DE102019118905A1 - Cooling system and energy storage with one cooling system - Google Patents

Abstract

Cooling system (1) for an energy store, comprising at least one cooling element (3), which has a wall (31) and a volume (32) delimited by the wall (31) and through which a coolant can flow, wherein the cooling element (3) has at least a passage (4) is introduced, which is at least partially separated from the volume (32) by the wall (31), the passage (4) being assigned an emergency opening device which opens when exposed to heat and / or pressure and thereby creates a flow-conducting connection between the volume (32) and the passage (4) and energy storage (17).

Description

The invention relates to a cooling system for an energy store which has at least one cooling element. The invention also relates to an energy store with such a cooling system.

Energy storage devices in the form of lithium-ion batteries are known from the prior art, for example as energy storage devices for electrically powered vehicles. These lithium-ion batteries comprise a multiplicity of energy storage cells in the form of rechargeable battery cells, which have a cell housing and at least two electrodes arranged in the cell housing. In the case of organic lithium-ion batteries, the electrodes are surrounded in the cell housing by an electrolyte based on an organic solvent or solvent mixture.

If such energy storage devices are incorrectly manufactured, if they are damaged during operation, or if they are overstrained by, for example, overcharging, irreversible decomposition of the electrolyte components can occur. For example, oxidative decomposition of the organic solvent can take place on an electrode surface. The heat of reaction formed during this decomposition and the resulting gaseous decomposition products are responsible for a so-called thermal runaway and the resulting destruction of the rechargeable battery cell concerned.

During this thermal runaway, the affected rechargeable battery cell is heated very quickly and locally and there is an associated increase in the internal cell pressure in the cell housing of the rechargeable battery cell concerned. The thermal runaway usually ends in an uncontrolled rupture or bursting of the cell housing and a burnout of the electrolyte components. This process can take place suddenly, in the form of an explosion or locally with the formation of a focal beam.

In order to allow the respective rechargeable battery cell to burn off in a controlled manner in the event of thermal runaway and to prevent the energy store from being completely burned out, the rechargeable battery cells usually each have a predetermined breaking point in the form of a fuse opening. This safety opening opens when a critical internal cell pressure is exceeded and thus prevents the cell housing of the rechargeable battery cell from breaking open in an uncontrolled manner. The increased internal cell pressure, the gaseous decomposition products responsible for this and the resulting heat of reaction can be discharged into a controlled combustion beam, which emerges at the opened fuse opening of the rechargeable battery cell.

If an individual rechargeable battery cell is thermally runaway, there is a risk that the adjacent rechargeable battery cells will be heated to such an extent that thermal runaway can also take place in them. A chain reaction can thus be triggered which only ends when no more rechargeable battery cells can be heated in the effective area of the first battery cell that was thermally broken. In the worst case, the thermal runaway leads to a complete burnout of the energy storage device.

The chain reaction can be interrupted by an additional emergency cooling of the entire energy storage device, so that only a single or a few rechargeable battery cells are destroyed in the event of thermal runaway. Under certain circumstances, this can ensure that the energy storage device continues to function despite the thermal runaway of an individual rechargeable battery cell.

For cooling the energy store in the event of thermal runaway, a separate emergency cooling system is known from the prior art, which is integrated into the energy store in addition to a standard cooling system. This emergency cooling system is only used for emergency cooling of the energy store during thermal runaway or the like.

For example, the DE 20 2007 011 578 U1 a device with an energy store and an air conditioning system, in which the air conditioning system functions as an emergency cooling system and supplies its circulating medium to the energy store during the thermal runaway.

The WO 2011 054 582 A1 describes an energy storage device into which a liquefied gas contained in a container is introduced when a critical temperature is exceeded.

The presence of this additional emergency cooling system increases the total weight of the energy store. In addition, in the event of a single rechargeable battery cell thermal runaway, not only the affected rechargeable battery cell is cooled, but the entire energy store. For this purpose, these additional emergency cooling systems require sufficient coolant, which in turn also has a negative effect on the total weight of the energy storage device.

