/DC converter) for almost the whole CC (constant current) phase. The module or cell DC/DC converters only have to come into play when transferring to the CV (constant voltage) phase. This results in an efficiency advantage of ˜92−75%=17% for usually more than 50% of the test period. The test arrangement according to the invention therefore also allows work to be carried out with the best possible efficiency.
For testing or forming, an energy storage unit of the energy storage module is simply connected to an output of a cell DC/DC converter. This enables the energy storage unit to be subjected to a specifiable charging current at the level of the cell DC/DC converter.
When the outputs of a module DC/DC converter are connected to the series-connected outputs of the associated cell DC/DC converters which are connected in series, discharging can take place even when using unidirectional cell DC/DC converters. With this, all energy storage units can be discharged by deactivating all cell DC/DC converters. However, individual energy storage units can also be subjected to any load current by superimposing a current of the cell DC/DC converter on the current of the associated module DC/DC converter.
Larger energy storage devices can be tested and formed when a plurality of module DC/DC converters are connected in parallel to the output of the AC/DC converter and each module DC/DC converter is connected to a plurality of parallel-connected cell DC/DC converters. This enables any expansion stages and configurations of an energy storage device to be tested and formed, which increases the flexibility of the test arrangement.
If the outputs of the module DC/DC converters can be connected in series by means of switches, energy storage devices which consist of a plurality of interconnected energy storage modules can also be tested or formed as a whole with high efficiency.
By bringing out the outputs of the module DC/DC converters via a switch, the test arrangement can also be connected at module level, e.g. as an input for a battery management system or for testing or forming individual energy storage modules as a whole.
If the output of the AC/DC converter is brought out via a switch as output of the test arrangement, the test arrangement can also be connected at energy storage device level, e.g. as an input for a battery management system or for testing or forming individual energy storage devices as a whole.
The flexibility of the test arrangement can be further increased if the outputs of a plurality of cell DC/DC converters can be connected in series by means of switches and/or the outputs of the series-connected cell DC/DC converters are brought out via a switch as outputs of the test arrangement.
The present invention is explained in more detail below with reference to the attached drawings, which show advantageous embodiments of the invention in an exemplary, schematic and non-restricting form. In the drawings:
The test arrangement 1 according to the invention for electrical energy storage devices consists of a bidirectional AC/DC converter 2 on the input side which can be connected by means of an input connector 4 to a power supply 3, e.g. a 400 VAC voltage source. A number of (at least one) module DC/DC converters 51 . . . 5n are connected in parallel to the DC output of the AC/DC converter 2, e.g. a 400 VDC output. The module DC/DC converters 51 . . . 5n are designed as commercially available bidirectional isolated DC/DC converters. The module DC/DC converters 51 . . . 5n convert the high-voltage DC output of the AC/DC converter 2 to a DC voltage which corresponds to the voltage range of an energy storage module, such as a battery module or a fuel cell module for example, consisting of a plurality of energy storage units, such as battery cells or fuel cells for example, e.g. 12V or 48V DC. The outputs of the module DC/DC converters 51 . . . 5n can also be connected in series by means of switches SM, which is possible as the module DC/DC converters 51 . . . 5n are designed as isolated DC/DC converters.
A number of (at least one) cell DC/DC converters 611 . . . 6nm are connected in parallel to the output of a module DC/DC converter 51 . . . 5n. The cell DC/DC converters 611 . . . 6nm are designed as commercially available isolated DC/DC converters. At the same time however, the cell DC/DC converters 611 . . . 6nm can also be designed as bidirectional DC/DC converters. The cell DC/DC converters 611 . . . 6nm convert the DC output of the associated module DC/DC converter 51 . . . 5n to a DC voltage which corresponds to the voltage range of the energy storage unit of an energy storage module, e.g. 0.5V to 5.5V DC for battery cells of a battery module. The outputs of the cell DC/DC converters 611 . . . 6nm can also be connected in series by means of switches SZ, which is possible as the cell DC/DC converters 611 . . . 6nm are designed as isolated DC/DC converters.
