WO2012146463A1 - Energy storage apparatus comprising a plurality of storage modules for electrical energy - Google Patents

Abstract

An energy storage apparatus (1) comprising a plurality of storage modules (6) for electrical energy which are each coupled to a capacitor unit (5) of a converter submodule (4), which is associated with a converter (2), for charging or discharging at least one storage module (6) by means of at least one drivable DC-DC converter (7), which DC-DC converter (7) is designed to convert a capacitor voltage, which is applied to the capacitor unit (5), into a charge voltage which is required for charging the storage module (6), and to convert a discharge voltage, which is produced when the storage module (6) is discharged, into the capacitor voltage, wherein a central control device (11) is provided, said central control device being designed to drive the individual DC-DC converters (7) taking into account operating data from all the storage modules (6) and external request data (12), and/or each capacitor unit (5) and/or each DC-DC converter (7) has an associated control unit (8) which can be configured in a module-specific manner for at least two storage modules (6) which differ in respect of a property which influences the charge and discharge properties of said storage modules.

Description

description

An energy storage device comprising a plurality of storage modules for electrical energy

The invention relates to an energy storage device comprising a plurality of memory modules for electrical energy, each connected to a capacitor unit of an inverter to ^¬ associated Umrichtersubmoduls for loading or unloading at least one memory module via a controllable DC voltage controller are coupled at least, which DC voltage regulator for converting to the capacitor unit applied capacitor voltage in a charging voltage, which is required for charging the memory module, and is configured for converting a resulting charge in the energy storage discharge voltage in the capacitor voltage.

Electrical energy storage devices are becoming increasingly important, especially in non-consumer electronics and consumer electronics sectors. Energy storage devices of larger capacity have already been proposed for use in motor vehicles and also for stationary storage in networks. Thus, an intelligent integration of energy storage in electrical networks, especially as decentralized energy storage devices or storage in isolated networks, is becoming increasingly important.

An inverter with Umrichterventilen or Umrichterarmen having a series circuit of submodules for charging or discharging an energy storage, is known from nachveröffent ^¬ clear application with the application number PCT / EP / 2009 / 065,491th A process described there submodule for loading or Entla ^¬ an energy storage device comprises a capacitor unit, and a power semiconductor circuit having on and off power semiconductors. The capacitor unit and the power semiconductor circuit are connected to one another such that, depending on the control of the power semiconductors of the power semiconductor circuit, at least Gate unit falling voltage or a zero voltage at Aus ^¬ output terminals of the submodule can be generated. The there beschrie ^¬ bene basic idea is now that the energy store can be connected to the sub-module via a DC voltage controller, said DC voltage controller is connected to the capacitor unit, and for converting a dropped across the capacitor unit capacitor voltage into a charging voltage necessary to charge the energy store is, and is arranged to convert a discharging voltage dropping at the energy storage in the discharge voltage in the capacitor voltage. As an energy storage can be provided at ^¬ example, an accumulator.

Problems with such energy storage devices or larger storage systems, in which the storage of electrical energy ultimately takes place decentrally in a plurality of memory modules occur, in particular due to the number of Spei ^¬ chermodule.

Even if the memory modules can be designed uniformly at the beginning of the life, this is no longer the case with increasing aging. The scattering of individual cells of the memory modules can be, for example, 5% or more. After aging, ie operation, and thus different heating of individual cells according to position in the module (cooling) and operating conditions may lead to an even more different behavior of the individual memory modules. In the construction of large energy storage devices or systems today very similar cells are often used for a memory module or the entire system, which can lead to ei ^¬ nem greater sorting costs. It is further desired that are to be used from Berührschutzgründen (Safety of Be serving ^¬ personal and legal requirements) individual modules, for example, a maximum of 60 V or 120 V voltage which can be transported without significantly increasing safety requirements ^¬ stanchions and handled. Einzelmo ^¬ modules with higher voltages require transport and hand- specially trained personnel and technically partly expensive security arrangements.

The invention is therefore based on the object to provide an electrical ^¬ specific energy storage device rungs- in the memory modules of different charge and discharge characteristics, especially different internal resistance, capacitance, aging and health, can be used.

To solve this problem is vorgese ^¬ hen in an energy storage device of the type mentioned vorgese ^¬ hen that a central control device is provided, which is designed to control the individual DC voltage controller taking into account operating data of all memory modules and external request data, and / or each capacitor unit and / or each DC voltage controller is assigned a control unit that is module-specific configurable for at least two in ei ^¬ ner their charge and discharge characteristics affecting property different memory modules.

After it post-published in the prior art, in particular with respect to the already cited above

PCT / EP / 2009/065491 has already been proposed to provide a modular solution that allows to divide an energy storage device into different memory modules, specifically a Marquardt multi-stage converter was used, but there it was basically necessary to use the same Spei ^¬ chermodule , With the present invention, it is, especially for general Umrichterkonzepte, only ^¬ times possible to specifically use differing memory modules or counteract the effects of temporal changes after aging of the memory modules.