Furthermore, such emergency cooling systems often have a temperature sensor which monitors the temperature of the energy store. The temperature determined by the temperature sensor is passed on to a thermal management system of the energy store, which starts the emergency cooling system when a critical temperature is exceeded so that the coolant can be fed to the energy store for emergency cooling. The reaction times of these thermal management systems are so long that the chain reaction during thermal runaway is usually very far advanced by the time the coolant reaches the affected rechargeable battery cells.

The invention is therefore based on the object of further developing a cooling system and an energy store with a cooling system of the type mentioned at the outset in such a way that they enable emergency cooling that takes place with a reduced reaction time and is aimed at the area of thermal runaway while simultaneously reducing the total weight of the energy store.

According to the invention, this object is achieved by a cooling system with the features of claim 1 and an energy store with the features of claim 15. The subclaims refer to an advantageous embodiment.

The cooling system according to the invention for an energy store has at least one cooling element which comprises a wall and a volume delimited by the wall and through which a coolant can flow. At least one passage, which is at least partially separated from the volume by the wall, is made in the cooling element. The passage is preferably completely separated from the volume by the wall. An emergency opening device is assigned to the passage, which opens when exposed to heat and / or pressure and thereby creates a flow-conducting connection between the volume and the passage.

The cooling system according to the invention can serve both as a standard cooling system and as an emergency cooling system for an energy store in which such a cooling system is used. In an essentially error-free operation of this energy store, the emergency opening device is closed and the cooling system functions as standard cooling for the energy store.

Essentially error-free means that no errors occur during the operation of the energy store which lead to an impermissible pressure and / or temperature rise above a critical value in one or more of its energy storage cells. As already described, errors in the energy storage device or one of its energy storage cells can occur in the event of faulty manufacture, damage or overuse during operation of the energy storage device and lead to a thermal runaway of one or more of the energy storage cells, which is accompanied by an increase in pressure in the Inside the energy storage cell and / or is connected to an ignition of the energy storage cell.

In particular, the ignition of the energy storage cell can lead to a chain reaction in the energy storage device and its partial or complete destruction. If an internal pressure and / or temperature increase occurs in at least one of the energy storage cells due to such a fault and the internal temperature and / or the internal pressure exceeds a critical value, the emergency opening device opens, creating a flow-conducting connection between the volume and the Passage is established. As a result, the coolant flowing through the volume, which is preferably under pressure, is fed to the energy storage cell concerned. As a result, the affected energy storage cell is preferably cooled in such a way that a thermal runaway of neighboring energy storage cells can be prevented. The cooling system according to the invention thus has the advantage that it can be used both for standard cooling of the energy store in its essentially fault-free operation and for emergency cooling during the thermal runaway of one or more energy storage cells. This has a positive effect on the total weight of an energy store in which such a cooling system is installed. Since the emergency opening device can already be opened by the action of heat and / or pressure, an additional temperature and / or pressure sensor in the energy store can be dispensed with. Rather, the emergency opening device reacts directly and essentially without delay. This significantly shortens the reaction time of the cooling system in the event of a thermal runaway, so that a chain reaction can be partially or even completely prevented.

It is particularly advantageous here that no active components, sensors or other electrical components are required for the emergency cooling to function. No additional electrical energy is required for the emergency cooling to function.

The passage can have a circular, elliptical or rectangular cross section. In addition, it can also be conical.

In a first advantageous embodiment of the cooling system according to the invention, the emergency opening device comprises a coolant outlet opening introduced in the area of the passage and a closure element which closes the coolant outlet opening. This closure element becomes detached from the coolant outlet opening when pressure and / or temperature act, as a result of which the fluid-conducting connection is formed between the volume and the passage and coolant can exit from the volume into the passage. The cooling element can be designed in the form of a plate, the passage being introduced into the cooling element, crossing from a first cooler wall to a second cooler wall of the cooling element which is essentially opposite the first cooler wall. In order to improve the supply of the coolant from the volume of the cooling element through the coolant outlet opening into the passage and towards the energy storage cell, the coolant outlet opening can be designed in the shape of a nozzle.

In a further advantageous embodiment of the cooling system according to the invention, the closure element of the emergency opening device is designed as a plug. The plug can be manufactured as a separate component which is inserted into the coolant outlet opening during the final manufacture of the cooling element.

