WO2012167812A1 - Energy storage unit and/or converter unit - Google Patents

Abstract

The invention relates to an energy storage unit and/or converter unit (1) having at least one pressure compensation element (2) in the form of an elastic hollow body. According to the invention, at least one opening in the pressure compensation element (2) is connected to at least one housing opening in a housing (3) of the energy storage unit and/or converter unit (1), wherein the housing opening is sealed in fluid-tight fashion by the pressure compensation element (2) with respect to an external environment of the energy storage unit and/or converter unit (1).

Description

 Energy storage unit and / or converter unit

The invention relates to an energy storage unit and / or converter unit according to the features of the preamble of claim 1.

From the prior art, as described in US 2003/0022059 A1, a container is known in which an electrolyte circulates. The container has a device for preventing pressure changes in the container. The device comprises a pressure compensation element, which as an elastic hollow body of a

acid-resistant and airtight material is formed and disposed in a gas-filled region of the container. An interior of the pressure compensation element is in contact with an external environment of the container, so that the

Pressure compensation element depending on the pressure in the container and the

Ambient pressure expands or contracts.

The invention has for its object to provide an improved energy storage unit and / or converter unit.

The object is achieved by an energy storage unit and / or - converter unit with the features of claim 1.

Preferred embodiments and further developments of the invention are specified in the dependent claims.

An energy storage unit and / or energy converter unit has at least one pressure compensation element configured as an elastic hollow body, d. H. the

Pressure compensation element has an elastic, in particular expandable wall, so that it, like a balloon, can inflate and contract again and formed in this way a variable volume fluid reservoir, in particular gas storage.

According to the invention, at least one opening of the pressure compensation element is connected to at least one housing opening of a housing of the energy storage unit and / or converter unit, wherein the housing opening through the

Pressure compensation element against an external environment of

Energy storage unit and / or converter unit is sealed fluid-tight, d. H. the pressure compensation element acts as a fluid-tight closure of an interior of the

Housing relative to the external environment of the energy storage unit and / or converter unit.

The energy storage unit and / or converter unit may be provided for mobile and / or stationary uses. It is for example one

electrochemical energy storage unit and / or -wandlereinheit, in particular an electrochemical battery with at least one single cell or with a plurality of parallel and / or series electrically interconnected single cells. Such, designed as an electrochemical battery energy storage unit and / or -wandlereinheit is for example a vehicle battery, in particular a battery for a

Hybrid vehicle, a fuel cell vehicle or an electric vehicle.

By means of the pressure compensation element is a fluid exchange, in particular an exchange of air or gas, between the housing and the outer environment of the housing in a change of a housing internal pressure relative to an ambient pressure of the housing or a change in the ambient pressure relative to the

Housing pressure avoided or at least significantly reduced, since a pressure gradient between an interior of the housing and its outer environment is close to zero. In this way, no air exchange takes place by air flowing into the housing.

This is an entry of moisture, especially humidity in the

Housing avoided or at least significantly reduced. In particular, one is

Avoid accumulation of liquid in the housing.

Such an entry of moisture can lead to damage, in particular in the form of corrosion, to parts of the energy storage unit and / or converter unit arranged in the housing. In addition, the moisture can shorts on the housing arranged portions of the energy storage unit and / or -wandlereinheit cause and / or lead to an increase in electrical resistance to the arranged in the housing parts of the energy storage unit and / or -wandlereinheit and thereby to a higher heat loss.

Since this is avoided by the pressure compensation element or at least significantly reduced, for example, corrosion protection requirements on the interior of the

Housing arranged parts reducible, so that the corrosion protection requirements are already met with simple design measures. Thereby are

Production facilitation and cost and weight savings feasible.

Since, as already mentioned, the pressure gradient between the interior of the housing and its outer environment is close to zero, moreover, no complex and costly constructive measures to take to the housing and arranged in the housing parts of the energy storage unit and / or -wandlereinheit sufficient pressure resistant to occurring pressure fluctuations interpret. As a result, manufacturing facilitation and cost and weight savings can be realized. Since such pressure fluctuations do not occur due to the pressure compensation element, there is no risk of explosion or implosion of the energy storage unit and / or converter unit as well as damage to the parts of the energy storage unit and / or converter unit arranged in the housing or at least considerably reduced.

Conveniently, the housing and / or the pressure compensation element are formed at least within a predetermined housing inner pressure range fluid-tight against an outer environment of the housing. This is possible because of the

Pressure compensation, at least within the predetermined housing internal pressure range, only by the pressure compensation element can be realized. Through the fluid-tight housing is an entry of fluids, in particular ambient air and

Humidity, avoided in the case.

The housing and / or the pressure compensation element preferably has at least one overpressure and / or vacuum valve. If a maximum expansion size of the pressure compensation element is limited, for example due to a limited installation space in which it can expand, then the pressure compensation element can realize the pressure compensation only within certain limits, for example tuned to main operating conditions of the energy storage unit and / or

-wandlereinheit.