For this purpose, two measures are preferably used cumulatively proposed, namely first, each Gleichspannungsstel ^¬ ler, via the yes a memory module is connected to assign a control unit, the module-specific and / or modular is type-specific configurable. In practice this means that the control unit, which can also be referred to as a battery management unit is specifically tailored to a specific memory module, but is intended from the outset in the energy storage device to use different memory modules, whether they are completely different ^¬ Liche module types or only different storage modules from the state of aging (especially in the context of so-called second-life scenarios). It is therefore also possible to use different types of modules in the energy storage device selectively, with module types, in particular different models of memory modules, differing from home in a property influencing their charge and discharge properties, ie for different module types, in particular in their storage principle and / or their storage capacity and / or its voltage level and / or the Che mie ^¬ their storage process and / or its efficiency or its internal resistance. Ultimately, it is therefore possible to adjust a control algorithm used in the control unit to the actually used memory modules, which is possible in particular due to the use of Gleichspannungsstel- ler, which may be formed for example as a step-up converter and / or deep ^¬ converter. The DC voltage regulators make it possible to cover a considerable voltage spectrum on the output side, which can even be adapted flexibly to slightly different conditions or network environments as required. In particular, however, the manner of operation of the DC voltage controller, which is controlled via the control unit to be configured specifically for him to be closed ^¬ memory module type or concrete attached storage module.

By the use of DC voltage controllers, in particular step-up converters, preferably with high efficiency can be achieved, therefore, for example, the voltage level of the memory modules, which may consist ge ^¬ switched single cells in series and / or parallel, must not be necessarily the same. Rather, different Memory modules are used, in particular, un ^¬ different cell chemistries in the memory modules can be used.

Another special advantage of the present invention is the use of a central control device which is designed to control the individual DC voltage regulators, if necessary additionally the memory modules themselves, taking into account operating data of all memory modules and external request data, for example a power requirement , It is therefore proposed a holistic control concept for the energy storage ^¬ chervorrichtung, which is not only able, for example, different current characteristics, such as the current state of charge to consider the individual memory modules, but also to address the characteristics of different memory modules used, which then depending on their characteristics can be used. For example, in the case of a high, quickly-required power requirement, memory modules with suitable properties can be preferably unloaded and the like. But beyond the use of a central control device offers advantages so that, for example, a portion of the memory modules maintenance and / or measuring cycles pre ^¬ see his can, the power requirements and an in-depth performance can be initially provided or used by other memory modules , By such a Ge ^¬ samtregelung taking into account a particular heterogeneous overall configuration of the energy storage device by using different memory modules, a high flexibility and a variety of ways, game as to extend in ^¬ the lifetimes of memory modules to optimize reaction times of the energy storage device to changing performance requirements, and the like is obtained. This will be discussed in more detail below.

In general, however, it remains to be stated that in the case of the energy storage device according to the invention, is again possible to specifically different memory modules, in particular different types of memory modules to USAGE ^¬. Accordingly, it can be provided that at least two memory modules are different charge and Entladeeigen ^¬ properties affecting property in a, in particular in its storage principle and / or its memory capacity and / or its voltage level and / or the chemistry of their storage process and / or its state of aging and / or their performance.

In particular, different Speichermo ^¬ dultypen that the memory modules, a lithium-ion battery and / or a lithium-polymer battery, and / or a lead-battery and / or a nickel-cadmium battery and / or may be provided in the sense Nickel-metal hydride battery and / or a high-temperature battery, in particular a sodium-sulfur battery and / or a ZEBRA battery and / or a metal-air battery, and / or a redox flow battery and / or a supercapacitor, in particular a double-layer capacitor and / or a hybrid capacitor, in particular at least two memory modules from this group. It is therefore conceivable to use the most diverse types of batteries and other memory modules in a single decentralized electrical energy storage device, it being noted at this point that the voltage level of the individual memory modules can each be chosen so that they are on the DC voltage controller in a before fixed voltage window is fixed. This means that it is already fundamentally possible to define a voltage ^window within which the voltage level of the memory modules moves. In this way it is possible to limit the voltage level locally so that globally for all of the electrical energy storage device provided see ^¬ ne voltage limits can be met.

Due to the given modular design of the energy storage device according to the invention, not only can each inverter submodule be assigned a different type of memory module, but it is also conceivable to use memory modules which have a different aging state, which can be expressed, for example, in a changed capacity, voltage or permissible charging or discharging current. This opens the possibility of implementing so-called "second-life scenarios" in which, for example, already used (ge ^¬ needed) memory modules that have an altered Powerful ^¬ ness, continue to be used. In addition, can be offered as a degree of redundancy or it can potential tasks to be fulfilled spe-. So it is, for example, think ^¬ bar, in particular in the form of a specific Umrichterarms, re ^¬ gelrechte "victim strands" which means, individual groups of already used memory modules in an older state to use that at particularly high Loads that would damage newer memory modules, especially controlled by the cent ^¬ rale control device preferably be used to prevent damage from the newer (and thus more valuable) memory modules. Of course, however, it is also possible for extreme power requirements or the like via the central control device so to speak to realize a "distributed damage or aging".

As already mentioned, it is possible that a memory module can be made up of several individual cells. Then, it is also possible that the existing of a plurality of memory cell memory modules, which memory module operation unit so controls a memory module operating unit umfas ^¬ sen the memory cells and their charging and discharging that the SpeI ^¬ cherzellen be operated in a certain temperature range and / or in a certain voltage range and / or a charge balance between the memory cells takes place. Particularly in the case of series-connected memory cells, an electronic management system, the memory module operating unit, is integrated into the memory module, which enables the safe operation of the memory module or of each individual memory cell of the memory module in a predetermined temperature and voltage window. This management can as well perform a charge equalization between the memory cells of the memory module, so-called "balancing".

