• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to an accumulator (1) having at least one cell (3) for storing electrical energy and at least one cooling device (2) for cooling or tempering the cell (3), the cooling device (2) at least one NEN coolant channel (5). The cooling device (2) has at least one single-layer or multi-layered film (4, 9) with at least one sensor element (17).
    公开号:AT520411A1
    申请号:T50770/2017
    申请日:2017-09-14
    公开日:2019-03-15
    发明作者:Ing Stefan Gaigg Dipl;Dipl Ing Hintringer Roland
    申请人:Miba Ag;
    IPC主号:
    专利说明:

    The invention relates to an accumulator with at least one cell for storing electrical energy and at least one cooling device for cooling or tempering the cell, the cooling device having at least one coolant channel.
    The lifespan and effectiveness as well as the safety of a rechargeable battery, i.e. of an accumulator, for so-called e-mobility also depend on the temperature during operation. Excessively high temperatures can be dangerous for the batteries and the drive in electric and hybrid vehicles. For this reason, various concepts for cooling or tempering the batteries have already been proposed. The concepts can essentially be divided into two types, namely air cooling and water cooling or generally cooling with liquids. NTC temperature sensors are known for monitoring the heat development, for example from EPCOS AG (https://de.tdk.eu/tdk-de/190976/tech-library/artikel/applications—cases/applications—cases/bodyguards-fuer- battery-and-drive / 190330).
    The present invention has for its object to provide a structurally simple way to monitor at least one operating parameter of an accumulator.
    The object of the invention is achieved in the above-mentioned accumulator in that the cooling device has at least one single-layer or multilayer film with at least one sensor element.
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    The advantage here is that the combination of "foil" with "sensor element" makes it easier to bring the temperature sensor into contact with the cells, since the foil can more easily compensate for tolerances in the cells. The film can therefore contact the cells over the entire area without having to take any further measures (such as, for example, the application of leveling compounds), as a result of which the measurement of the operating parameter can be made more efficient. In addition, a weight reduction can also be achieved through the film, so that the increase in weight can be at least partially compensated for by the additional sensors.
    If in the following only the term "cooling" is used for simplification, the term "temperature control" should also be read. The term “cooling” in the sense of the invention also means the temperature control of the accumulator.
    According to one embodiment variant of the accumulator, it can be provided that the single-layer or multilayer film has at least one separate sensor element for each cell, which makes it possible in a simple manner to detect each cell individually.
    The at least one sensor element is preferably arranged on or in the single-layer or multi-layer film according to another embodiment variant of the battery, as a result of which the structure of the battery can be further simplified. In addition, the effects mentioned above can be better realized.
    In the preferred variant of the accumulator, the at least one sensor element is a thin-film sensor element. On the one hand, the arrangement of the at least one sensor element on the film can be simplified using thin-film technology. On the other hand, the sensor element can also be given a certain flexibility, so that the sensor element can better follow movements of the film.
    In a further preferred embodiment variant of the accumulator, the at least one sensor element is a temperature sensor or a pressure sensor or / 24
    N2017 / 22200-AT-00 a humidity sensor or a leak sensor or a pressure drop sensor, because such sensor elements can be easily integrated into the system.
    It can also be provided that, according to another embodiment variant of the rechargeable battery, the at least one sensor element is formed by a coating of the single-layer or multilayer film, as a result of which the application of the sensor element can be simplified. In addition, the effects mentioned above with regard to the flexibility of the sensor element can thus be achieved more easily.
    According to another preferred embodiment variant of the rechargeable battery, the at least one sensor element is electrically conductively contacted by means of conductor tracks, as a result of which the provision of the film with the sensor element can be further simplified.
    It can be provided that the at least one sensor element is in direct contact with one of the cells, as a result of which the immediacy of the measured value can be improved. In addition, it is thus possible for the cooling device to first go through all the essential manufacturing steps before the sensor element is formed. The sensor element can thus be better protected against damage in the manufacturing phase.
    However, according to another embodiment variant of the rechargeable battery, it can also be provided that the multilayer film comprises at least two plastic films and that the at least one sensor element is arranged between these two plastic films. The sensor arrangement can thus be made more robust, since it can be better protected against environmental influences.