However, these limits may be exceeded or undershot in exceptional cases, for example in the case of strong changes in ambient pressure or in the event of a malfunction of the energy storage unit and / or converter unit, for example in the event of a short circuit, overload or overcharging. Therefore, such an overpressure and / or vacuum valve is advantageous to an explosion or implosion of the housing and the resulting severe damage to the

Energy storage unit and / or -wandlereinheit and hazards to persons and further damage to the interior parts of the

Energy storage unit and / or converter unit to prevent or at least significantly reduce.

The overpressure and / or vacuum valve is, for example, by means of a

Measuring device controllable, for example by a pressure sensor, by means of which the pressure and / or vacuum valve is switchable. The overpressure and / or

Vacuum valve is closed, for example, in the de-energized state and by

Apply power to open.

A flow path of a compensating air flow through the overpressure and / or

In this case, the vacuum valve preferably runs over or through one with a

Moisture binding agent, for example so-called SILICA particles, filled

Drying cartridge to extract moisture in the housing inflowing air moisture and to prevent moisture entry into the housing even with the pressure relief and / or vacuum valve open or at least significantly reduced. Alternatively or additionally, in the flow path, for example, a gas-permeable, in particular air-permeable and liquid-impermeable membrane, for example

Polytetrafluoroethylene (PTFE), be arranged.

The pressure compensation element is expediently formed from plastic and / or metal, for example from one or more fabrics and / or from one or more films. For stability reasons, for example, a layer structure of several film and / or fabric layers of plastic and / or metal is possible. The pressure compensation element is arranged in an advantageous embodiment within and in a further advantageous embodiment outside of the housing. When using a plurality of pressure compensation elements is also a

Combination of the two embodiments possible, d. H. one or more

Pressure equalization elements are within and one or more further

Pressure compensation elements arranged outside the housing.

The use of multiple pressure compensation elements may be advantageous, for example due to limited space in the housing and / or outside the housing, because then instead of a large, for example, several smaller

Pressure compensation elements can be used. Furthermore, for example, even in a housing having a plurality of separate internal spaces the

Use multiple pressure equalization elements be useful, in which case at least one pressure compensation element should then be provided for each interior of the housing.

Is the pressure compensation element disposed within the housing and with the

Connected housing opening which seals it, as in the pressure compensation element is a shielded from the interior of the housing and connected via the opening in the pressure compensation element connected to the external environment variable air volume, whereby a separation required for the pressure equalization

Amount of fluid, d. H. in particular outside air quantity, from one in the housing

existing fluid quantity, in particular air or gas quantity is realized. As a result, a fluid exchange, in particular an exchange of air or gas, between the housing and the external environment of the housing with a change in the housing internal pressure relative to the ambient pressure of the housing and / or a change in the ambient pressure against the housing internal pressure avoided or at least significantly reduced. In this way, in particular no air exchange takes place by air flowing into the housing.

If the housing internal pressure rises in relation to the ambient pressure and / or if the ambient pressure drops in relation to the housing internal pressure, this is caused by a

Compression of the pressure compensation element and an outflow of air from the pressure compensation element in the external environment immediately compensated. Similarly, when the ambient pressure increases with respect to the housing internal pressure and / or when the housing internal pressure falls from the ambient pressure, this is caused by an inflow ambient air into the pressure compensation element and an expansion of the

Pressure compensation element in the housing immediately compensated, so that the pressure difference is always close to zero.

If the pressure compensation element is arranged outside the housing and connected to the housing opening which seals it, a variable fluid volume which is shielded from the outside environment of the housing and connected to the interior of the housing via the opening in the pressure compensation element is present in the pressure compensation element. If the housing internal pressure rises above the

Ambient pressure and / or the ambient pressure falls over the

Housing pressure from, this is by an influx of fluid from the

Interior of the housing in the pressure compensation element and an expansion of the pressure compensation element immediately compensated. Similarly, when the ambient pressure increases with respect to the housing internal pressure and / or when the housing internal pressure falls from the ambient pressure, this is achieved by compressing the housing

Pressure equalization element and a backflow of the fluid from the

Pressure compensation element in the housing immediately compensated, so that the pressure difference is close to zero at all times.

The opening of the pressure compensation element is arranged in an advantageous embodiment of the housing opening and connected in a further advantageous embodiment by a connecting line with the housing opening. Here, too, a combination of the two embodiments is possible when using a plurality of pressure compensation elements.

The connection of the opening of the pressure-equalizing element with the housing opening via a connecting line, for example a pipe or a hose, is advantageous in order to be able to position the pressure-equalizing element at a favorable position at which, in particular, unimpeded expansion of the

Pressure equalization element is possible. In addition, the pressure compensation element can be positioned in this way at a sheltered location in order to avoid or at least significantly reduce the risk of damage to the pressure compensation element.