It should also be noted at this point that - realizable ^¬ bar on the memory module operating unit, the control unit and / or the control device itself, the shutdown of the memory modules can be constantly monitored, for example, whether the memory module is fully charged or fully discharged, that means , the maximum or minimum tension ^¬ voltage of the memory module is reached. Then the energy exchange ^¬ between the memory module and the capacitor unit via a correspondingly clever control of Um ^¬ richtersubmoduls, specifically in particular the Gleichspannungs- stellers be prevented and the corresponding Umrichter ^¬ submodule acts ultimately as a "conventional" Umres ^¬ tersubmodul, for example as conventional Marquardt Mehrstufenumrichtersubmodul, so as a Umrichtersubmodul to which no memory module is connected.

The memory module operating unit can be integrated in a control unit ^¬ there, where it should be ^¬ noted at this point that the concepts for the control of such existing from single cells memory modules can also be applied to larger measure ^¬ bars. Thus, for example be provided that when a plurality of memory modules are connected to a capacitor unit or a Umrichtersubmodul, the control unit so controls the memory modules and their loading and unloading ^¬ charging mode that the memory modules in a be ^¬ certain temperature range and / or in a certain voltage range are operated and / or a charge balance between the memory modules takes place. In this way, for example, that is, the "balancing" among several connected to a condenser unit memory modules are discharged through ^¬ and it is of course also conceivable to apply the concepts described in the control device itself, so that for example, a "balancing" also all memory modules the energy storage device can be realized. In a further embodiment of the present invention can be provided that the inverter is a multi-stage converter and / or a converter without intermediate circuit, in particular with a decentralized intermediate circuit, and / or a multi-point converter. As already described, the corresponding converter is composed of a plurality of converter submodules which, for example, can be arranged with their memory modules connected to the phases connecting or individual phases associated converter arms.

In a particularly advantageous embodiment of the present invention can be provided that the inverter is a multi-point converter, in particular a three-point converter, with at least three different, in particular the phases ver ^¬ binding arms, wherein at least one Umrichtersubmodul is provided on each arm. It is possible, therefore, for ^¬ play as to realize a Dreiecksumrichter, the memory modules are arranged between the phases. Ana ^¬ loges applies, for example, multipoint.

In a special, advantageous embodiment, for example, an electrical energy storage device can be rea ^¬ lisiert, the learning at least a three-point inverter with Umrichtersubmodulen with corresponding Gleichspannungsstel- (which ultimately DC-DC converters, respectively), comprising. Here, for example on every different phases verbin ^¬ Denden arm of Dreipunktumrichters a same topology are provided, which comprises for example a respective Umrichtersubmodul, two memory modules can be connected to the two DC voltage controller so that a total of two memory modules per phase result. The construction of each phase is ideally but not necessarily symmetrical chosen be ^¬ züglich the utilization and energy storage modules for each phase are ideally equal ausgestal ^¬ tet. However, this symmetrical structure does not have to apply to the different phases or arms. It should also be noted at this point that the inverters may well have decentralized intermediate circuits, which are then implemented in the Umrichtersubmodulen.

As already mentioned, may be guiding shape provided in a concrete, be ^¬ vorzugten out that the inverter is a Marquardt Mehrstufenumrichter. Possible realizations of a Marquardt Mehrstufenumrichters, can be connected to more memory modules, example ^¬ as in the aforementioned post-published

PCT / EP / 2009/065491. Was first described in the Marquardt-Mehrstufenumrichter in DE 31 101 030 Bl, wherein the converter described therein has Umrichterventile ^(¬ To judge poor) forming a bridge circuit. In this case, each converter valve extends between an AC voltage connection for connecting the converter to an AC voltage network and a DC voltage connection. Each valve has a series arrangement of bipolar submodules, each having a capacitor unit connected in parallel with a power semiconductor circuit. The two connection terminals of each submodule are connected once to the capacitor unit and once to the potential point between the two power semiconductor switches, to each of which a freewheeling diode is connected in parallel in opposite directions. In this way, either a zero voltage or the capacitor unit on the abfal ^¬ loin capacitor voltage can be generated at the two terminals of each submodule. Thus, a so-called multistage DC voltage impressing converter or Marquardt multi-stage converter is provided.

In a development of the invention, the DC voltage positioner can electrically isolate the capacitor unit and the memory module or be designed for the galvanic separation of the capacitor unit and the memory module and / or have a fixed or adjustable transmission ratio. It is therefore conceivable an energy storage device, in which the DC voltage controller galvanic isolation between the Inverter, specifically the Umrichtersubmodul, and the Speichermo ^¬ module, such as a battery, can allow. It can be provided with particular advantage that when operating the energy storage device on the memory module side side, the applied voltage does not exceed a threshold voltage, ^{insbesonde ¬} re 120 V. In such Energiespei ^¬ chervorrichtung is specifically selected the voltage level so that the memory module is below a DC threshold voltage, for example below 120 V or 60 V. High voltages in the inverter, the energy storage device can be lowered to low voltages over a transmission ratio of the DC voltage controller so that the threshold voltage falls below a statutory threshold or not as strong the effect on the people in unachtsa ^¬ mem touch. In this way, a Berührschutzthematik can be avoided, since the memory modules are in the maintenance below a critical Berührschutz critical voltage, in Germany, for example, below 120 V. The voltage actually used of the memory modules can of course by selecting a suitable number of memory cells of the memory module to others border tensions, for example, are tuned to the ört ^¬ union conditions of the network / application / legislation be adapted. It is conceivable, in ^¬ play that may be present on the part of the condenser unit of up to 850 V, which can be advantageous as a power semiconductor, for example when using 1200 V IGBTs, whereas on the side of the memory module, in particular a battery, 117.6 V may be present, for example, by 26 cells 4.2 V can be realized.

