DE102021210030A1 - Battery module with a plurality of battery cells and use of such - Google Patents

Abstract

The invention relates to a battery module with a plurality of battery cells (2) which are electrically conductively connected to one another in series and/or in parallel and which are accommodated in a housing (3) of the battery module (1), the housing (3) containing a plurality of of battery cell receptacles (30), in each of which one battery cell (2) of the plurality of battery cells (2) is accommodated, wherein the housing (3) has a flow space (4) between two battery cell receptacles (30) arranged adjacent to one another, and wherein the battery module (1) further has a first cover element (51) and a second cover element (52), which are arranged opposite one another on the housing (3) in such a way that in each case between the housing (3) and the respective cover element (51, 52) a further flow space (40) is formed, each of which is fluidly connected to the battery cell receptacle (30), the first cover element (51) and the second cover element ment (52) each have an opening (6), which are each formed for an inflow and/or outflow of the temperature control fluid out of the battery module (1) or into the battery module (1).

Description

State of the art

The invention is based on a battery module with a plurality of battery cells according to the species of the independent claim. The subject of the present invention is also the use of such.

It is known from the prior art that a battery module has a plurality of individual battery cells, each of which has a positive voltage tap and a negative voltage tap, the respective voltage taps being electrically conductive for an electrically conductive serial and/or parallel connection of the plurality of battery cells to one another are connected to each other and can thus be interconnected to form the battery module. In particular, the battery cells can each have a first voltage tap, in particular a positive voltage tap, and a second voltage tap, in particular a negative voltage tap, which are electrically conductively connected to one another by means of cell connectors, so that an electrically serial and/or parallel connection is formed. Battery modules, for their part, are also connected together to form batteries or entire battery systems.

In particular, lithium-ion battery cells or Li-polymer battery cells heat up due to chemical conversion processes inside them, especially when energy is released or absorbed quickly in battery systems. The more powerful the battery system is, the more it heats up and, as a result, an efficient active thermal management system is necessary.

Disclosure of Invention

A battery module with a plurality of battery cells with the features of the independent claim offers the advantage that reliable and efficient temperature control, in particular cooling, can be implemented for the plurality of battery cells.

For this purpose, a battery module with a plurality of battery cells, which are designed in particular as lithium-ion battery cells, is made available. The battery cells are electrically conductively connected to one another in series and/or in parallel. Furthermore, the battery cells are accommodated in a housing of the battery module. In this case, the housing of the battery module has a plurality of battery cell receptacles, in each of which one battery cell of the plurality of battery cells is accommodated. In this case, the housing has a flow space between two battery cell receptacles arranged adjacent to one another. Furthermore, the battery module also includes a first cover element and a second cover element, which are arranged opposite one another on the housing of the battery module in such a way that a further flow space is formed between the housing and the respective cover element. The further flow chambers are each fluidly connected to the plurality of battery cell receptacles. Furthermore, the first cover element and the second cover element each have an opening, each of which is designed for the temperature control fluid to flow in and/or out of the battery module or into the battery module.

Advantageous developments and improvements of the device specified in the independent claim are possible as a result of the measures listed in the dependent claims.

It is expedient if the battery cells are in the form of prismatic battery cells or pouch cells. As a result, reliable accommodation and temperature control of a prismatic battery cell or a battery cell designed as a pouch cell can be made available.

At this point it should be noted that battery cells of prismatic design each comprise a battery cell housing with a total of six side surfaces which are arranged in pairs opposite one another and essentially parallel to one another. Furthermore, side surfaces arranged adjacent to one another are arranged at right angles to one another. The electrochemical components of the respective battery cell are accommodated in an interior of the battery cell housing. Two voltage taps, such as in particular a positive voltage tap and a negative voltage tap, are usually arranged on an upper side surface referred to as the cover surface. The lower side surface arranged opposite the upper side surface is referred to as the bottom surface.

It should also be noted at this point that in the case of so-called pouch cells, a film encloses an interior in which the electrochemical components of the respective battery cell are accommodated. Two voltage taps, in particular a positive voltage tap and a negative voltage tap, are routed through this film from the inside.