    For the same reason, it can be provided that the multilayer film further has a metal film, the metal film being arranged on the surface of the multilayer film facing away from the cells. In addition, the temperature can in particular be measured more independently of environmental influences, since the film can be used to dissipate heat that does not come from the cells.
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    N2017 / 22200 AT-00
    It can also be provided that the at least one sensor element is connected to a control and / or regulating element and that the volume per unit of time of coolant flowing through the coolant channel is regulated as a function of the measured temperature, thereby increasing the efficiency of the accumulator can, in that it can be operated at least essentially in the appropriate temperature level.
    For a better understanding of the invention, this will be explained in more detail with reference to the following figures.
    Each shows in a simplified, schematic representation:
    1 shows an accumulator in an oblique view with a cooling device.
    FIG. 2 shows the accumulator according to FIG. 1 in an oblique view without a cooling device;
    3 shows a detail from the cooling device;
    4 shows a detail from the cooling device;
    Fig. 5 shows a cooling device with sensor elements arranged.
    In the introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, and the disclosures contained in the entire description can be applied analogously to the same parts with the same reference numerals or the same component names. The location information selected in the description, e.g. above, below, to the side, etc., referring to the figure described and illustrated immediately, and if the position is changed, these are to be applied accordingly to the new position.
    1 and 2 an accumulator 1, i.e. a rechargeable battery, shown in an oblique view, FIG. 1 shows the accumulator 1 with a cooling device 2 and FIG. 2 shows the accumulator 1 without this cooling device 2.
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    The accumulator 1 comprises several cells 3 for electrical energy. In the example shown there are 27 cells 3. However, this number is not to be understood as limiting.
    The cells 3 can be cuboid, cube-shaped, cylindrical, etc.
    Since the basic structure of such accumulators 1 for e-mobility is known from the relevant prior art, reference should be made to avoid repetition.
    As can be seen from the comparison of the two FIGS. 1 and 2, the cooling device 2 is arranged on one side of the accumulator 1, in particular at the top. However, it can also be provided that the cooling device 2 extends over at least two surfaces of the rechargeable battery 1, for example above and to the side and optionally below. Alternatively or additionally, the cooling device 2 can also be arranged between the cells 3.
    It is preferred if the cooling device 2 extends over all cells 3, in particular the upper side of the cells 3 (as can be seen from FIG. 1), so that all cells 3 can be cooled with only one cooling device 2. In principle, however, it is also possible to provide a plurality of cooling devices 2 in the accumulator 1, for example two or three or four, so that, for example, the cells 3 are divided into two or three or four, etc. cooling devices 2.
    It should be pointed out that the terms top side, etc., refer to the installation position of the accumulator 1.
    It should also be pointed out that the cells 3 can have a modular design, so that they can also be referred to by memory modules.
    In addition, it should be pointed out that in the present description the accumulator 1 is described with several cells 3. The accumulator 1 can / 24
    N2017 / 22200-AT-00 also have only one cell 3, so that the explanations in the description can also be applied accordingly to this variant.
    In all of the design variants, the cooling device 2 comprises or consists of a single-layer or multilayer film 4, as can be seen from FIGS. 3 and 4. With this film 4, the cooling device 2 lies against the cells 3, in particular directly. The system takes place, for example, on the top of the cells 3, as was explained above. Since the film 4 is flexible, ie is not stiff, this film 4 can adapt better to unevenness in the cells 3 or between the cells 3. A balancing mass between the cooling device 2 and the cells 3 is not necessary.
    The cooling device 2 can have the one or a multi-layer film 4 on both sides. However, it is also possible that the single-layer or multilayer film 4 is arranged only on the side of the cooling device 2 facing the cells 3, and that this film 4 is combined with a rigid metal layer, for example made of aluminum or an aluminum alloy, which can also form a lid of the accumulator 1.