In a further advantageous embodiment of the cooling system according to the invention, the plug has a first section, which is arranged in the coolant outlet opening, and a second section, which covers the coolant outlet opening at least in sections. A further advantageous embodiment of the cooling system according to the invention provides that the second section covers the coolant outlet opening at least in sections on an outer side of the wall facing the passage. As a result of the action of temperature, the plug can in this case be detached from the coolant outlet opening, for example by melting.

In contrast to this, a further advantageous embodiment of the cooling system according to the invention provides that the second section covers the coolant outlet opening at least in sections on an inside of the wall facing the volume. If the second section is arranged on an inside of the wall facing the volume, the stopper can be pressed into the volume of the cooling element by the action of pressure and / or melted by the action of heat.

In a further advantageous embodiment of the cooling system according to the invention, the closure element is designed as an insert which, in sections, forms the wall of the cooling element and delimits the passage. In this case, the insert can also be manufactured as a separate component and inserted into the passage of the cooling element during the final manufacture of the cooling system.

Another advantageous embodiment of the cooling system according to the invention provides that the insert is designed as a hollow body. This hollow body has a base surface with a first hollow body opening, a top surface with a second hollow body opening and a jacket connecting the base surface and the top surface to one another. The base area, the top area and the jacket define an inner area of the hollow body. In this embodiment, the hollow body openings are formed from the jacket with essentially circumferential latching units, the latching units being formed on an outer side of the casing facing away from the inner area and at least one melting area essentially covering the coolant outlet opening being arranged between the latching units.

The insert is inserted or inserted into the passage in such a way that the first hollow body opening is arranged in the region of a first passage opening and the second hollow body opening is arranged in the region of a second passage opening of the passage. The top surface and / or the base surface preferably terminate essentially flush with a cooler wall of the cooling element that is adjacent on both sides of the passage. Essentially flush means that the jacket of the hollow body in the area of the top surface and / or the base surface does not protrude or protrudes only slightly from the passage. In this way, it can be avoided that an excessively large distance or cavity is created between the cooling system and the energy storage cells of the energy store, which would hinder the dissipation of heat from the energy storage cells to the cooling system during the standard cooling of the energy store.

The hollow body can be made of elastomeric plastic for easier insertion of the insert, which is embodied as a hollow body, into the passage.

The base area and the top area of the insert are preferably circular, elliptical or rectangular, independently of one another. If both the base and the top surface are circular, the insert can be cylindrical. The shape of the base and the top surface is selected depending on the geometry of the passage. If the passage has a cylindrical and / or conical shape, an insert in the form of a hollow cylinder is inserted into the passage.

In the melting area, the jacket preferably has a reduced wall thickness, which makes it easier to melt or break the jacket in the melting area. The melting area preferably runs partially or completely around the jacket of the insert. If the insert is a hollow cylinder, the melting area between the two locking elements can be distributed rotationally symmetrically or in segments around the circumference of the hollow cylinder. Furthermore, the jacket of the insert can have a taper in the melting area, so that the melting area assumes an exposed position in the passage.

A further advantageous embodiment of the cooling system according to the invention provides that the latching unit has a projection which protrudes essentially perpendicular to the outer side of the casing and encircles the casing, and at least one elastically deformable latching element. The projection and the latching element form a receptacle for an edge of the wall that encloses either the first or the second passage opening. During the final production of the cooling element, the insert is inserted into the passage through the first or the second passage opening. In order to prevent the locking element from hanging on the edge surrounding the respective passage opening or remaining stuck in the passage opening during insertion, the locking element can be deformed due to its elasticity when it passes through the respective passage opening. After passing through the respective passage opening, it returns to its original shape. The elastic deformability of the locking element thus facilitates the insertion of the hollow body into the passage. After the edge surrounding the respective passage opening has been received in the receptacle, i.e. between the projection and the locking element, it is pressed sealingly against the projection by the locking element so that no coolant can escape from the volume of the cooling element via the locking unit.

The latching element can be designed as a flexurally elastic latching collar which partially or completely encloses the jacket of the hollow body. This achieves an optimal fit of the hollow body in the passage.