At energy storage device level, the outputs AE+, AE− of the AC/DC converter 2, and, at energy storage module level, the outputs AM1+, AM1− . . . AMn+, AMn− of the module DC/DC converters 51 . . . 5n and the outputs A1+, A1− . . . Ax+, Ax− of the cell DC/DC converters 611 . . . 6nm can be brought out as outputs of the test arrangement 1 and can be connected electrically. Likewise, preferably each of the first and last output AZ1+, AZ1− . . . AZx+, AZx− of the series-connectable cell DC/DC converters 611 . . . 6nm are brought out as shown in
The outputs AE+, AE− of the AC/DC converter 2 can be activated by means of switch S1. The outputs AM1+, AM1− . . . AMn+, AMn− of the module DC/DC converters 51 . . . 5n can be activated by means of switch S2. The outputs AZ1+, AZ1− . . . AZx+, AZx− of the series-connectable cell DC/DC converters 61m . . . 6nm, that is to say in essence the first and last output of the series-connected cell DC/DC converters 611 . . . 6nm, can be activated by means of switch S3.
In the maximum configuration, a test arrangement 1 according to the invention has, for example, an AC/DC converter 2 to which eight module DC/DC converters 51 . . . 58 are connected, to each of which 12 cell DC/DC converters 611 . . . 6812 are connected. As a result, consequently, up to 96 energy storage units or 8 energy storage modules each comprising 12 energy storage units can be tested or formed. Other expansion stages are of course conceivable.
In this case, the AC/DC converter 2, the module DC/DC converters 51 . . . 5n and the cell DC/DC converters 611 . . . 6nm are controlled according to requirements by a control unit 10, which can also be integrated into the test arrangement 1. Likewise, the control unit 10 can control the opening/closing of the switches S1, S2, S3, SM, SZ. The control cables 20 from the control unit 10 to the individual components of the test arrangement 1 are not shown or are only indicated in
The function of the test arrangement 1 according to the invention is described in more detail below based on a specific exemplary embodiment in the form of a test and forming system for an electrical energy storage device.
In the example according to
When using unidirectional cell DC/DC converters 611 . . . 6nm, discharging can only take place at energy storage module level, as is described with reference to the module DC/DC converter 5n in
As a result of the interaction of cell DC/DC converters 611 . . . 6nm and the associated module DC/DC converter 5n, each individual battery cell 9n1 . . . 9nm can be tested or formed with any load current in the manner described above. In particular, the current of a module DC/DC converter 51 . . . 5n can be overlaid by any current of a cell DC/DC converter 611 . . . 6nm, whereby the current of the module DC/DC converter 51 . . . 5n at energy storage unit level can also be strengthened.
When switches S1, S2, S3, SZ and SM are open, only voltages which lie below the safety extra-low voltage level are present at the outputs A1+, A1− . . . Ax+, Ax− and AZ1+, AZ1− . . . AZx+, AZx− of the cell DC/DC converters 611 . . . 6nm and at the outputs AM1+, AM1− . . . AMn+, AMn− of the module DC/DC converters 51 . . . 5n, as a result of which protection against contact can be entirely dispensed with. This is particularly interesting for forming and energy storage.
At the same time, the battery cells 911 . . . 9nm can also be connected or disconnected individually by means of switches SB11 . . . SBnm between the series-connected battery cells 911 . . . 9nm. In doing so, the switches SB11 . . . SBnm can also be controlled by the control unit 10.
When a cell DC/DC converter is designed as a bidirectional DC/DC converter 611 . . . 6nm, this also enables discharging to be carried out at energy storage unit level (battery cell).
Number | Date | Country | Kind |
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A50513/2012 | Nov 2012 | AT | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2013/073504 | 11/11/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2014/076033 | 5/22/2014 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5751150 | Rippel et al. | May 1998 | A |
6344985 | Akerson | Feb 2002 | B1 |
8354825 | Lee et al. | Jan 2013 | B2 |
Number | Date | Country |
---|---|---|
508279 | Dec 2010 | AT |
200950162 | Sep 2007 | CN |
101930058 | Dec 2010 | CN |
102043131 | May 2011 | CN |
102680898 | Sep 2012 | CN |
202471920 | Oct 2012 | CN |
202494763 | Oct 2012 | CN |
2424069 | Feb 2012 | EP |
H05276673 | Oct 1993 | JP |
2012143104 | Jul 2012 | JP |
2012154793 | Aug 2012 | JP |
2013160652 | Aug 2013 | JP |
Entry |
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English Abstract of JPH05276673. |
English Abstract of JP2012143104. |
English Abstract of JP2012154793. |
English Abstract of JP2013160652. |
English Abstract of CN102680898. |
Translation of Abstract of CN102680898. |
English Abstract of CN202494763. |
English Abstract of CN101930058. |
English Abstract of CN102043131. |
English Abstract of CN202471920. |
English Abstract of CN200950162. |
English Abstract of EP 2424069. |
Number | Date | Country | |
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20150293179 A1 | Oct 2015 | US |