It is advantageous if the battery cells arranged adjacent to one another between two Oil recordings arranged flow spaces and formed between the housing and the respective cover element further flow spaces are arranged substantially at right angles to each other. This offers the advantage that a compact embodiment of the battery module can be made available.

According to a preferred aspect of the invention, the housing of the battery module is made of a metallic material, in particular aluminum, and/or the first cover element and the second cover element are made of a polymer material. At this point it should be noted that the housing of the battery module can be designed in particular as an extruded profile, preferably made of aluminum. Overall, a battery module of comparably light design can be made available here. In particular, a die-cast aluminum housing can be adapted to different dimensions and/or tolerances of a battery cell by machining or differently designed tools.

According to a further preferred aspect of the invention, the flow spaces arranged between two battery cell receptacles arranged adjacent to one another also have support elements. This makes it possible to increase the stability of the battery module and in particular of the battery cell receptacles.

It is also preferred if the housing of the battery module also has additional flow spaces on the outside. This makes it possible to fully temperature control the majority of battery cells. Thus, for example, the entire side surfaces, e.g. the entire casing and base surface of the respective battery cell, can be temperature-controlled, in particular except for a cover surface having the voltage taps.

The first cover element expediently has recesses which are sealed off from the further flow space and in which cell connectors are accommodated. As a result, an electrically conductive serial and/or parallel interconnection of the plurality of battery cells can be formed in a simple manner.

The first cover element is preferably designed in two parts. Thereby, it is possible to design reliable sealing.

The subject matter of the present invention is also the use of a battery module just described in an electrically driven vehicle.

Overall, with an embodiment of the battery module according to the invention, central, uniform and, for example, parallel cooling of a plurality of interconnected battery modules can be implemented at the level of the battery pack.

Furthermore, a compact design, particularly in terms of height, can be formed, in which, for example, cooling pipes and hoses known from the prior art can be omitted.

Furthermore, a mechanically robust structure of the battery module can be designed overall for greater safety in the event of an accident and/or also against so-called swelling of the battery cell. As a result, for example, a frame made of aluminum can be used at the battery pack level, in particular instead of a frame made of steel, which can save weight at the battery module and battery pack level, for example.

character list

Embodiments of the invention are shown in the drawings and explained in more detail in the following description.

• 1a eine erste Ausführungsform eines erfindungsgemäßen Batteriemoduls in einer perspektivischen Ansicht,
• 1b eine zweite Ausführungsform eines erfindungsgemäßen Batteriemoduls in einer perspektivischen Ansicht,
• 1c eine dritte Ausführungsform eines erfindungsgemäßen Batteriemoduls in einer perspektivischen Ansicht,
• 1d eine vierte Ausführungsform eines erfindungsgemäßen Batteriemoduls in einer perspektivischen Ansicht,
• 2a eine Ausführungsform eines Gehäuses eines ersten erfindungsgemäßen Batteriemoduls,
• 2b eine Ausführungsform eines Gehäuses eines zweiten erfindungsgemäßen Batteriemoduls,
• 2c eine Ausführungsform eines Gehäuses eines dritten erfindungsgemäßen Batteriemoduls,
• 3a eine Durchströmung eines erfindungsgemäßen Batteriemoduls,
• 3b eine andere Durchströmung eines erfindungsgemäßen Batteriemoduls und
• 4a eine Aufnahme einer pouch-Zelle in einem Gehäuse.

It shows

• 1a a first embodiment of a battery module according to the invention in a perspective view,
• 1b a second embodiment of a battery module according to the invention in a perspective view,
• 1c a third embodiment of a battery module according to the invention in a perspective view,
• 1d a fourth embodiment of a battery module according to the invention in a perspective view,
• 2a an embodiment of a housing of a first battery module according to the invention,
• 2 B an embodiment of a housing of a second battery module according to the invention,
• 2c an embodiment of a housing of a third battery module according to the invention,
• 3a a flow through a battery module according to the invention,
• 3b another flow through a battery module according to the invention and
• 4a a recording of a pouch cell in a housing.

The 1a shows a first embodiment of a battery module 1 in a perspective view, initially in an exploded view. Furthermore, the battery module 1 is also shown in the assembled state.