The tightness between the insert and the passage of the cooling element can be improved in that, in a further advantageous embodiment of the cooling system according to the invention, a sealing element is assigned to the projection on a side facing the receptacle. The sealing element can in particular be designed as a sealing ring. On a side facing the receptacle, the projection can have a groove running around the jacket, into which the sealing element is inserted.

In a further advantageous embodiment of the battery storage device according to the invention, the energy storage cells and the cooling system are arranged with respect to one another in such a way that the second hollow body opening of the insert inserted into the passage is located on a side of the cooling element facing the fuse opening. In this case, the first hollow body opening is arranged on a side of the cooling element facing away from the securing opening. Thus, a focal beam emerging from the safety opening is first passed through the second hollow body opening, then passes the interior of the insert and ultimately leaves the insert through the first hollow body opening.

So that the coolant contained in the volume and under pressure can be directed towards the opened fuse opening when the energy storage cell thermally passes through, a further advantageous embodiment of the cooling system according to the invention provides that the first hollow body opening has a smaller clear dimension compared to the second hollow body opening . If the insert comprises a circular top surface and a circular base surface, the first hollow body opening has a smaller inner diameter than the second hollow body opening. In both cases, the jacket can be designed to taper essentially conically from the second hollow body opening to the first hollow body opening and is therefore suitable for insertion into a conically designed passage. Furthermore, the insert in the area of a second latching unit encircling the second hollow body opening can have larger external dimensions compared to a first latching unit encircling the first hollow body opening.

In order to ensure easier insertion of the insert into the passage of the cooling element, the first latching unit in a further advantageous embodiment of the cooling system according to the invention, starting from the first hollow body opening along the jacket, initially has a first latching element and then a first projection. In contrast to this, the second latching unit, starting from the second hollow body opening, initially has a second projection along the jacket and then a second latching element. When inserting the insert from the side of the second passage opening into the passage, the first locking element and the second locking element are deformed at the two edges surrounding the passage opening due to their elasticity before the two edges are received in the receptacles formed by the locking units and the locking elements are again return to their original form.

Another advantageous embodiment of the cooling system according to the invention provides that the closure element is made from plastic, in particular from an elastomer. In particular if the closure element is designed as a separate component that is introduced into the passage, it can be designed as an injection molded part.

In a further advantageous embodiment of the cooling system according to the invention, the wall of the cooling element is made of metal, preferably sheet metal. Alternatively, the wall of the cooling element can also be made of plastic.

The wall of the cooling element can comprise at least two sheets of metal, in particular aluminum, or a metal alloy, which are preferably connected to one another in the area of the passage, in particular in the area of the coolant outlet opening, for example by welding. At least a first sheet metal can be reshaped or machined to form the passage.

Furthermore, the cooling element can also be designed as a hose cooler which is arranged on a hose carrier. In this case, the hose carrier has a passage that is complementary to the passage of the hose cooler. This means that the passage extends through the hose cooler and the hose carrier. The hose cooler is preferably made of plastic, in particular synthetic rubber. The hose carrier can be made of injection-molded plastic and is used to stabilize the hose cooler.

In a further advantageous embodiment of the cooling system according to the invention, the closure element and the wall are made in one piece. One-piece means that the closure element and the wall of the cooling element are formed from the same material or that the wall has a coolant outlet opening onto which the closure element was molded. This closure element can be detached from the wall by the action of heat and / or pressure in order to open the coolant outlet opening in the wall during emergency cooling of the energy storage cells.