Furthermore, it can be provided that the capacitor unit comprises ei ^¬ nen module capacitor, in particular a built-in as part of the DC voltage controller module capacitor. It is therefore conceivable that the module Capacitor in DC is integrated manufacturers provided after anyway DC voltage are known manufacturers that already have input side ei ^¬ nen condenser. If this is provided on the input side provided capacitor used as the capacitor module of the capacitor unit, is advantageously a component incorporated ^¬ saved.

The energy storage device according to the invention can furthermore be characterized in that no memory module is connected to at least one DC voltage controller. Thus, embodiments are also conceivable in which no memory module is fitted to individual converter submodules of the modular converter, but, for example, only one module capacitor for stabilizing the converter submodule. Such Umrichtersubmodule, in which no Speicherermo ^¬ module is equipped, are then operated as a "conventional" Umrichter ^¬ submodule.This may be the case for availability and maintenance ^¬ reasons, with a flexibility is given, the retrofitting or omission of memory modules allowed.

Regarding the control in general, it can be provided that the control device and / or the control units for controlling the DC voltage regulator taking into account the voltage of the memory module and / or the current state of charge of the memory module and / or the remaining capacity of the memory module and / or the performance of the memory module and / or the internal resistance of the SpeI ^¬ chermoduls and / or the aging state of the memory module is formed as an operating parameter. Of course, further or other operating parameters can be taken into account, for example the charging and / or discharging current and the like.

In this case can be used the Umrichtersubmodul at which the memory module is coupled to provide the power Sanforde ^¬ approximations to the memory, according to a control logic which is adapted to the mode of operation. This can, for. For example, it may prefer to load more heavily on memory modules to maximize the overall performance of the system. Similarly, it may be a partial or total discharge or activation individual memory modules to relieve them, to save or possibly to switch maintenance or replacement of the entire system.

It can preferably be provided that the control units and / or the control device and / or provided on each memory module measuring device for automatically determining at least one operating parameter of Speichermo ^¬ duls are formed. Alternatively or additionally, it may be provided that the control device is designed for operating a group of memory modules having at least one memory module in a maintenance mode, and / or measurement mode, in particular for determining a capacity of Speichermodu ^¬ le the group and / or a self-discharge of the memory modules of the group as operating parameters.

It is therefore generally conceivable to use conventional measuring methods in order to determine operating parameters which are taken into account in the control. The state of charge can be determined in some chemistries simply by measuring the voltage of the memory module. A measurement of the inner ^¬ resistance, which may be a useful parameter for determining the aging state of a memory module, for example, can be made possible by the application of a voltage pulse to the memory module, so determine taking into account a measured current of the DC internal resistance leaves. Characterized in that a central Steuerein ^¬ direction is provided, however, it is also possible, the capacity of a memory module and the self-discharge filters festzu ^¬. For example, a group of memory modules, for example, all provided on one arm of the inverter memory modules are separated from the rest of operating for a certain time ^¬ period in which these memory modules are fully ^¬ continuously discharged and / or be fully charged, so that the corresponding Operating parameters and thus in particular the real available capacity of Spei ^¬ chermodule can determine. In order to be able to determine a self-discharge of a storage module as an operating payer, For example, any charging and / or discharging current from a memory module in the measuring mode for a defined time can be avoided and the course of the state of charge, in particular determined on the basis of the voltage of the memory module, can be considered. Seen are various possible ^¬ possibilities conceivable operating parameters, in particular variable operating parameters, it is to identify and deploy as part of the Steue ^¬ tion by the control device or a control unit due to the charge state or the aging state.

In particular, it should be noted at this point that special ^¬ It benefits in control, be it should be done at the level of the control device or at the level of the control units, not only on the voltage of the memory module, but other operating parameters considered who should ^¬. These may, for example, the state of charge of the storage modulus and the remaining capacity, the power ^¬ ability and / or the internal resistance of the memory module, which from ^¬ depend strongly on the memory technology, the aging state of the module, from which in particular ^¬ sondere an adjustment of the operating parameters remaining Capacity, performance and internal resistance results, and the like.

