DE102023112376B3 - Energy storage device designed as a battery with a marking element identifying an extinguishing opening - Google Patents

Abstract

The present invention relates to an energy storage device (1), wherein the energy storage device (1) is designed as a battery and has a plurality of battery cells. The battery cells are arranged in a receiving space enclosed by a housing (3) of the energy storage device (1), wherein the housing (3) has an extinguishing opening (5) for introducing coolant or extinguishing agent into the receiving space, wherein the housing (3) has on its outside an identification element (9) identifying the position of the extinguishing opening (5), wherein the identification element (9) is recognizable when viewed with a thermal imaging camera and can be distinguished from the areas of the housing (3) without an identification element (9).

Description

The present invention relates to an energy storage device, wherein the energy storage device is designed as a battery and has a large number of battery cells. Such energy storage devices are used, for example, as mobile energy storage devices in electrically or partially electrically powered motor vehicles such as hybrid motor vehicles (HEV - Hybrid Electric Vehicle), plug-in hybrid motor vehicles (PHEV - Plug-in Hybrid Electric Vehicle) or purely electrically powered motor vehicles (BEV - Battery Electric Vehicle) in the form of high-voltage batteries. Furthermore, such energy storage devices are also used as stationary energy storage devices, for example in the form of home storage devices in households or as larger district storage devices in a defined residential area. Home storage devices can, for example, have a storage capacity of 6 to 20 kWh. Home storage devices can, for example, increase the proportion of self-use of photovoltaic electricity.

In the event of a malfunction and/or damage to a battery cell, the battery cell may heat up significantly or even experience thermal runaway. This can, particularly due to thermal propagation, cause the energy storage device to start burning. It may therefore be necessary to extinguish and/or cool the energy storage device using an extinguishing agent supplied from the outside, such as extinguishing water. Even in the case of a fire that does not originate directly from the energy storage device, it is advisable to cool the energy storage device using an externally supplied coolant to avoid damage to the energy storage device and/or thermal runaway of the battery cells due to the heat generated. In order to achieve the most efficient cooling and/or extinguishing of the energy storage device, it is advisable to bring the extinguishing agent or coolant as close to the battery cells as possible, in particular to completely flood the space around the battery cells with extinguishing agent. In this regard, the EN 10 2016 224 473 A1 a system for a vehicle, wherein the system comprises an outer wall with which at least one electrical energy storage device for storing electrical energy for the vehicle can be enclosed and separated from an environment, wherein the outer wall of the system has at least one opening with a closure element for closing the opening, wherein the at least one opening is accessible from the outside by applying pressure to the closure element, wherein an extinguishing liquid can be filled into an interior space enclosed by the outer wall through the opened opening. The opening and the closure element can be assigned a marking that is visible from the outside. The EN 10 2020 118 892 A1 , EN 20 2019 005 008 U1 , CN109552080A , the CN216488362 U and the EN 10 2013 021 416 A1 also describe vehicles in which extinguishing agents or coolants can be supplied to a motor vehicle battery. EN 10 2017 210 615 A1 discloses an electrical energy supply device with an extinguishing device. The EP 4 104 907 A1 discloses a vehicle for fire fighting. The vehicle has a temperature detection system in the form of a thermal imaging camera to detect a point of highest heat in order to introduce extinguishing agent to this point.

The problem with an energy storage system with an extinguishing opening is that the extinguishing agent must be directed specifically into the extinguishing opening in order to feed it to the battery cells and preferably flood the space surrounding the battery cells. In particular, when there is considerable smoke development and/or flame formation, it is usually difficult for the fire-fighting personnel to reliably identify the extinguishing opening and, if necessary, to direct a jet of extinguishing water specifically at the extinguishing opening. EN 10 2021 213 768 B3 a motor vehicle is disclosed with an energy storage device, wherein the energy storage device has an extinguishing opening and a marking of the extinguishing opening, wherein the marking can be a luminous marking. The EN 10 2021 213 768 B3 The energy storage device described has the features of the preamble of patent claim 1.

The object of the present invention is to further develop an energy storage device which has the features of the preamble of patent claim 1 with regard to the identification element.

This object is achieved by an energy storage device having the features of claim 1. Advantageous further developments are the subject of the dependent claims.

The energy storage device according to the invention is designed as a battery and has a large number of battery cells, for example pouch cells or prismatic cells. The energy storage device has a housing, wherein the battery cells are arranged in a receiving space enclosed by a housing of the energy storage device. The housing has an extinguishing opening for introducing coolant or extinguishing agent into the receiving space, wherein the housing has on its outside an identification element identifying the position of the extinguishing opening, wherein the identification element is recognizable when viewed with a thermal imaging camera and can be distinguished from the areas of the housing without an identification element. It is intended that the marking element consists of a ceramic material and/or that the marking element is a coating applied to the housing.