Another aspect of the invention provides an energy store comprising a plurality of energy storage cells and a cooling system. The energy storage cells each have a cell housing and at least one securing opening assigned to the cell housing. The cooling system has at least the aforementioned features of the cooling system according to the invention or one or more features which are the subject of advantageous embodiments of the cooling system according to the invention. The securing opening is each assigned to a passage of a cooling element of the cooling system. The safety opening can be designed as a burst safety device, in particular as a bursting membrane or bursting disc. The burst protection is a predetermined breaking point in the cell housing of the energy storage cell, which protects the energy storage cell from increased internal cell pressure by bursting when a critical internal cell pressure is reached, thus preventing uncontrolled rupture or bursting of the cell housing. Such an overpressure can arise, for example, as a result of ignition or gas-forming decomposition of a solvent mixture contained in the energy storage cell. If the burst protection bursts due to an increased internal cell pressure, then in the event of a fire in the energy storage cell, a combustion beam can emerge from the cell housing in a controlled manner at this point. Since the securing opening is assigned to the passage, this focal beam can then pass through the passage and be diverted. When the focal beam passes through the passage, the emergency opening device is opened and thus enables emergency cooling of the thermally continuous energy storage cell. Such an energy store has the advantage over the energy stores known from the prior art that no additional emergency cooling system has to be built into the energy store in addition to the standard cooling system. As already mentioned, this allows the total weight of the energy store to be significantly reduced. The energy storage cells of the energy store are preferably arranged on the cooling system. In this case, a thermal paste can be introduced between the energy storage cells and the cooling system to improve the thermal conductivity from the energy storage cells to the cooling system. The energy storage cells are preferably designed as rechargeable battery cells, in particular as lithium-ion battery cells. In the latter case, the energy storage device is thus a rechargeable lithium-ion battery. However, the invention is not limited to a rechargeable lithium-ion battery as an energy store. The energy store can be used as a drive battery in motor vehicles or as some other temporary energy store. Furthermore, the energy store can also comprise several cooling systems. If an emergency opening device has been opened due to thermal runaway of an energy storage cell and the coolant contained in the volume has been at least partially fed to the energy storage cell concerned, a first cooling system assigned to this energy storage cell no longer has sufficient cooling capacity for the standard cooling of the other, still intact energy storage cells assigned to this cooling system on. By the If the energy store comprises further cooling systems in addition to this first cooling system, the energy storage cells assigned to these further cooling systems can still be sufficiently standard-cooled.

An advantageous embodiment of the energy store according to the invention provides that the energy storage cells are arranged on the cooling element, in particular the plate-shaped cooling element, in such a way that a longitudinal axis of the energy storage cells is essentially perpendicular to a cooling surface of the cooling element. In this case, the fuse opening is arranged on a contact surface between the respective energy storage cell and the cooling element. The energy store can have a frame or a frame-like energy storage housing which encloses the energy storage cells in their entirety and ensures a thermally conductive contact between the energy storage cells and the cooling element, in particular during the standard cooling of the energy storage device.

The energy storage cells can be cylindrical, prismatic or designed as pouch cells.

• Figuren näher erläutert. Diese zeigen, jeweils schematisch:
• 1 zeigt ein erstes Ausführungsbeispiel eines erfindungsgemäßen Kühlsystems als schematische Schnittdarstellung;
• 2 zeigt ein zweites Ausführungsbeispiel eines erfindungsgemäßen Kühlsystems als schematische Schnittdarstellung;
• 3 zeigt ein drittes Ausführungsbeispiel eines erfindungsgemäßen Kühlsystems als schematische Schnittdarstellung;
• 4 zeigt ein viertes Ausführungsbeispiel eines erfindungsgemäßen Kühlsystems als schematische Schnittdarstellung;
• 5 zeigt ein Ausführungsbeispiel eines erfindungsgemäßen Energiespeichers, der ein Kühlsystem gemäß dem ersten Ausführungsbeispiel aufweist, als schematische Schnittdarstellung.

Some configurations of the cooling system according to the invention or the energy store according to the invention are described below with reference to FIG

• Figures explained in more detail. These show, each schematically:
• 1 shows a first embodiment of a cooling system according to the invention as a schematic sectional illustration;
• 2 shows a second embodiment of a cooling system according to the invention as a schematic sectional view;
• 3 shows a third embodiment of a cooling system according to the invention as a schematic sectional view;
• 4th shows a fourth embodiment of a cooling system according to the invention as a schematic sectional illustration;
• 5 shows an exemplary embodiment of an energy store according to the invention, which has a cooling system according to the first exemplary embodiment, as a schematic sectional illustration.

1 shows a first embodiment of a cooling system according to the invention 1 as a schematic sectional illustration with a cell bottom shown above in a partial view 2 an energy storage. The cooling system includes a cooling element 3 that one wall 31 and one from the wall 31 limited volume through which a coolant flows 32 having.