With particular advantage, it can be provided that the control device for determining and / or consideration of a preferred operating window for each memory module of the voltage is bezüg ^¬ Lich least formed and / or the control units for determining and / or consideration of a preferred operating window for each of its assigned memory module with respect to at least the voltage are formed. Such operating window, so for example, a ma ^¬ ximum and minimum allowed or recommended voltage have already been mentioned. Such operating windows can ensure that excessive aging of memory modules is avoided and / or the memory modules can always be used optimally with regard to their performance. It is al However, it should be borne in mind that these preferred, in particular optimum, operating windows can change with the aging ^{status of} the respective memory modules. For this purpose, it can be provided in a particularly preferred embodiment of the present invention that the control device and / or the control units for determining the current operating window of a memory module taking into account at least one of the aging state of the memory module ^¬ writing operating parameter, in particular the Innenwider ^¬ states and / or the Capacity, is formed, in particular on the basis of an operating window in the new state of Spei ^¬ chermoduls under consideration of a database and / or a particular memory module-specific look-up table. Describe so certain operating parameters, in particular the internal resistance and / or capacity, the aging of the memory module, the optimal operating window for different aging conditions depending on these Parame ^¬ ter, in particular memory module specific, present, and therefore be queried accordingly to the operating window adapted as possible to keep the current aging state of the memory module. The "starting values" for different memory modules can already be set as part of the configuration for the memory modules, whereby in particular also certain look-up tables can be preselected.However, it is also possible to enter such starting values for the operating windows manually or otherwise in To bring experience.

In a concrete embodiment of the present invention can be provided that for the configuration of a control unit on a memory module to be controlled by them in a Spei ^¬ cher the control unit several different ^{anschlie ¬} ren memory modules and / or memory module types associated parameter sets of a control algorithm are stored selectable. It is therefore a configurable control algorithm used for the present pre-registered selectable Parame ^¬ tersätze which only have ultimately still be adjusted, for example by hand, if an appropriate Memory module is connected. With particular advantage, however, it is conceivable that a device for automatically detecting a memory module connected to a DC voltage controller is provided, wherein the selection of a parameter set takes place automatically as a function of a memory module detected by the device. For this purpose, in the prior art already several embodiments be ^¬ known, for example, on a storage medium, beispielswei ^¬ se a microchip stored data can be read in connection of the memory module via a communication link by the controller to the memory module with respect to the relevant parameters to identify. Also conceivable, for example, is the use of an RFID technology, in order in particular to enable contactless, ie radio, read-out of the memory module type or other parameters. In a further example, it is conceivable to transport information about particular harmonics once impressed when connecting the memory module. Such electrical energy storage devices, as described by the present invention, can be advantageously used in a wide variety of applications. Examples for this are:

 - Injectors in low, medium, high and low

 High-voltage networks with integrated energy storage, here in the form of memory modules,

 - mains (short) couplings with integrated electric

 Energiespeieher,

 - buffers for sensitive networks / processes, that means, in particular, a supply of a subnetwork whose primary supply has failed, for example to safely transfer critical processes or processes into a defined state,

 - shore connections with optional buffering,

- Solar inverter with integrated electrical energy storage (this can, for example, a variable total DC voltage to search the "maximum power point" (MPP) are provided), Energy storage device / power coupling in one

Electric or hybrid vehicle, wherein when charging the change ^¬ voltage connection of the inverter of Energiespeichervor ^¬ direction is connected to a power grid, in the locomotion of the AC terminal of the inverter is connected to the drive motor and a network buffering can be realized, that means it can, if necessary to be fed back into the AC voltage network (power grid), central charging station for batteries, with an appropriate structure, in particular with a switchable galvanic isolation by the DC voltage controller, a replacement of individual memory modules during operation of the Um ^¬ judge is possible.

Further advantages and details of the present invention will become apparent from the embodiments described below and with reference to the drawing. Showing:

FIG. 1 shows a schematic diagram of an energy storage device according to the invention,

 FIG. 2 shows a possible first, concrete realization of an energy storage device according to the invention,

 Figure 3 shows an implementation of the energy storage device according to the invention in the form of a direct converter, and

 FIG. 4 shows a topology on an arm of a three-point converter.

Figure 1 shows a schematic diagram of an energy storage device according to the invention 1. Specific embodiments with respect to the inverter will be shown with reference to Figures 2 to 4 in the further course.

The energy storage device 1 comprises an inverter 2 which in the present case has a three-phase input 3. The judge 2 can be a multi-stage converter, a converter without intermediate circuit and / or a multi-point converter. The inverter 2 is composed of several Umrichtersubmodulen 4, comprising a condenser unit 5 and are ausgebil ^¬ det for loading and unloading at least one memory module. 6 In the schematic diagram shown in FIG. 1, in each case a memory module 6 is coupled to the capacitor unit 5 via a controllable DC voltage controller 7, in particular a step-up converter, which can also be referred to as a DC / DC converter.

The purpose of the DC voltage controller 7 is, on the one hand, to convert a capacitor voltage applied to the capacitor unit 5 into a charging voltage which is required for charging the memory module. At the same time the DC ^¬ actuator 7 is designed to convert a produced during unloading at the SpeI ^¬ submodule 6 discharge voltage in the capacitor voltage.

Consequently, a decentralized energy store in the form of the individual memory modules 6 is provided in the energy storage device 1, which are each angekop ^¬ pelt to a Umrichtersubmodul 4.