Preferably, the housing opening has a connection unit for connecting the pressure compensation element, either directly or indirectly via the connecting line, on, wherein the connection unit is gas-permeable and sealing against liquids and solids, in particular in the form of dust, is formed. For this purpose, the connection unit has, for example, a gas-permeable, in particular

permeable and liquid-impermeable membrane on, for example

Polytetrafluoroethene (PTFE). This can for example be combined with an additional dust filter. Through the connection unit is both an ingress of liquids and contaminants in the pressure compensation element as well as their penetration into the interior of the housing in case of damage to the pressure compensation element, such as bursting, tearing or complete removal of the

Pressure compensation element, prevented or at least greatly reduced.

Alternatively or additionally, the housing opening may have an emergency shut-off valve, which closes the housing opening in the event of damage to the pressure compensation element, for example when it burst, tears or completely clears the housing

Pressure compensation element closes and in this way an intrusion of

Moisture in the interior of the housing prevents. The damage or removal of the pressure compensation element can be determined for example by means of corresponding sensors, which can register, for example, a sudden strong pressure change in the interior of the housing, then to actuate the emergency shut-off valve and close. In particular, at least partially off

Made of metal foils pressure compensation element is for example by means of a

Supervisory circuit, in which the metal foil is integrated, a

Damage to the pressure compensation element by damage to the metal foil and a resulting change in a monitored current, voltage, and / or resistance in the monitoring circuit determined and then the

Emergency shut-off valve can be activated and closed.

The housing is preferably filled with an inert gas or protective gas, for example with nitrogen, carbon dioxide and / or with a noble gas. By means of such

Protective gas or inert gas is for example a risk of fire in the interior of the housing arranged parts of the energy storage unit and / or -wandlereinheit prevented or at least reduced. Since a gas exchange with the outer environment of the housing is prevented or at least significantly reduced by the pressure compensation element, a dilution of the protective gas or inert gas with

Ambient air prevented or at least significantly reduced, whereby the Fire protection effect is maintained even over a very long period of use of the energy storage unit and / or -wandlereinheit.

Conveniently, the housing and / or the pressure compensation element has a valve for filling and / or suction of a fluid, for example for filling and / or suction of the inert gas or inert gas or of air. This valve can

For example, be the pressure and / or vacuum valve or a separate valve.

In particular, the filling of the inert gas or protective gas or the air should be carried out such that the pressure compensation element is filled and inflated in accordance with the prevailing pressure conditions and temperatures during filling. Ie. a respective filling volume must be adjusted accordingly.

If, for example, average ambient and internal pressure conditions and ambient and indoor temperatures prevail, the pressure compensation element should be inflated, for example, up to half the maximum permissible size. In this way, it can expand or contract sufficiently, for example due to changes in pressure and / or volume, for example due to temperature changes.

Embodiments of the invention are explained in more detail below with reference to drawings.

Showing:

Fig. 1 shows schematically an inner air volume change in a battery after

 State of the art,

Fig. 2 shows schematically an internal pressure change in a battery after

 State of the art,

3 shows schematically a first exemplary embodiment of an energy storage unit and / or converter unit in a first operating state, 4 schematically shows a first exemplary embodiment of an energy storage unit and / or converter unit in a second operating state,

5 schematically shows a second embodiment of an energy storage unit and / or converter unit,

6 shows schematically a third exemplary embodiment of an energy storage unit and / or converter unit,

Fig. 7 shows schematically a housing internal pressure change in a

 Energy storage unit and / or converter unit and

8 shows schematically a fluid volume change of a fluid

 Energy storage unit and / or converter unit.

Corresponding parts are provided in all figures with the same reference numerals.

FIG. 1 schematically shows an inner air volume change dVB as a function of a change in a battery temperature TB in a battery according to the prior art with a battery housing not sealed to an environment. In a closure of the battery case, which took place in the example shown here at a battery temperature TB of 20 ° C, the battery had an internal volume of air in a battery compartment, for example, ten liters. This inside air volume results from a free space which is still present in the battery housing and is filled with air.

In an operation of the battery this is always exposed to temperature changes, for example, by heating during charging and discharging and by

Cooling in unused phases of the battery. In addition, external effects

Temperature changes on the battery and heat or cool this.

When the battery temperature TB rises, as shown in FIG

Expansion and thereby an inner air volume increase in the existing in the battery housing inside air instead, at a battery temperature TB of 60 ° C, for example, 1, 4 liters, so that due to the non-sealed battery housing inside air in the Environment escapes. At a decreasing battery temperature TB finds, as also shown in Figure 1, an internal air volume reduction of the existing inside the battery housing, at a battery temperature TB of -40 ° C, for example, -2 liters, so that due to the unsealed battery housing ambient air from the environment Battery flows into the battery housing.