This design has the advantage that the fire opening can be located using a thermal imaging camera even when there is a lot of smoke or in the dark. Nowadays, thermal imaging cameras are standard equipment for firefighters, so that firefighters can use a thermal imaging camera to locate the fire opening if necessary and supply extinguishing water, extinguishing foam or other suitable media in a targeted manner. It is not necessary to connect an extinguishing agent line to the fire opening. Rather, it is considered advantageous if the firefighters keep their distance from the energy storage unit for safety reasons and direct an extinguishing agent jet at the fire opening.

In the event of a thermal event or overheating of one of the battery cells, the housing will heat up and emit thermal radiation. Using a suitable material and/or a suitable surface structure of the marking element, the marking element can be designed in such a way that it can be distinguished from the housing in the wavelength range of infrared radiation. For example, the materials of the housing and the marking element can be different, so that even at the same temperature they have different emissivity and/or a different radiation spectrum in the infrared range and can therefore be distinguished when viewed with a thermal imaging camera.

It is also conceivable that the marking element is thermally insulated from the housing so that when the housing is heated compared to the environment, the marking element has a lower temperature and can therefore be distinguished from the housing when viewed with a thermal imaging camera.

A thermal imaging camera is understood to be a camera that is also or exclusively sensitive in the wavelength range of infrared radiation. In this case, infrared radiation is understood to mean electromagnetic radiation in the wavelength range from 0.7 µm to 1000 µm.

It is considered advantageous if the surface of the marking element differs in terms of its emissivity from the surface surrounding the marking element, for example the surface of the housing. For example, the surface of the marking element could be reflective and the surrounding surface could be black. A suitable structuring of the surfaces is also conceivable.

It is considered advantageous if the marking element consists of a material that has a different radiation characteristic in the wavelength range of infrared radiation than a material surrounding the marking element.

It is considered particularly advantageous, wherein the outer side of the housing is formed by a first material and at least one outer side of the marking element is formed by a second material, wherein a radiation characteristic in the infrared range of the first material and a radiation characteristic in the infrared range of the second material are different.

Preferably, the housing is made of a material that has a higher thermal conductivity than a material of the marking element.

Preferably, the housing is made of a metal or a metal alloy, for example aluminum or steel.

In a preferred embodiment, a warning sign is attached to the outside of the housing, wherein the warning sign is recognizable when viewed with a thermal imaging camera and can be distinguished from the rest of the housing.

In a further development, it is provided that the extinguishing opening is closed with a closure element. This closure element can burst, for example, when exposed to extinguishing agent or coolant. However, it is conceivable that the closure element consists of a material, for example a plastic, which melts at a temperature above a limit temperature, whereby this limit temperature is lower than a melting temperature of the housing material.

Preferably, the closure element is designed to melt or burst in the event of a thermal event of one of the battery cells.

Preferably, the energy storage device is a stationary energy storage device. In principle, however, it is also conceivable that the energy storage device can be used as a high-voltage battery ry in an electrically or partially electrically powered motor vehicle.

It is considered advantageous if the energy storage device is arranged in such a way that the extinguishing opening is formed on a side wall pointing in the horizontal direction. This design is considered advantageous in particular in an embodiment of the energy storage device as a stationary energy storage device, since when installed in a building, a side wall, in particular a front wall pointing into the room, is often easily accessible in order to apply extinguishing agent or coolant to it.

Preferably, the extinguishing opening is formed in the vertical direction above the battery cells.

The battery cells are preferably lithium-ion cells.

The housing is preferably cuboid-shaped.

In a preferred embodiment, the housing has one or more outlet openings for discharging the coolant or extinguishing agent introduced via the extinguishing opening from the receiving space.

It is considered particularly advantageous if the one or more outlet openings are fluidically connected to an extinguishing agent channel for the targeted discharge of the extinguishing agent or coolant flowing out through the one or more outlet openings. In particular in the case of a stationary energy storage device, such an extinguishing agent channel can be used to specifically discharge the extinguishing agent or coolant introduced into areas in which the extinguishing agent or coolant does not cause any damage. For example, the extinguishing agent channel can discharge the extinguishing agent or coolant out of the building. In addition, the extinguishing agent or coolant can be specifically collected via the extinguishing agent channel, as it may contain environmentally harmful contaminants due to contact with the battery cells.

It is considered advantageous if a funnel-shaped extinguishing agent drain is arranged on the housing, wherein the one or more outlet openings open into the extinguishing agent drain at an enlarged end of the extinguishing agent drain.

It is considered particularly advantageous if the marking element is arranged all the way around the erasure opening.

• 1 einen stationären als Batterie ausgebildeten Energiespeicher in einer Vorderansicht,
• 2 der Energiespeicher gemäß 1 in einer Seitenansicht.

The invention is explained in more detail in the following figures using an exemplary embodiment, without being limited to this. They show:

• 1 a stationary energy storage device designed as a battery in a front view,
• 2 the energy storage according to 1 in a side view.