    Furthermore, the cooling device 2 comprises at least one coolant channel 5, which extends from at least one inlet 6 to at least one outlet 7. The at least one coolant channel 2 is formed within the single or multi-layer film or between two single or multi-layer films 4 or between this film 4 and the metal layer by only partially connecting the film (s) 4 or the film 4 to the metal layer. For example, the at least one coolant channel 5 can be produced by gluing or shitting the foils (s) 4 to form webs 8 (FIG. 4). The at least one coolant channel is formed in the non-connected areas of the film (s) 4 next to the webs 8. Other suitable connection techniques can also be used to connect the film (s) 4 or the film 4 to the metal layer. In general, the connection techniques are preferably selected in such a way that no additional measures have to be taken in order to obtain a liquid-tight design of the connection.
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    The at least one coolant channel 5 can also be made differently. For example, the metal layer can be shaped accordingly, e.g. deep-drawn.
    The coolant channel 5 can be arranged in a meandering shape in the cooling device 2, as can be seen from FIG. 3. The specific representation of the course of the at least one coolant channel 5 in FIG. 3 is only to be understood as an example. The optimized course of the at least one coolant channel 5 is directed among other things. according to the amount of heat to be dissipated, the geometry of the accumulator 1, etc. It can also be provided that more than one coolant channel 5 is formed or arranged in the cooling device 2. In this case, it is advantageous if a common inlet 6 and then a common outlet 7 are arranged in front of the plurality of coolant channels 5, which can each be configured as a collecting channel from which the coolant channels 5 branch or into which they open , However, there is also the possibility that each coolant channel 5 has its own inlet 6 and / or its own outlet 7.
    A liquid, for example a water-glycol mixture, is used in particular as the coolant through which the cooling device 2 flows.
    The cooling device 2 according to FIG. 4 comprises the film 4 and a further single- or multi-layer film 9. The film 4 and the further film 9 are in connection areas 10 with the formation of the at least one coolant channel 5 between the film 4 and the further film 9 connected. The connection areas 10 extend along the longitudinal extent of the at least one coolant channel 5, areas which are not connected remaining between the connection areas 10, in which the at least one coolant channel 5 is formed by the spacing of the film 4 from the further film 9. The film 4 and the further film 9, which is arranged in particular above the film 4, extend over an area which preferably at least approximately, in particular 100%, corresponds to the area of the cooling device 2 (viewed in plan view).
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    N2017 / 22200 AT-00
    The film 4 and the further film 9 can consist of a laminate which has a first plastic film 11, 12, a reinforcement layer 13, 14 connected thereto, a metal film 15 or 16 connected to the reinforcement layer 13 or 14, or one with the reinforcement layer 13 has connected metallized further plastic film. However, it should be pointed out that in particular the film 4 lying against the cells 3 can also be formed in one layer from the plastic film 1.
    In principle, other laminates can also be used. For example, only the foil 4 can be provided with the metal foil 14 or only the further foil 10 with the metal foil 17. Likewise, only the film 4 can have the reinforcement layer 13 or only the further film 10 can have the reinforcement layer 16. Likewise, more than three-layer structures of the film 4 and / or the further film 9 are possible. However, the film 4 and the further film 14 are preferably of the same design.
    The at least one coolant channel 5 is not formed by separate components but is formed by the only partial connection of the film 4 to the further films 10. The wall or the walls of the at least one coolant channel 6 are thus formed by the film 4 and the further film 10, preferably half each.
    The first plastic films 11, 12 and / or the metallized further plastic film preferably consists of at least 80% by weight, in particular at least 90% by weight, of a thermoplastic or an elastomer. The thermoplastic can be selected from a group comprising or consisting of polyethylene (PE), polyoxymethylene (POM), polyamide (PA), in particular PA 6, PA 66, PA 11, PA 12, PA 610, PA 612, polyphenylene sulfide ( PPS), polyethylene terephthalate (PET), cross-linked polyolefins, preferably polypropylene (PP). The elastomer can be selected from a group comprising or consisting of thermoplastic elastomers such as e.g. thermoplastic vulcanizates, olefin, amine, ester-based, thermoplastic polyurethanes, in particular thermoplastic elastomers based on ether / ester, styrene block copolymers, silicone elastomers.