In this influx of ambient air from the environment of the battery in the battery case is also an entry of humidity in the battery case instead. As a result, moisture accumulating in the battery housing can lead to corrosion damage, so that costly and costly corrosion protection measures must be taken. In addition, the moisture can cause short circuits to battery parts arranged in the battery housing and / or lead to an increase of an electrical resistance to the arranged in the battery case battery parts and thereby to a higher heat loss.

To avoid this, the battery case must be completely sealed from the environment so that there is no air exchange between the battery compartment and the environment. However, this leads, as shown in Figure 2, to

Internal pressure changes dPB inside the battery in the already described temperature changes. If the battery is manufactured, for example, at 20 ° C. at an ambient temperature which then corresponds to the battery temperature TB, then an internal pressure in the battery housing corresponds to a battery temperature TB of 20 ° C.

Ambient pressure, d. H. a pressure difference between internal pressure in the battery case and ambient pressure is zero.

In the case of temperature increases, since the air can not escape from the battery housing, an internal pressure increase relative to the ambient pressure takes place, for example at a battery temperature TB of 60 ° C. by 140 mbar. When the temperature is reduced accordingly, since no air from the environment can flow into the battery case, an internal pressure reduction relative to the ambient pressure instead, at a battery temperature TB of -40 ° C, for example by -200 mbar.

These internal pressure changes dPB can lead to an explosion or an implosion of the battery, i. H. to considerable damage or to complete

Destruction of the battery, and also endanger persons in the vicinity of the battery. Furthermore, these internal pressure changes dPB, even if the Battery housing withstands this, leading to damage or destruction of arranged in the battery case battery parts.

To avoid this, complex and costly constructive measures are required, for example, a correspondingly reinforced battery housing, which withstands the internal pressure changes dPB, and corresponding to the occurring

Internal pressure changes dPB designed battery parts. Alternatively, from a given internal pressure value ranges, a pressure equalization with the environment is again possible, from which, however, an entry of moisture into the battery housing with the already described disadvantages results.

In the figures 3 to 6 are embodiments of an inventive

Energy storage unit and / or -wandlereinheit 1 shown, by means of which, as shown in Figures 7 and 8, a constant internal pressure and a housing

Fluid volume change of a relation to an external environment fluid-sealed fluid at least within a predetermined volume range and thereby within a predetermined temperature range is made possible, whereby the described disadvantages of batteries are avoided according to the prior art. To illustrate this, in Figure 7, a housing internal pressure change dPE in

Dependence on a temperature TE of the energy storage unit and / or

converter volume 1 and in FIG. 8 a fluid volume change dVE as a function of the temperature TE of the energy storage unit and / or converter unit 1.

The energy storage unit and / or converter unit 1 may be provided for mobile and / or stationary uses. It is for example one

electrochemical energy storage unit and / or -wandlereinheit 1, in particular, as in the embodiments shown here, an electrochemical battery with at least one single cell or with a plurality of parallel and / or series electrically interconnected single cells. Such, formed as an electrochemical battery energy storage unit and / or -wandlereinheit 1 is for example a vehicle battery, in particular a battery for a hybrid vehicle, a

Fuel cell vehicle or an electric vehicle.

The energy storage unit and / or -wandlereinheit 1 has, as shown in Figures 3 to 6, at least one designed as an elastic hollow body

Pressure equalization element 2, that is, the pressure compensation element 2 has an elastic, in particular expandable wall, so that it, analogous to a balloon, can inflate and contract again and in this way one

volume variable fluid reservoir, in particular gas accumulator forms. The

Pressure compensation element 2 is formed, for example, from plastic and / or metal, for example from one or more fabrics and / or from one or more films. For stability reasons, for example, a layer structure of several film and / or fabric layers of plastic and / or metal is possible.

An opening of the pressure compensation element 2 is connected to a housing opening of a housing 3 of the energy storage unit and / or converter unit 1 in such a way that the housing opening is closed in a fluid-tight manner by the pressure compensation element 2 with respect to the external environment of the energy storage unit and / or converter unit 1, d. H. the pressure compensation element 2 acts as a fluid-tight closure of a

Interior 4 of the housing 3 with respect to the external environment of the

Energy storage unit and / or -wandlereinheit 1. The housing 3 is closed at all other locations at least largely closed to the outside environment. Fiuiddicht means in this context that an exchange of liquids and gases, in particular of air and moisture, for example in the form of humidity, between the interior 4 of the housing 3 and the external environment is at least largely prevented.

In FIGS. 3 and 4, the pressure compensation element 2 is arranged inside the housing 3 and fastened to a connection unit 5 of the housing opening, via which the pressure compensation element 2 is connected to the external environment, i. H. is connected to outside air in the external environment. About this connection unit 5 is the

Pressure compensation element 2 largely pressure-difference-free connected to the external environment and thereby the volume work with the external environment, d. h with the outside air.