Here, at least two of the memory modules 6 are different ^¬ Lich. While it is always possible that the Spei ^¬ chermodule 6 are of the same memory module type, but differ in their state of health, however, it is presently also conceivable to use different types of modules for memory modules 6, it means specifically different Spei ^¬ chermodule 6 Thus, they differ in their properties related to loading and / or unloading, which has also happened in the exemplary embodiment according to FIG. At least two memory modules 6 may differ in their memory principle and / or their storage capacity and / or their voltage level and / or the chemistry of their storage process and / or their performance. Concretely, it may be provided that at least one memory module a ^¬ Li thium-ion battery, a lithium polymer battery, a lead battery, a nickel-cadmium battery, a nickel Metal hydride battery, a high-temperature battery, a redox flow battery and / or a storage capacitor. As can be seen, a wide variety of memory modules 6 are conceivable. It should be noted at this point that may consist of several memory cells memory modules ^¬ 6, as is customary, but these are not shown in detail here. It is also conceivable for a memory module operating unit to be provided which regulates the memory cells and their charging and discharging operation in such a way that the memory cells are operated in a specific temperature range and / or voltage range and / or charge compensation between the memory cells Memory cells takes place (balancing). This memory module operating unit can be integrated in the control unit 8, which is described in more detail below, which is assigned to each DC voltage regulator 7, but at least can preferably communicate with it if, as is known, it is already installed in the memory module 6. The control units 8 are now the first important

Use basis for the possibility of different memory modules 6, creates, because they are on different Spei ^¬ chermodule 6 or types of memory modules configurable, which means memory module specific or speichermodultypspezi- fish adjustable. For this purpose, in the control units 8 a schematically indicated, configurable control algorithm in conjunction with the present ^¬ various module types associated is stored 9, parameter sets 10, which may be for example, stored in a database. If a memory module 6 is connected, then the associated control unit 8 is by selection of the correct parameter set 10 and using configured dessel ^¬ ben in the control algorithm 9, wherein said A ^¬ position by hand, in particular via a higher-level central ^¬ rale controller 11 can take place, preferably However, a device for automated detection of a rule ^¬ connected to a DC voltage controller 7 memory module 6 not shown in detail is used. For example, the data in a memory device within the Memory module 6 to be stored and retrieved via a corresponding communication connection by the control unit 8, which then automatically selects a parameter set 10 in dependence on the data from the memory module.

Among the parameters in the parameter set includes a preferred operating window for the memory module 6, and in particular we ^¬ nigstens respect to the voltage, but optionally also with respect to temperature, when new, and a rule how to be described in consideration of the aging state of the memory module 6 operating parameters of the Memory module 6 can determine therefrom an operating window corresponding to the aging state, for example a look-up table. Under operating windows are limits, therefore, to understand examples play as voltage limits, temperature limits, which met during operation of the memory module 6 who should ^¬ to realize optimum performance and minimal From ^¬ use of the memory module. 6 It should be noted that the operation window determination can also take place via the central control device 11. In a specific embodiment, it is even conceivable that the control units 8 are integrated in the central control device 11.

Furthermore, as already mentioned, the central control ^device 11 is provided, which ^activates the individual DC voltage controllers 7 -under the intermediary of the control units 8-taking into account the operating data of all the memory modules 6 and external request data 12, for example a power requirement. So this means that a ganzheitli ^¬ ches control concept is provided which is particularly well able to make optimum use of the different properties of the memory modules 6 with regard to the Anforderungsda- th. So it is conceivable that at ho ^¬ hen performance requirements, some memory modules 6 are more suitable, so this should be preferred then discharged, for example, to damage and / or Aging of other memory modules 6 to avoid. Such is useful in particular with regard to so-called second-life scenarios are where old for emergencies Batte ^¬ rien used as storage modules 6 in the energy storage device 1, which are then targeted via the central control ^¬ device. 11 Seen various approaches are possible to advantageously use the knowledge of the different union under ^¬ memory modules. 6

However, independent of the use of different memory modules 6, a central control device 11 can be advantageously used, for example, to realize maintenance cycles and measuring cycles for groups of memory modules 6 by being brought into a maintenance mode or a measuring mode, for example. Maintenance cycles may mean, for example, that the memory modules 6 are completely discharged once, in order then to be completely recharged. Incidentally, the operating parameter of the current capacity of a memory module 6 can also be determined in this way. In this sense, there is also a measurement mode. Conceivable, however, it is also possible to provide in a measurement mode no La ^¬ de- and discharging at a memory module 6 so that its self-discharge can be measured as operating parameters.

General further measurements of operating parameters of the memory modules can be made 6 on principle known manner, so that for example the current charge ^¬ state of a memory module can be read on the voltage at the Spei ^¬ submodule 6 6, the AC or DC indoor resistance of a memory module 6 via a short chip ^¬ voltage pulse and the resulting current can be measured and the like. Control unit 8 and / or control means 11 are also adapted, moreover, from certain Be ^¬ operating parameters, in particular the internal resistance and / or the capacity to derive the state of aging. Overall, in the present case distributed to the ^{Steuerereinhei ¬} th 8 and the controller 11, thus a total control of the power modules 6 based on the request data 12 and the operating parameters, the controller 11 and / or the control units 8, the voltage of the respective memory module 6, the current state of charge take into account the Speichermo ^¬ duls 6, the remaining capacity of the storage module 6, the performance of the storage module 6, the internal resistance of the memory module 6 and the aging state of the Speichermo ^¬ duls 6 as an operating parameter.

Thus, not only different memory modules 6 can be used, but the overall control of the energy storage device 1 is adapted to this advantageous.