The cooling element 3 is designed in the present embodiment as a cooler plate made of plastic and has an upper cooler wall 33 , a lower cooler wall 34 and one the upper cooler wall 33 and the lower cooler wall 34 interconnecting the cooling element 3 traversing, passage 4th on. The passage 4th comprises a first passage opening 41 and a second passage opening 42 , both of which are circular in the present embodiment. Both passage openings 41 , 42 be from an edge 411 , 421 enclosed. The first port 41 has in the present exemplary embodiment one compared to the second passage opening 42 smaller inner diameter. Because of this is the passage 4th from the second passage opening 42 to the first passage opening 41 conically designed.

Furthermore, the cooling system 1 an emergency opening device. In the present exemplary embodiment, this emergency opening device comprises one on the cooling element 3 in the area of the passage 4th arranged coolant outlet opening 5 and this coolant outlet opening 5 closing closure element 6th on. The coolant outlet opening 5 is closed in the present exemplary embodiment, but can be opened in the event of a thermal runaway of the energy storage cell. The closure element 6th is in the present embodiment an insert made of injection molded plastic, which is designed as a hollow body. This use 6th has a base area 61 , a top surface 62 and one the base 61 and the top surface 62 interconnecting coat on. The base 61 and the top surface 62 are circular in the present embodiment. The base 61 , the top surface 62 and the coat 63 define an interior area 64 of the hollow body 6th . The base 61 has a first hollow body opening 611 and the top surface 62 a second hollow body opening 621 on, the first hollow body opening 611 one compared to the second hollow body opening 621 has a smaller inner diameter. Thus, the stake 6th also approximately conical.

On one of the interior 64 facing away from the outside of the jacket comprises the jacket 63 the first hollow body opening 611 and the second hollow body opening 621 circumferential locking units 7th , 8th . Between the locking units 7th , 8th shows the coat 63 a melting range 631 on. This melting range 631 covers the coolant outlet opening 5 completely and runs radially symmetrically around the circumference of the jacket 63 (in 1 not shown). By the action of heat on the Melting range 631 in the event of a thermal runaway of the energy storage cell, this melting range melts 631 and thus opens the coolant outlet opening 5 .

The locking units 7th , 8th each have a perpendicular to the outside of the jacket and the jacket 63 circumferential projection 71 , 81 and in each case an elastically deformable locking element 72 , 73 on. One of the projections each 71 , 81 and in each case one of the elastically deformable locking elements 72 , 82 form a recording 73 , 83 for either the first passage opening 41 or the second passage opening 42 enclosing edge 411 , 421 out. The first locking unit 7th comprises starting from the first hollow body opening 611 along the coat 63 first the first locking element 72 and then the first cantilever 71 on. In contrast, the second locking unit 8th starting from the second hollow body opening 621 along the coat 63 first the second cantilever 81 and then the second latching element 82 on. In the present embodiment, the two elastically deformable locking elements 72 , 82 designed as a flexible snap-in collar that holds the jacket 63 of the hollow body 6th completely encloses.

So that no coolant in the area of the locking units 7th , 8th from the volume 32 of the cooling element 3 can emerge include both projections 71 , 81 on one of the recordings 73 , 83 facing side each a sealing element designed as a sealing ring 9 , 10 that in one the coat 63 circumferential groove in this area 91 , 101 is used.

If there is thermal runaway in the energy storage cell, this leads to a pressure and temperature increase in the volume of this energy storage cell. In the present exemplary embodiment, the cell base has 2 this energy storage cell a fuse opening 21st on, with the fuse opening 21st the passage 4th assigned. More precisely, are the fuse opening 21st and the passage 4th and thus the interior of the hollow body is arranged in alignment with one another.

The fuse opening 21st is designed as a bursting membrane in the present embodiment. If the pressure and the temperature exceed a critical value, this safety opening bursts 21st and a focal beam emerges from the interior of the energy storage cell. This focal beam first passes through the second hollow body opening 621 , then passes through the interior of the hollow body 64 and leaves the hollow body via the first hollow body opening 611 .

Due to the high temperature of the focal beam, it occurs in the melting range 631 of the coat 63 melting of the plastic. This opens the coolant outlet opening 5 opened and the coolant emerges from the volume 32 via the coolant outlet opening 5 into the passage 4th out.