The connection unit 5 is gas-permeable and sealing against liquids and solids, in particular in the form of dust formed. For this purpose, the connection unit 5, for example, a gas-permeable, in particular air-permeable and liquid-impermeable membrane, for example of polytetrafluoroethylene (PTFE). This can for example be combined with an additional dust filter. By the connection unit 5 is both an intrusion of liquids and

Dirt in the pressure compensation element 2 as well as their penetration into the interior 4 of the housing 3 in the event of damage to the pressure compensation element 2, for example, when bursting, tearing or completely removing the

Pressure compensation element 2, prevented or at least greatly reduced.

In the interior 4 of the housing 3 parts 6 of the energy storage unit and / or converter unit 1 are arranged. These are only schematically indicated here for the sake of simplified illustration.

In an energy storage unit designed as a battery and / or converter unit 1, such parts 6, d. H. Such battery internals, for example, a plurality of electrically series and / or parallel interconnected individual cells. In addition, these may be, for example, one or more tempering devices for tempering the individual cells, for example heat-conducting plates, and furthermore, alternatively or additionally, for example electrical connection devices and / or

Monitoring equipment. These parts 6 in the interior 4 of the housing 3 are at least largely volume-solid, d. H. they do not change their volume or at least not significantly.

Since the pressure compensation element 2 in that shown in Figures 3 and 4

Embodiment disposed within the housing 3 and connected to the housing opening, wherein it seals the interior 4 of the housing 3 from the outside, is in the pressure compensation element 2 with respect to the interior 4 of the housing 3 shielded and the opening in the pressure compensation element 2 with the outer Surrounding associated variable air volume, whereby a separation of a required for pressure equalization fluid amount, d. H. in particular, the amount of outside air is realized by a quantity of fluid in the housing 3, in particular by air or gas. As a result, a fluid exchange, in particular an air or gas exchange, between the housing 3 and the external environment of

Housing 3 at a change in the housing internal pressure relative to the

Ambient pressure of the housing 3 and / or avoided in a change in the ambient pressure relative to the housing internal pressure or at least significantly reduced. In this way, in particular no air exchange takes place through in the housing. 3

inflowing air.

By means of the pressure compensation element 2, as shown in Figure 3, already a slight increase in the housing internal pressure relative to the ambient pressure, for Example due to an increase in temperature in the interior 4 of the housing 3 and / or a slight drop in the ambient pressure relative to the housing internal pressure, for example due to an uphill drive of a vehicle, such as

Vehicle battery formed energy storage unit and / or -wandlereinheit 1, by compressing the pressure compensation element 2 and a

Outflow of air from the pressure compensation element 2 in the external environment immediately compensated. This is schematically indicated in FIG. 3 by a first arrow P1 directed into the external environment. In this case, there is no leakage of fluid, such as air, from the pressure compensation element 2 surrounding the interior 4 of the housing 3 in the external environment, since this is closed fluid-tight.

Analogously, as shown in Figure 4, already a slight increase in the

Ambient pressure relative to the housing internal pressure, for example due to a downhill and / or a slight drop in the housing internal pressure relative to the ambient pressure, for example due to a decrease in temperature in the interior 4, by an influx of ambient air into the pressure compensation element 2 and an expansion of the pressure compensation element 2 in the housing 3 immediately compensated. This is schematically indicated in FIG. 4 by a second arrow P2 directed into the pressure compensation element 2. In this case, the expanded pressure compensation element 2 replaces the volume of the compressed fluid, d. H. During this process, there is no inflow of ambient air and humidity from the external environment into the interior 4 of the housing 3 surrounding the pressure compensation element 2, since the latter is sealed in a fluid-tight manner.

In both cases, due to the effect of the pressure compensation element 2 the

Pressure difference between the housing internal pressure and the ambient pressure in the external environment of the housing 3 at any time near zero.

In the figures 5 and 6 alternative embodiments are shown, in which the pressure compensation element 2 outside the housing 3 and arranged with the

Housing opening is connected, wherein here also the housing 3 and by the fluid-tight connection of the pressure compensation element 2 with the housing opening and an interior of the pressure compensation element 2 fluid-tight with respect to the outer

Environment are closed. In this case, the pressure compensation element 2, as shown in Figure 5, attached directly to the terminal unit 5 of the housing opening or, as in 6, connected via a connecting line 7, which is fixed to the connection unit 5, connected to the housing opening. The connection line 7 formed, for example, as a pipe or hose and, for example, made of plastic or metal, is advantageous, for example, in order to be able to position the pressure compensation element 2 at a favorable position, on which, in particular, unimpeded expansion of the pressure compensation element 2 is possible. In addition, the pressure compensation element 2 can be positioned in this way at a protected location to reduce the risk of

Damage to the pressure compensation element 2 to avoid or at least significantly reduce.