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    N2017 / 22200 AT-00
    It should be mentioned at this point that a plastic is understood to mean a synthetic or natural polymer which is produced from corresponding monomers.
    The first plastic film 11, 12 and / or the metallized further plastic film preferably consists of a so-called sealing film. This has the advantage that the respective foils can be connected directly to one another.
    But it is also possible to use other plastics, e.g. to use thermosetting plastics or thermosetting materials which are then glued together, for example with an adhesive. Two-component adhesive systems based on polyurethane or silicone or hot glue systems are particularly suitable for this purpose.
    The reinforcement layer (s) 13, 14 preferably comprise or consist of a fiber reinforcement, which is preferably designed as a separate layer. The fiber reinforcement can be formed from fibers and / or threads which are selected from a group comprising or consisting of glass fibers, aramid fibers, carbon fibers, mineral fibers, such as, for example, basalt fibers, natural fibers, such as e.g. Hemp, sisal, and combinations thereof.
    Glass fibers are preferably used as the fiber reinforcement layer. The proportion of fibers, in particular glass fibers, in the fiber reinforcement can be at least 80% by weight, in particular at least 90% by weight. The fibers and / or threads of the fiber reinforcement preferably consist exclusively of glass fibers.
    The fibers and / or threads can be present in the fiber reinforcement as scrims, for example as a fleece. However, a woven or knitted fabric made of the fibers and / or threads is preferred. It is also possible that the fabric or knitted fabric is only present in some areas and the remaining areas of the fiber reinforcement are formed by a scrim.
    It is also possible for rubberized fibers and / or threads to be used as or for fiber reinforcement.
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    N2017 / 22200 AT-00
    When using a woven fabric, different types of weave are possible, especially plain, twill or satin weave. A plain weave is preferably used.
    However, it is also possible to use an open-mesh glass fabric or glass scrim.
    A coated paper can also be used as fiber reinforcement. The coating makes the paper liquid-resistant.
    As an alternative or in addition to the fiber reinforcement, the reinforcement layers 13, 14 can have a mineral filling. Calcium carbonate, talc, quartz, wollastonite, kaolin or mica can be used as the mineral filler (mineral filler).
    The metal foil 15, 16 is in particular an aluminum foil. However, other metals can also be used, such as copper or silver.
    The metal foil 15, 16 can have a layer thickness between 5 μm and 100 μm.
    The plastic films 11, 12 can have a layer thickness between 10 μm and 200 μm.
    The layer thickness of the reinforcement layer (s) 13, 14 can be between 5 μm and 50 μm.
    Although the films 4, 9 can in principle be used in the form of the individual films for the production of the cooling device 2, so that the film laminate (s) are only formed in the course of the production of the cooling device 2, it is advantageous if the films 4, 9 can be used as a (laminated) semi-finished product.
    To connect the individual layers of the laminate or the laminates, these can be glued together using adhesives. The adhesives mentioned above are suitable for this. In addition to adhesives, coextrusion and extrusion coating can also be used as a connection option.
    / 24
    N2017 / 22200 AT-00
    Of course, a combination is also possible that several plastics are coextruded and glued together with an extrusion-coated metal or (fiber) reinforcement layer. In general, all known methods for producing composite films or film laminates can be used.
    The cooling device 2 can also have further single-layer or multilayer films, as a result of which coolant channels 5 can be formed in several planes.
    In Fig. 5, the cooling device 2 is now shown in an oblique view from below of the single or multi-layer film 4. As can be seen from this illustration, the single-layer or multilayer film 4 has at least one sensor element 17. Each cell 3 (which are indicated in FIG. 5) is preferably assigned at least one sensor element 17.
    In principle, the sensor element 17 can have any shape and can be arranged at any suitable location on the cooling device 2. In the preferred embodiment variant, however, the at least one sensor element 17 is arranged on or in the single-layer or multilayer film 4 for the above reasons. If it is arranged in the film 4, it can be arranged between two of the above layers of the laminate of the film. However, it is also possible for the at least one sensor element 17 to be arranged within only one layer of the laminate. For this purpose, the sensor element 17 can already be provided when the layer is formed and can be enclosed or enclosed by the material of this layer.