A melting of the plastic in the melting range 631 to facilitate, the coat points 63 in the melting range 631 a taper on. So that the pressurized coolant is directed towards the cell floor 2 can be conducted, has the first hollow body opening 611 one compared to the second hollow body opening 621 smaller inner diameter.

2 shows a second embodiment of the cooling system according to the invention 1 as a schematic sectional view. This embodiment differs from that in 1 shown first embodiment in that the cooling element 3 is designed as a hose cooler.

This cooling element designed as a hose cooler 3 is on a hose carrier 11 applied so that the hose carrier 11 the hose cooler 3 supports. The passage 4th extends in this embodiment through the hose cooler 3 and the hose carrier 11 . The hose cooler 3 also includes a wall 31 , the volume through which the coolant flows 32 limited. In this embodiment, the wall 31 and the closure element 12 in one piece made of elastomeric material, in the present case made of synthetic rubber. The closure element 12 is in this way in the area of the passage 4th arranged that it is on contact with the focal beam from the wall 31 detaches or melts and the coolant outlet opening 5 opens. The coolant outlet opening 5 is in this embodiment radially symmetrical around the circumference of the passage 4th distributed (in 2 not shown).

3 shows a third embodiment of the cooling system according to the invention 1 as a sectional view. This third embodiment differs from that in FIG 1 first embodiment shown and the in 2 second embodiment shown in that the cooling element 3 as a radiator plate made of two metal sheets 13 , 14th is made of aluminum, which in the area of their joint or their connection point 15th are firmly connected to one another by welding.

The first radiator plate 13 points in the area of the passage 4th a coolant outlet opening 5 on, with a closure element designed as a stopper 16 is locked. In the present embodiment, the plug 16 made of plastic. The stopper 16 has a first section 161 in the coolant outlet opening 5 is arranged, and a second section 162 on which the coolant outlet opening 5 Completely covered. The second section 162 of the plug 16 is on one of the volume 32 facing inside of the wall 31 arranged.

In the event of a thermal runaway of the energy storage cell and an associated exit of the focal beam from the opened safety opening 21st into the passage 4th is through this on the stopper 16 acting pressure of the plug 16 in the volume 32 of the cooling element 3 depressed.

4th shows a fourth embodiment of the cooling system according to the invention 1 as a sectional view. This fourth embodiment differs from that in FIG 3 third embodiment shown in that the second section 162 of the plug 16 on an outside of the wall facing the passage 31 the coolant outlet opening 5 completely covered. In the event of a thermal runaway of the energy storage cell and an associated exit of the focal beam from the opened safety opening 21st into the passage 4th is through this on the stopper 16 heat of the focal beam of the plug 16 melted and the coolant outlet opening 5 open.

5 shows an embodiment of an energy store according to the invention 17th . This energy store 17th includes a cooling system 1 according to the first embodiment, on which a plurality of energy storage cells 18th , 19th so arranged to one another so that a longitudinal axis of the energy storage cells 18th , 19th essentially perpendicular to a cooling surface of the cooling element designed as a cooler plate 3 stands (the present 4th shows only two of the energy storage cells).

Every energy storage cell 18th , 19th is made of a cell housing 181 , 191 enclosed, with the cell floor 2 part of this cell housing 181 , 191 is. In the error-free operation of the energy store, each energy storage cell 18th , 19th along the cooling surface from the cooling system 1 chilled. That means the cooling system 1 as standard cooling for the energy storage 17th serves.

To improve the cooling performance can be placed between the cell floor 2 and the cooling element 3 be introduced a thermal paste. This thermal paste should be the respective passages 4th in which the use 6th arranged, do not clog.

The energy storage cells 18th , 19th and the cooling system 1 are from an energy storage housing 22nd enclosed, which is a thermally conductive contact between the energy storage cells 18th , 19th and the cooling surface of the cooling system 1 ensures. The energy storage case 22nd is designed like a frame in the present embodiment. Every energy storage cell 18th , 19th has a safety opening 21st in the area of your cell floor 2 on. For the interaction of the energy storage 17th and the cooling system 1 during thermal runaway of the energy storage cell 18th , 19th it is essential in the present embodiment that the securing opening 21st every energy storage cell 18th , 19th and the respective passage 4th are arranged in alignment with one another. Thus, the cooling system 1 the energy storage 17th or the energy storage cells contained in it 18th , 19th both in the error-free operation of the energy storage 17th as well as optimally cool during emergency cooling of one or more energy storage cells during the thermal runaway.