The connection unit 5 shown in FIGS. 5 and 6 may have a similar structure as already described with reference to FIGS. H. gas-permeable and in particular sealing against liquids, for example by means of the gas-permeable, in particular air-permeable and liquid-impermeable membrane, for example of polytetrafluoroethylene (PTFE). The dust filter for retaining dust particles is not absolutely necessary here, since the connection unit 5 in the in FIGS. 5 and 6

illustrated embodiments in particular a penetration of liquids into the interior 4 of the housing 3 in the event of damage to the

Pressure equalization element 2, for example, in a burst, tearing or

complete removal of the pressure compensation element 2, prevent or at least greatly reduce. However, the dust filter may also be present to even a penetration of dust into the interior 4 of the housing 3 or usefully already a pollution and clogging of the gas-permeable and

to prevent liquid-impermeable membrane.

Alternatively or additionally, the housing opening a not shown here

Notabschlussventil have, which the housing opening in case of damage to the pressure compensation element 2, for example, in a burst, tearing or

completely removing the pressure compensation element 2 closes and prevents in this way penetration of moisture into the interior 4 of the housing 3. This applies both to the exemplary embodiments illustrated in FIGS. 5 and 6 and to the exemplary embodiment illustrated in FIGS. 3 and 4.

The damage or removal of the pressure compensation element 2 is

be determined for example by means of corresponding sensors, which, for example, a can register sudden strong pressure change in the interior 4 of the housing 3, then to actuate the emergency shut-off valve and close. In particular in the case of a pressure compensation element 2 made at least partially from metal foils, damage to the pressure compensation element 2 by means of a monitoring circuit, in which the metal foil is embedded, is damaged

Damage to the metal foil and a resulting change in a monitored current, voltage, and / or resistance in the monitoring circuit can be determined and then the emergency shut-off valve controlled and closed.

Due to the arrangement of the pressure compensation element 2 outside the housing 3 is in the pressure compensation element 2 a shielded from the outer environment of the housing 3 and connected via the opening in the pressure compensation element 2 with the interior 4 of the housing 3 variable fluid volume available. In this way, there is already a slight increase in the internal pressure of the housing relative to the ambient pressure and / or a slight drop in the ambient pressure relative to the housing internal pressure, for example due to the reasons already mentioned above, due to an inflow of the fluid from the interior 4 of the housing 3 into the pressure compensation element 2 and an expansion of the pressure compensation element 2 immediately compensated. In this case, there is no leakage of fluid, for example air, from the interior 4 of the housing 3 in the outer environment, since this is closed fluid-tight.

Analog is already a slight increase in the ambient pressure compared to the internal pressure of the housing and / or a slight drop in the housing internal pressure relative to the ambient pressure, for example, due to the reasons already mentioned above, by a compression of the pressure compensation element 2 and a

Backflow of the fluid from the pressure compensation element 2 in the housing 3 immediately compensated. In this case, there is no inflow of ambient air and humidity from the external environment in the interior 4 of the housing 3, since it is closed fluid-tight.

In both cases, due to the effect of the pressure compensation element 2 the

Pressure difference between the housing internal pressure and the ambient pressure in the external environment of the housing 3 at any time near zero. In all embodiments illustrated in FIGS. 3 to 6, the interior 4 of the housing 3 is preferably filled with an inert gas or inert gas, for example with nitrogen, carbon dioxide and / or with a noble gas. By means of such

Protective gas or inert gas, for example, a risk of fire in the interior 4 of the housing 3 arranged parts 6 of the energy storage unit and / or -wandlereinheit 1 can be prevented or at least reduced. Since a gas exchange with the outer environment of the housing 3 is prevented or at least significantly reduced by the pressure compensation element 2, a dilution of the protective gas or inert gas with

Ambient air prevented or at least significantly reduced, whereby the

Fire protection effect is maintained over a very long service life of the energy storage unit and / or -wandlereinheit 1 away.

Conveniently, the housing 3 and / or the pressure compensation element 2 has a valve, not shown here, for filling and / or aspirating a fluid, in particular for filling in the inert gas or protective gas. In particular, the filling of the inert gas or inert gas or, if this is not used, the filling of air, should be carried out such that the pressure compensation element 2 according to the pressure conditions prevailing during filling and

Temperatures are filled and bloated. Ie. a respective filling volume must be adjusted accordingly.

If, for example, average ambient and internal pressure conditions and ambient and interior temperatures prevail, the pressure compensation element 2 should be inflated, for example, up to half the maximum permissible size. In this way, it can, for example, with housing internal pressure changes dPE and / or fluid volume changes dVE, for example, due to temperature changes, still sufficiently expand or contract.