    By "arranged on the film" it is meant that the at least one sensor element 17 on an outside, i.e. an outer surface, the single or multilayer film 4 is arranged.
    It is further preferred if the at least one sensor element 17 is a thin-film sensor element. The thin-film technology itself is known from the relevant literature, so reference is made to the details.
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    It is also possible to apply the sensor element 17 as a (partial) coating on the single-layer or multilayer film 4. The coating can be applied in particular by a printing process (e.g. screen printing, roll printing, inkjet printing, gravure printing, gravure printing, planographic printing, stamp printing), by spraying, vapor deposition, plasma coating, sputtering, powder coating, etc.
    It is also possible for the at least one sensor element 17 to be contacted by wire. However, the electrical contacting of the at least one sensor element 17 by means of at least one conductor track 18 is preferred, as can be seen from FIG. 5. The conductor track 18 is in particular arranged on the same surface of the single-layer or multilayer film 4, 11 on which the at least one sensor element 17 is also arranged.
    Furthermore, the at least one conductor track 18 is preferably also applied using thin-film technology or using a coating method. In this regard, reference is made to the corresponding explanations given above for sensor element 17.
    It is also advantageous if the conductor tracks 18 of the sensor elements 17 are led to the outside for contacting only on one side of the cooling device 2, since this makes contacting easier. If necessary, in particular if two different sensor elements 17 are used, contact can be made to the outside on different sides in order to have a separation of the two sensor elements 17, as shown in FIG. 5 (the two different sensor elements 17 are delimited by a circle or indicated a square).
    It can be advantageous if the at least one inlet 6 and the at least one outlet 7 or generally all inlets 6 and all outlets 7 of the at least one coolant channel 5 are arranged or formed in the region of one side or from the side of the cooling device 2, in which no contacting of the at least one sensor element 17 is provided (for example the two short sides in the embodiment of the cooling device 2 according to FIG. 5).
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    N2017 / 22200 AT-00
    If the at least one sensor element 17 is arranged on an outside of the single-layer or multilayer film 4, this is preferably that surface of the film 4 with which it rests on the cells 3, so that the at least one sensor element 17 also directly on the at least one Cell 3 is present.
    As stated above, the single-layer or multilayer film 4 can also comprise a metal film or a metallized plastic film. In this case, it is advantageous if the metal foil or the metallized plastic foil is arranged on the surface of the multilayer foil 4 facing away from the cells 3. It is particularly advantageous if the cooling device has the two foils 4, 9 and only the foil 9 is provided with the metal foil 16 or the metallized plastic foil.
    The sensor element 17 can be of any design. In the preferred variant of the cooling device 2, however, at least one temperature sensor (circle in FIG. 5) and / or at least one pressure sensor (square in FIG. 5) is used.
    The at least one temperature sensor can be, for example, a thermocouple or a termistor. In principle, other suitable temperature sensors can also be used.
    The temperature sensor can have a thermistor (NTC) or a thermistor (PTC).
    A piezzoelectric sensor, a piezoresistive sensor, a capacitive pressure sensor, etc. can be used as the force or pressure sensor.
    The sensor element 17 can also be a moisture sensor or a leak sensor or a pressure drop sensor.
    Since the sensors are known per se from measurement technology, they are not discussed further or the measurement principles hidden behind them.
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    N2017 / 22200 AT-00
    It is further possible that the at least one sensor element 17 is connected to a control and / or regulating element and that the volume per unit time of coolant flowing through the coolant channel 5 is regulated as a function of the measured temperature. For this purpose, the accumulator 1 can have a corresponding control and / or regulating device or can be assigned to the accumulator 1 such a control and / or regulating device.
    In the preferred embodiment variant, the cooling device 2 is used for cooling and / or temperature control of an accumulator 1. However, other uses of the cooling device 2 are also possible, e.g. Power electronics cooling, stationary accumulators, industrial system cooling of surfaces, etc. The cooling device 2 can therefore be an independent invention, ie without the cells 3 and the accumulator 1. The corresponding statements above regarding the cooling device 2 therefore also apply to this independent invention.