In this case, the battery module 1 has a plurality of battery cells 2 which are designed in particular as lithium-ion battery cells 20 . The battery cells 2 are electrically conductively connected to one another in series and/or in parallel.

At the in 1a illustrated embodiment, the battery cells 2 are designed as prismatic battery cells 21.

The battery cells 2 are accommodated in a housing 3 of the battery module 1 . The housing 3 has a plurality of battery cell receptacles 30 in each of which one battery cell 2 of the plurality of battery cells 2 is accommodated.

The housing 3 has a flow chamber 4 between two battery cell receptacles 30 arranged adjacent to one another.

Furthermore, the battery module 1 has a first cover element 51 and a second cover element 52 . The first cover element 51 and the second cover element 52 are arranged opposite one another on the housing 3 in such a way that a further flow chamber 40 is formed between the housing 3 and the respective cover element 51 , 52 . The further flow chambers 40 are connected to the battery cell receptacles 30 in a fluid-conducting manner.

The first cover element 51 and the second cover element 52 each have an opening 6 . The openings 6 are each designed for the temperature control fluid to flow in and/or out of the battery module 1 or into the battery module 1 .

From the 1a It can also be seen that the first cover element 51 has recesses 7 which are sealed off from the further flow space 40 and in which cell connectors 8 are accommodated. The battery module 1 can in particular have a sealing element 9 for such a seal.

The housing 3 of the battery module 1 is made from a metallic material, in particular aluminum, and the first cover element 51 and the second cover element 52 are made from a polymer material.

The 1b shows a second embodiment of a battery module 1 in a perspective view, initially in an exploded view. Furthermore, the battery module 1 is also shown in the assembled state.

In this case, the battery module 1 has a plurality of battery cells 2 which are designed in particular as lithium-ion battery cells 20 . The battery cells 2 are electrically conductively connected to one another in series and/or in parallel.

At the in 1b illustrated embodiment, the battery cells 2 are designed as pouch cells 22.

The battery cells 2 are accommodated in a housing 3 of the battery module 1 . The housing 3 has a plurality of battery cell receptacles 30 in each of which one battery cell 2 of the plurality of battery cells 2 is accommodated.

The housing 3 has a flow chamber 4 between two battery cell receptacles 30 arranged adjacent to one another.

Furthermore, the battery module 1 has a first cover element 51 and a second cover element 52 . The first cover element 51 and the second cover element 52 are arranged opposite one another on the housing 3 in such a way that a further flow chamber 40 is formed between the housing 3 and the respective cover element 51 , 52 . The further flow chambers 40 are connected to the battery cell receptacles 30 in a fluid-conducting manner.

The first cover element 51 and the second cover element 52 each have an opening 6 . The openings 6 are each designed for the temperature control fluid to flow in and/or out of the battery module 1 or into the battery module 1 .

From the 1b It can also be seen that the first cover element 51 has recesses 7 which are sealed off from the further flow space 40 and in which cell connectors 8 are accommodated. The battery module 1 can in particular have a sealing element 9 for such a seal.

The housing 3 of the battery module 1 is made of a metallic material, in particular aluminum, and the first Cover element 51 and the second cover element 52 are formed from a polymeric material.

The 1c shows a third embodiment of a battery module 1 in a perspective view in an exploded view.

In this case, the battery module 1 has a plurality of battery cells 2 which are designed in particular as lithium-ion battery cells 20 . The battery cells 2 are electrically conductively connected to one another in series and/or in parallel.

At the in 1c illustrated embodiment, the battery cells 2 are designed as pouch cells 22.

The battery cells 2 are accommodated in a housing 3 of the battery module 1 . The housing 3 has a plurality

Battery cell shots 30, in each of which a battery cell 2 of the plurality of battery cells 2 is added.

The housing 3 has a flow chamber 4 between two battery cell receptacles 30 arranged adjacent to one another.

Furthermore, the battery module 1 has a first cover element 51 and a second cover element 52 . The first cover element 51 and the second cover element 52 are arranged opposite one another on the housing 3 in such a way that a further flow chamber 40 is formed between the housing 3 and the respective cover element 51 , 52 . The further flow chambers 40 are connected to the battery cell receptacles 30 in a fluid-conducting manner.