By means of the pressure compensation element 2, as already described, the disadvantages known from the prior art can be avoided, since a pressure gradient between the interior 4 of the housing 3 and its external environment is close to zero and thereby a fluid exchange, in particular an air or gas exchange, between the housing 3 and the external environment of the housing 3 when the internal pressure of the housing changes with respect to the ambient pressure of the housing 3 and / or when the ambient pressure with respect to the housing internal pressure changes or at least significantly reduced. In this way, in particular no

Air exchange by nachströmende in the housing 3 air.

As a result, the entry of moisture, in particular humidity in the housing 3 is avoided or at least significantly reduced. In particular, one is

Accumulation of liquid in the housing 3 avoided. Because this and that

connected, already described disadvantages avoided by the pressure compensation element 2 or at least significantly reduced, for example

Corrosion protection requirements for the arranged in the interior 4 of the housing 3 parts 6 of the energy storage unit and / or -wandlereinheit 1 reduced, so that the corrosion protection requirements are already met with simple constructive measures. As a result, manufacturing facilitation and cost and weight savings can be realized.

Since, as already mentioned, the pressure gradient between the interior 4 of the housing 3 and its outer environment is close to zero, also no complex and costly constructive measures to take to the housing 3 and arranged in the housing 3 parts 6 of the energy storage unit and /or

converter unit 1 sufficient pressure resistant to occurring

Chassis internal pressure changes dPE interpreted. Thereby are

Production facilitation and cost and weight savings feasible. Since such internal pressure changes dPE due to the

Pressure equalization element 2 does not occur, there is a risk of explosion or

Implosion of the energy storage unit and / or converter unit 1 and damage to the arranged in the housing 3 parts 6 of the energy storage unit and / or

transducer unit 1 not present or at least considerably reduced.

Is the interior 4 in the housing 3, in particular a not through the parts 6 of

Energy storage unit and / or converter unit 1, but by air or the

Interior space filled inert or inert gas is very large and / or a maximum expansion size of the pressure compensation element 2 is limited, for example, due to a limited space in which it can expand, the pressure compensation element 2 can realize the pressure compensation only within certain limits, for example, tuned to main operating conditions of the

Energy storage unit and / or converter unit 1. These main operating conditions For example, according to the annual mean values of the temperatures that are given.

However, these limits can be exceeded or undershot, for example, in extreme cases, for example, in strong ambient pressure changes or malfunction of the energy storage unit and / or -wandlereinheit 1, for example in the event of a short circuit, overload, overcharging or in a

Fire situation of the energy storage unit and / or converter unit 1 or for example of the vehicle, in which the energy storage unit and / or converter unit 1 is arranged. Therefore, the housing 3 and / or the pressure compensation element 2 preferably at least one not shown here overpressure and / or vacuum valve to an explosion or implosion of the housing 3 and the resulting strong

Damage to the energy storage unit and / or converter unit 1 and

To prevent hazards to persons and further damage to the arranged in the interior 4 parts 6 of the energy storage unit and / or -wandlereinheit 1 or at least significantly reduce.

The overpressure and / or vacuum valve is, for example, by means of a

Measuring device controllable, for example by a pressure sensor, by means of which the pressure and / or vacuum valve is switchable. The overpressure and / or

Vacuum valve is closed, for example, in the de-energized state and by

Apply power to open.

A flow path of a compensating air flow through the overpressure and / or

In this case, the vacuum valve preferably runs over or through one with a

Moisture binding agent, for example so-called SILICA particles, filled

Drying cartridge to extract moisture in the housing 3 incoming air moisture and moisture entry into the housing 3, d. H. in the interior 4, even when the pressure relief and / or vacuum valve is open to avoid or at least significantly reduce. Alternatively or additionally, in the flow path, for example, a gas-permeable, in particular air-permeable and liquid-impermeable membrane, for example made of polytetrafluoroethylene (PTFE), may be arranged.

If the energy storage unit and / or converter unit 1 is such, d. H. with the

Pressure equalization element 2 and in addition to the pressure and / or vacuum valve formed, this results in an example schematically shown in Figure 7

Pressure curve DK and one example shown schematically in Figure 8

Volume curve VK. As can be seen from the curves DK, VK, this results in a compromise between an isobaric and an isochoric operation of the energy storage unit and / or converter unit 1, the isobaric operation being possible in a temperature range in which the energy storage unit and / or converter unit 1 by default, d. H. within a normal operating temperature range of the energy storage unit and / or converter unit 1.

Within this normal operating temperature range, in the example shown here in the temperature range between 10 ° C and 30 ° C, the pressure compensation element 2 is able by its volume change the pressure balance between the

To ensure ambient pressure and the housing internal pressure, so that the isobaric operation of the energy storage unit and / or converter unit 1 is ensured and no fluid exchange between the interior 4 of the housing 3 and the external environment takes place. Ie. In this normal operating temperature range and thus in normal main operating conditions of the energy storage unit and / or converter unit 1, the advantages can be fully realized by avoiding the fluid exchange. In the example shown here, the possible volume change of

Pressure compensation element 2 to compensate for the fluid volume changes dVE in

Interior 4 of the housing 3, starting from an approximately half filled

Pressure compensation element 2 in a medium normal operating temperature range, between 0.35 L and -0.35 L.