    The exemplary embodiments show or describe possible design variants, wherein combinations of the individual design variants with one another are also possible.
    For the sake of order, it should finally be pointed out that, for a better understanding of the structure of the accumulator 1 or the cooling device 2, these have not necessarily been shown to scale.
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    LIST OF REFERENCE NUMBERS
    accumulator
    cooler
    cell
    foil
    Coolant channel
    inlet
    outlet
    web
    foil
    connecting area
    Plastic film
    Plastic film
    reinforcing layer
    reinforcing layer
    metal foil
    metal foil
    sensor element
    conductor path
    权利要求:
    Claims (11)
    [1]
    claims
    1. Accumulator (1) with at least one cell (3) for storing electrical energy and at least one cooling device (2) for cooling or tempering the cell (3), the cooling device (2) having at least one coolant channel (5), thereby characterized in that the cooling device (2) has at least one single-layer or multilayer film (4, 9) with at least one sensor element (17).
    [2]
    2. Accumulator (1) according to claim 1, characterized in that the single-layer or multilayer film (4, 11) has at least one sensor element (17) for each cell (3).
    [3]
    3. Accumulator (1) according to claim 1 or 2, characterized in that the at least one sensor element (17) is arranged on or in the single-layer or multilayer film (4, 9).
    [4]
    4. Accumulator (1) according to one of claims 1 to 3, characterized in that the at least one sensor element (17) is a thin-film sensor element.
    [5]
    5. Accumulator (1) according to one of claims 1 to 4, characterized in that the at least one sensor element (17) is a temperature sensor or a pressure sensor or a moisture sensor or a leak sensor or a pressure drop sensor.
    [6]
    6. Accumulator (1) according to one of claims 1 to 5, characterized in that the at least one sensor element (17) is formed by a coating of the single-layer or multilayer film (4, 9).
    17/24
    N2017 / 22200 AT-00
    [7]
    7. Accumulator (1) according to one of claims 1 to 6, characterized in that the at least one sensor element (17) is electrically conductively contacted by means of at least one conductor track (18).
    [8]
    8. Accumulator (1) according to one of claims 1 to 7, characterized in that the at least one sensor element (17) bears directly on one of the cells (3).
    [9]
    9. Accumulator (1) according to one of claims 1 to 7, characterized in that the multilayer film (4, 9) comprises at least two plastic films (11, 12) and that the at least one sensor element (17) between these two plastic films (11 , 12) is arranged.
    [10]
    10. The accumulator (1) according to claim 9, characterized in that the at least the multilayer film (4, 9) further comprises a metal film (15, 16), the metal film (15, 16) facing away from the cells (3) Surface of the multilayer film (4, 9) is arranged.
    [11]
    11. Accumulator (1) according to one of claims 1 to 10, characterized in that the at least one sensor element (17) is connected to a control and / or regulating element, and that the volume per unit of time flowing through the coolant channel (5) Coolant is regulated depending on the measured temperature.
    类似技术:
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    同族专利:
    公开号 | 公开日
    AT520411B1|2019-09-15|
    DE112018005115A5|2020-06-18|
    WO2019051519A1|2019-03-21|
    US20200227798A1|2020-07-16|
    CN111418109A|2020-07-14|
    引用文献:
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    法律状态:
    2020-08-15| PC| Change of the owner|Owner name: MIBA EMOBILITY GMBH, AT Effective date: 20200626 |
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50770/2017A|AT520411B1|2017-09-14|2017-09-14|accumulator|ATA50770/2017A| AT520411B1|2017-09-14|2017-09-14|accumulator|
    CN201880052270.3A| CN111418109A|2017-09-14|2018-09-11|Storage battery|
    PCT/AT2018/060204| WO2019051519A1|2017-09-14|2018-09-11|Accumulator|
    US16/638,932| US20200227798A1|2017-09-14|2018-09-11|Accumulator|
    DE112018005115.3T| DE112018005115A5|2017-09-14|2018-09-11|accumulator|
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