It should be noted at this point even more general that it is of course also possible that at least one DC voltage controller 7 no memory module is connected. This may be useful when just less stored energy is needed or a memory module 6 is being serviced. Similarly, this can be useful if temporarily not ge ^¬ nug modules verfüg than returns in "Second Life" scenarios are ^¬ bar. To this end, it should also be noted, moreover, that the DC voltage controller 7 in the present embodiments, the condenser unit 5 and the memory module 6 is formed ent ^¬ not already in principle electrically separates or at least for electrical isolation of the capacitor unit 5 and the storage module 6. in addition, he has a fixed or adjustable gear ratio. in this Wei ^¬ se can be realized namely that during operation of the Ener ^¬ giespeichervorrichtung 1 the voltage applied to a threshold voltage, here 120 V, is not exceeded. on the memory module facing side of the DC voltage controller 7 in this manner a particularly easy handling of the Energiespei ^¬ chervorrichtung 1 is given after the storage modules 6 ultimately easily without considering complex Berührschutzvorschrif have them exchanged. For example, it may be provided that memory modules 6 with memory cells be used so that a maximum Gesamtpan ^¬ voltage of the memory module 6 results close to the threshold voltage, for example, 117.6 V at 120 V threshold voltage. A module capacitor of the capacitor unit 5 can, moreover, here provided as part of the DC voltage controller 7 who ^¬ so that there already existing capacitor used as a capacitor module of the capacitor unit 5 who can ^¬.

FIG. 2 now shows a first, concrete exemplary embodiment, in which the converter 2 is realized as a Marquardt multi-stage converter 13. The inverter 13 consists of a Brü ^¬ bridge circuit of Umrichterventilen or power semiconductor valves 14, 15, 16, 17, 18 and 19, wherein each of said power semiconductor valves which can be referred to as Umrichterarme, between an AC voltage terminal 20 and a positive DC voltage terminal 21 and a negative DC voltage terminal 22 extends. In addition, each power semiconductor valve 14, 15, 16, 17, 18 and 19 has a current flow limiting inductor 23. In Figure 2 is only schematically indicated that each AC voltage terminal 20 is connected to the connection means 3 for connecting an AC voltage network. This is usually done via a transformer or else galvanically with the aid of chokes or coils, which are connected between the AC voltage terminals 20 and the AC voltage network, not shown in Figure 2. It is further seen that each of the Leistungshalblei ^¬ terventile 14, 15, 16, 17, 18 and 19 has a series circuit of bipolar Umrichtersubmodulen 4, all of which are identically constructed. Therefore, in the right half of Figure 2, only a sub-module 4 is shown in more detail. It can be seen that each submodule 4 has a capacitor unit 5 and a power semiconductor circuit 24 which extends parallel to the capacitor unit 5. The Leistungshalblei ^¬ terschaltung 24 has two power semiconductors 25 and 26, which can both be switched on and off. Such power semiconductors 25, 26 are, for example, so-called IGBTs, GTOs, X-FETs, IGCTs or the like. In principle, any switchable power semiconductor can be used in the context of this exemplary embodiment. Each of these controllable power semiconductors 25, 26, a freewheeling diode 27 is connected in parallel opposite directions. Further, a first on ^¬ connecting terminal 28 electrically connected to the capacitor unit 5 ver ^¬ prevented. A second connection terminal 29 is connected to the potential point between the power semiconductors 25 and 26. To the richter ^¬ 13 a capacitor voltage drops in the operation of the condenser unit. 5

As already stated above, each of the power semiconductors 25 or 26 can be transferred from a breaker position, in which a current flow through the respective power semiconductor is interrupted, into its open position, in which a current flow through the power semiconductor 25, 26 in a forward direction allows is and vice versa. If the power semi-conductors 25 and 26 for example, so angesteu ^¬ ert that the power semiconductor, however, 26 is in its breaker position of the power semiconductor 25 in its passage position, the capacitor voltage drops at the output terminals 28 and 29th However, if the power semiconductor 26 is in its open position, the power semiconductor 25 is in its breaker position, the voltage zero drops at the output terminals 28 and 29. Thus, either the capacitor voltage or a zero voltage may be applied to the output terminals 28 and 29.

In addition, it can be seen that the capacitor unit 5 is connected in parallel to a DC voltage controller 7. The DC voltage controller 7 is connected on the output side to a memory module 6, as already illustrated in FIG. Corresponding measuring means as part of the control unit 8 or externally realized are not shown nä forth for clarity.

Figure 3 shows another embodiment: a Umrich ter without central DC circuit. Here, the converter submodules 4 are located on the converter arms 31, 32 and 33 directly between the phases associated AC voltage terminals 20, similar to a cycloconverter. These can be interconnected in chains or individually, care must be taken that the converter submodules are able to work with the alternating current or voltage from their internal topology or through skillful interconnection. Another interconnection z. B. in the star is also conceivable.

FIG. 4 shows a further exemplary embodiment in which a three-phase converter is used as converter 2. For simplicity, corresponding components with appropriate ^¬ speaking reference numerals and it is only a Pha shown se.

As can be seen, the three-point converter also has AC voltage connections 20, on which different phases can be applied. The AC voltage connections are connected via the inverter arms. There are four Leis ^¬ tung semiconductor 34 are visible per arm - 37 are provided, which, in turn, a freewheeling diode is in each case connected in the opposite direction 38 parallel. The pairs of power semiconductors 34, 35 and 36, 37 are coupled via a further two diodes 39, which make it possible to apply the capacitor voltage or a zero voltage via a corresponding circuit of the power semiconductors 34 - 37 to two modulator capacitors 40 here. To each of the module capacitors 40, a memory module 6 is connected via a DC voltage controller 7 in turn coupled, that is, in the present case ^¬ the two memory modules 6 are coupled to a Umrichtersubmodul. 4 Nevertheless, in the present case for driving tion of the two DC voltage controller 7 is a single control unit 8 used. By way of example, this can be done by "balancing" between the two memory modules 6.