In exceptional cases, as already described, for example in strong

Ambient pressure changes or in the event of a malfunction of the energy storage unit and / or converter unit 1, for example in the event of a short circuit, overload or overcharging, these main operating conditions can be left, however, so that the resulting fluid volume changes dVE are no longer due to the expansion or contraction of the pressure compensation element 2 are compensated. Is no further volume change of

Pressure equalization element 2 more possible, for example, because it is already fully compressed or maximally possible inflated, enters the energy storage unit and / or converter unit 1 in the isochoric operation, ie the housing internal pressure increases with further temperature changes, in the example shown here Temperatures TE of 30 ° C and higher, or falls, in the example shown here from TE temperatures of 10 ° C and lower.

In order to avoid the explosion or implosion of the housing 3 with the consequences described above and damage to the interior 4 of the housing 3 arranged parts 6 of the energy storage unit and / or -wandlereinheit 1 in these cases, opens at predetermined internal pressure values, in the example shown here at an overpressure in the interior 4 of the housing 3 relative to the external environment of 100 mbar and at a negative pressure in the interior 4 of the housing 3 relative to the external environment of -175 mbar, the pressure and / or vacuum valve, so that fluid, such as air or Protective or inert gas from the interior 4 of the

Outflow housing 3 and outside air from the outer environment of the housing 3 can flow into the interior 4 of the housing 3, whereby a stabilization of the housing internal pressure takes place at the respective level and the risk of explosion or implosion of the housing 3 and the damage in the interior 4 of the housing 3 arranged parts 6 of the energy storage unit and / or converter unit 1 is prevented or at least significantly reduced.

Since, as already described, the flow path of the compensating air flow through the overpressure and / or vacuum valve preferably via or through a filled with a moisture-binding agent, for example so-called SILICA particles

Dry cartridge and / or through a gas-permeable, in particular air-permeable and liquid-impermeable membrane, for example made of polytetrafluoroethylene (PTFE), is also in these cases outside the main operating conditions and thus in isochoric operation of the energy storage unit and / or -wandlereinheit 1 of

Moisture entry into the housing 3 avoided or at least significantly reduced.

LIST OF REFERENCE NUMBERS

1 energy storage and / or converter unit

2 pressure compensation element

 3 housing

 4 interior

 5 connection unit

 6 part

 7 connection line

DK pressure curve

dPB internal pressure change

dPE housing internal pressure change

dVB indoor air volume change

dVE fluid volume change

 P1 first arrow

 P2 second arrow

 TB battery temperature

 TE temperature

 VK volume curve

Claims

claims

1. energy storage unit and / or converter unit (1) having at least one pressure compensating element (2) designed as an elastic hollow body,

 characterized in that

 at least one opening of the pressure compensation element (2) is connected to at least one housing opening of a housing (3) of the energy storage unit and / or converter unit (1), wherein the housing opening through the

 Pressure compensation element (2) against an external environment of

 Energy storage unit and / or converter unit (1) is sealed fluid-tight.

2. Energy storage unit and / or converter unit (1) according to claim 1,

 characterized in that

 the housing (3) and / or the pressure compensation element (2) are / at least within a predetermined housing inner pressure range fluid-tight with respect to an outer environment of the housing (3).

3. Energy storage unit and / or converter unit (1) according to claim 1 or 2, characterized in that

 the housing (3) and / or the pressure compensation element (2) have / have at least one overpressure and / or vacuum valve.

4. Energy storage unit and / or converter unit (1) according to one of claims 1 to 3,

 characterized in that

the pressure compensation element (2) made of plastic and / or metal is formed. Energy storage unit and / or converter unit (1) according to one of

previous claims,

characterized in that

the pressure compensation element (2) is arranged inside or outside the housing (3).

Energy storage unit and / or converter unit (1) according to one of

previous claims,

characterized in that

the opening of the pressure compensation element (2) is arranged on the housing opening or is connected by a connecting line (7) with the housing opening.

Energy storage unit and / or converter unit (1) according to one of

previous claims,

characterized in that

the housing opening a connection unit (5) for connecting the

Pressure compensation element (2), which is gas-permeable and sealing against liquids and solids.

Energy storage unit and / or converter unit (1) according to one of

previous claims,

characterized in that

the housing opening has an emergency shut-off valve.

Energy storage unit and / or converter unit (1) according to one of

previous claims,

characterized in that

the housing (3) is filled with an inert gas.

Energy storage unit and / or converter unit (1) according to one of

previous claims,

characterized in that

the housing (3) and / or the pressure compensation element (2) have / has a valve for filling and / or aspirating a fluid.