The 1 and 2 each show an energy storage device 1, wherein the energy storage device 1 is a stationary energy storage device 1 arranged in a building. The energy storage device 1 comprises several battery cells 2 for storing electrical energy. The energy storage device 1 is thus a battery, namely a high-voltage battery. The battery cells 2 are arranged in a receiving space 4 enclosed by a housing 3 of the energy storage device 1. On a front side of the housing 3, which is in the 1 shown in a plan view, an extinguishing opening 5 is formed for introducing coolant or extinguishing agent via the extinguishing opening 5 into the receiving space 4 for cooling or extinguishing the battery cells 2. The housing 3 has an outlet opening for discharging the coolant or extinguishing agent introduced via the extinguishing opening 5 from the receiving space 4. A funnel-shaped extinguishing agent outlet 6 is arranged vertically under the housing 3, the outlet opening opening into the extinguishing agent outlet 6 at an enlarged end of the extinguishing agent outlet 6. The flow direction of the extinguishing agent or coolant is indicated by the arrows 13 in the 2 marked. A hose 7 is attached to one outlet end of the extinguishing agent drain 6. The hose 7 forms an extinguishing agent channel for discharging the coolant or extinguishing agent from the building. The extinguishing agent drain 6 is provided with a cover 8.

The housing 3 has on its outside a marking element 9 which identifies the position of the extinguishing opening 5. The marking element 9 consists of a ceramic material, whereas the housing 3 consists of steel. As a result, the marking element 9 is recognizable when viewed with a thermal imaging camera and can be distinguished from the areas of the housing 3 without a marking element 9. As a result, even in the event of heavy smoke development or in the dark, firefighters have the option of using a thermal imaging camera to locate the position of the extinguishing opening 5 and to direct an extinguishing agent jet or coolant jet specifically at the extinguishing opening 5 in order to introduce the extinguishing agent or coolant into the receiving space 4. The marking element 9 in this case is a ceramic coating. The marking element 9 is designed as a rectangular frame that surrounds the erasure opening 5.

A warning sign 10 is also attached to the housing 3. The warning sign 10 is again a ceramic coating. This means that the warning sign 10 can be easily seen in a fire department thermal imaging camera.

A ring 11, e.g. made of fire-resistant steel, is attached to each of the eight corners of the housing 3. These rings 11 enable easier assembly during installation and easier transport by firefighters in the event of a fault, e.g. transport outside using a crane.

The housing 3 is earthed to divert fault currents. To enable rapid removal in the event of a fault, a material-locking or force-locking quick-disconnect device 12 is provided on an earthing line. This can be easily and irreversibly separated mechanically using fire service tools.

List of reference symbols

1

Energy storage

2

Battery cell

3

Housing

4

Recording room

5

Extinguishing opening

6

Extinguishing agent drain

7

Hose

8th

Blindness

9

Label element

10

warning sign

11

ring

12

Quick disconnect device

13

Arrow

Claims (8)

Energy storage device (1), wherein the energy storage device (1) is designed as a battery and has a plurality of battery cells (2), wherein the battery cells (2) are arranged in a receiving space (4) enclosed by a housing (3) of the energy storage device (1), wherein the housing (3) has an extinguishing opening (5) for introducing coolant or extinguishing agent into the receiving space (4), wherein the housing (3) has on its outside an identification element (9) identifying the position of the extinguishing opening (5), wherein the identification element (9) is recognizable when viewed with a thermal imaging camera and can be distinguished from the areas of the housing (3) without an identification element (9), characterized in that (i) the identification element (9) consists of a ceramic material and/or (ii) the identification element (9) is a coating applied to the housing (3). Energy storage (1) to Claim 1 , wherein the housing (3) consists of a metal or a metal alloy. Energy storage (1) to Claim 1 or 2 , wherein the extinguishing opening (5) is closed with a closure element. Energy storage (1) to Claim 3 , wherein the closure element is designed to melt or burst in the event of a thermal event of one of the battery cells (2). Energy storage device (1) according to one of the Claims 1 until 4 , wherein the energy storage device (1) is a stationary energy storage device (1). Energy storage device (1) according to one of the Claims 1 until 5 , wherein the housing (3) has one or more outlet openings for discharging the coolant or extinguishing agent introduced via the extinguishing opening (5) from the receiving space (4). Energy storage (1) to Claim 6 , wherein the one or more outlet openings are fluidically connected to an extinguishing agent channel for the targeted discharge of the extinguishing agent or coolant flowing through the one or more outlet openings. Energy storage (1) to Claim 6 or 7 , wherein a funnel-shaped extinguishing agent outlet (6) is arranged on the housing (3), wherein the one or more outlet openings open into the extinguishing agent outlet (6) at an enlarged end of the extinguishing agent outlet (6).

Images