In the present exemplary embodiment, the energy storage cells are 18th , 19th designed as rechargeable lithium-ion battery cells. It is therefore the energy store 17th a rechargeable lithium-ion battery.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 202007011578 U1 [0009]
• WO 2011054582 A1 [0010]

Claims (15)

Cooling system (1) for an energy store, comprising at least one cooling element (3), which has a wall (31) and a volume (32) delimited by the wall (31) and through which a coolant can flow, wherein the cooling element (3) has at least a passage (4) is introduced, which is at least partially separated from the volume (32) by the wall (31), the passage (4) being assigned an emergency opening device which opens when exposed to heat and / or pressure and thereby establishes a flow-conducting connection between the volume (32) and the passage (4). Cooling system after Claim 1 , characterized in that the emergency opening device comprises a coolant outlet opening (5) introduced in the region of the passage (4) and a closure element (6, 12, 16) closing the coolant outlet opening (5). Cooling system after Claim 2 , characterized in that the closure element is designed as a stopper (16). Cooling system according to one of the Claims 2 or 3 , characterized in that the plug (16) has a first section (161) which is arranged in the coolant outlet opening (5) and a second section (162) which covers the coolant outlet opening (5) at least in sections. Cooling system after Claim 4 , characterized in that the second section (162) covers the coolant outlet opening (5) on an outer side of the wall (32) facing the passage (4) at least in sections. Cooling system after Claim 4 , characterized in that the second section (162) covers the coolant outlet opening (5) on an inside of the wall (3) facing the volume (32) at least in sections. Cooling system after Claim 2 , characterized in that the closure element is designed as an insert (6) which in sections forms the wall (31) of the cooling element (3) and delimits the passage (4). Cooling system after Claim 7 , characterized in that the insert (6) is designed as a hollow body traversing the passage (4), which has a base surface (61) with a first hollow body opening (611), a top surface (62) with a second hollow body opening (621) and a the base surface (61) and the top surface (62) comprising jacket (63) connecting to one another, the base surface (61), the top surface (62) and the jacket (63) defining an inner region (64) of the hollow body (6) and wherein the hollow body openings (611, 621) essentially encircling latching units (7, 8) are formed from the shell (63), the latching units (7, 8) being formed on an outer side of the shell facing away from the inner region (64) and wherein between the latching units ( 7, 8) at least one melting area (631) essentially covering the coolant outlet opening (5) is arranged. Cooling system after Claim 8 , characterized in that the locking unit (7, 8) has a projection (71, 81) which protrudes essentially perpendicular to the outside of the jacket and encircles the jacket (63) and at least one elastically deformable locking element (72, 82), the projection (71 , 81) and the latching element (72, 82) form a receptacle (73, 83) for an edge (411, 421) which encloses either a first passage opening (41) or a second passage opening (42) of the passage (4). Cooling system after Claim 9 , characterized in that the projection (71, 81) is assigned a sealing element (9, 10) on a side facing the receptacle (73, 83). Cooling system according to one of the Claims 8 to 10 , characterized in that the first hollow body opening (611) has a smaller clear dimension compared to the second hollow body opening (621). Cooling system according to one of the Claims 2 to 11 , characterized in that the closure element (6, 12, 16) is made of plastic. Cooling system according to one of the Claims 1 to 12 , characterized in that the wall (31) of the cooling element (3) is made of metal or plastic. Cooling system according to one of the Claims 2 to 13 , characterized in that the closure element (12) and the wall (31) of the cooling element (3) are formed in one piece, the closure element (12) for producing the flow-conducting connection between the volume (32) and the passage (4) by action can be detached from the wall (31) by heat and / or pressure. Energy storage device (17), comprising a plurality of energy storage cells (18, 19) each having a cell housing (181, 191) and at least one securing opening (21) assigned to the cell housing (181, 191) and at least one cooling system (1) after at least one of the preceding claims, wherein the fuse opening (21) each one Passage (4) of a cooling element (3) of the cooling system (1) is assigned.

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