It should also be noted that, of course, other embodiments of the inverter and other control structures are possible.

Claims

claims

1. Energy storage device (1) comprising a plurality of SpeI ^¬ chermodule (6) associated to electric energy to a capacitor unit in each case (5) of a converter (2) Umrichtersubmoduls (4) for charging or discharging at least ei ^¬ nes memory module (6) via at least one controllable DC voltage controller (7) are coupled, which DC voltage regulator (7) for converting a voltage applied to the capacitor unit (5) capacitor voltage in a charging voltage, which is required for charging the memory module (6), and for converting a formed during discharging on the memory module (6) resulting discharge voltage in the capacitor voltage, characterized in that a central control device (11) is provided for driving the individual DC voltage controller (7) taking into account operating data of all memory modules (6) and external request data (12) is formed, and / or each capacitor unit (5) and / or each m DC voltage controller (7) is associated with a control unit (8) which is modul ^¬ specifically configured for at least two in one of their charging and discharging properties affecting property different memory modules (6).

2. Energy storage device according to claim 1, characterized in that at least two memory modules (6) differ in one of their charging and discharging properties affecting property, in particular in their storage principle and / or their storage capacity and / or their tension and / or the chemistry their storage process

and / or their state of health and / or its Leistungsfä ^¬ ability.

3. Energy storage device according to claim 1 or 2, characterized in that the memory modules (6) a lithium-ion battery and / or a lithium-polymer battery and / or a lead battery and / or a nickel-cadmium battery and or a nickel-metal hydride battery and / or a High-temperature battery, in particular a sodium-sulfur battery and / or a ZEBRA battery and / or a metal-air battery, and / or a redox flow battery and / or egg ^¬ nen supercapacitor, in particular a double-layer capacitor and / or a Hybrid capacitor include, in particular at least two memory modules from this group.

4. Energy storage device according to one of the preceding claims, characterized in that the converter (2) is a multi-stage converter and / or a converter without intermediate circuit and / or a multi-point converter.

5. Energy storage device according to one of the preceding claims, characterized in that the inverter (2) is a multi-point converter, in particular a three-point converter (30), with at least three different, in particular connecting the phases arms (31, 32, 33), wherein on each Arm (31, 32, 33) at least one Umrichtersubmodul (4) is provided.

6. Energy storage device according to one of the preceding claims, characterized in that the converter (2) is a Marquardt multi-stage converter (13).

7. Energy storage device according to one of the preceding claims, characterized in that the Gleichspannungs- actuator (7) the capacitor unit (5) and the memory module (6) is electrically isolated or formed for galvanic isolation and / or has a fixed or adjustable Überset ^¬ tion ratio ,

8. Energy storage device according to claim 8, characterized in that during operation of the energy storage device (1) on the memory module side of the dc voltage adjuster (7), the applied voltage does not exceed a limiting voltage, in ^¬ particular 120V.

9. Energy storage device according to one of the preceding claims, characterized in that the capacitor input unit (5) comprises a capacitor module (40), in particular a built-up as part of the DC voltage controller (7) Mo ^¬ dulkondensator.

10. Energy storage device according to one of the preceding claims, characterized in that the control units

(8) and / or the control device (11) and / or one on each memory module (6) provided for measuring device for automatic ^¬ tables determining at least one operating parameter of the memory module (6) are formed.

11. Energy storage device according to one of the preceding claims, characterized in that the control device

(11) for operating a group with at least one memory ^¬ module (6) in a maintenance mode and / or measurement mode is ^{ausgebil ¬} det, in particular for determining a capacity of the memory modules (6) and / or a self-discharge of the memory modules (6) as operating parameters ,

12. Energy storage device according to one of the preceding claims, characterized in that the control device

(11) with respect to the voltage for determining and / or consideration of a preferred operating window for each memory module (6) is at least formed and / or the control ^¬ units (8) for detecting and / or consideration of a preferred operating window for each of its associated SpeI ^¬ submodule (6) are formed.

13. Energy storage device according to one of the preceding claims, characterized in that for the configuration ei ^¬ ner control unit (8) to be controlled by them Spei ^¬ chermodul (6) in a memory of the control unit (8) a plurality of different connectable memory modules (6) and / or memory module types associated parameter sets (10) of a Re ^¬ gelungsalgorithmus (9) are stored selectable.

14. Energy storage device according to claim 13, characterized in that a device for automatically detecting is provided to a voltage of a DC voltage controller (7) connected to the memory module (6) is carried out wherein the selection ei ^¬ nes parameter set (10) in response to a detected through the A direction ^¬ memory module (6) automatically.

15. Energy storage device according to one of the preceding claims, characterized in that the control device (11) and / or the control units (8) for controlling the DC voltage controller (7) taking into account the voltage of the memory module (6) and / or the current Ladezu ^¬ states of the memory module (6) and / or the remaining capacity of the memory module (6) and / or the performance of the memory module (6) and / or the internal resistance of the memory module (6) and / or the aging state of the SpeI ^¬ chermoduls (6) as the operating parameter is trained.