The first cover element 51 and the second cover element 52 each have an opening 6 . The openings 6 are each designed for the temperature control fluid to flow in and/or out of the battery module 1 or into the battery module 1 .

From the 1c it can be seen here that the battery module 1 also has cell connectors 8, which serve to electrically conductively connect the plurality of battery cells 2 to one another in series and/or in parallel. Furthermore, the battery module 1 has further cover elements 53 which cover the cell connectors 8 from the environment.

The housing 3 of the battery module 1 is made from a metallic material, in particular aluminum, and the first cover element 51 and the second cover element 52 are made from a polymer material.

1d shows a fourth embodiment of a battery module 1 according to the invention in a perspective view.

Here, in contrast to the embodiment according to 1c the first cover element 51 and the second cover element 52 are dispensed with.

As a result, several battery modules 1 can be connected to one another, for example, screwed together via a crash frame.

The 2a shows an embodiment of a housing 3 of a first battery module 1 according to the invention. The housing 3 is shown in a perspective view and in a plan view.

It can be seen here that the housing 3 has a plurality of battery cell receptacles 30 and that a flow chamber 4 is formed between two battery cell receptacles 30 arranged adjacent to one another.

Furthermore, from the 2a It can be seen that the flow spaces 4 arranged between two battery cell receptacles 30 arranged adjacent to one another can also have support elements 41 .

Furthermore, it can be seen in particular from the plan view that the housing 3 of the battery module 1 has additional flow chambers 42 on the outer sides 10 .

The 2 B shows an embodiment of a housing 3 of a second battery module 1 according to the invention. The housing 3 is shown in a perspective view and in a plan view.

It can be seen here that the housing 3 has a plurality of battery cell receptacles 30 and that a flow chamber 4 is formed between two battery cell receptacles 30 arranged adjacent to one another.

Furthermore, from the 2 B It can be seen that the flow spaces 4 arranged between two battery cell receptacles 30 arranged adjacent to one another can also have support elements 41 .

Furthermore, it can be seen in particular from the top view that the housing 3 of the Battery module 1 has additional flow spaces 42 on outer sides 10 .

The 2c shows an embodiment of a housing 3 of a third battery module 1 according to the invention. The housing 3 is shown in a perspective view, in a top view and in a side view.

It can be seen here that the housing 3 has a plurality of battery cell receptacles 30 and that a flow chamber 4 is formed between two battery cell receptacles 30 arranged adjacent to one another.

Furthermore, from the 2c It can be seen that the flow spaces 4 arranged between two battery cell receptacles 30 arranged adjacent to one another can also have support elements 41 .

3a 1 shows a flow through a battery module 1 according to the invention, in particular according to the first and second embodiment of the battery module according to the invention, in a top view, a side view and a front view.

The plurality of flow spaces 4 and the further flow spaces 40 formed between the first cover element 51 or the second cover element 52 and the housing 3 can be seen.

The 3a shows that the flow chambers 4 arranged between two battery cell receptacles 30 arranged adjacent to one another and the further flow chambers 40 formed between the housing 3 and the respective cover element 51, 52 are arranged essentially at right angles to one another.

Furthermore, the additional flow spaces 42 arranged on the outer sides 10 can be seen.

From the 3a it can be seen here that temperature control fluid can flow into the further flow space 40 between the first cover element 51 and the housing 3 via the opening 6 of the first cover element 51 and can be distributed evenly to all flow spaces 4 and additional flow spaces 42 via this further flow space 40. The tempering fluid then flows into the further flow space 40 between the second cover element 51 and the housing element 3 and out of the battery module 1 via the opening 6 of the second cover element 52 .

3b shows a further flow through a battery module 1 according to the invention, in particular according to the third embodiment of the battery module 1 according to the invention, in a side view and a front view.

The plurality of flow spaces 4 and the further flow spaces 40 formed between the first cover element 51 or the second cover element 52 and the housing 3 can be seen.

The 3b shows that the flow chambers 4 arranged between two battery cell receptacles 30 arranged adjacent to one another and the further flow chambers 40 formed between the housing 3 and the respective cover element 51, 52 are arranged essentially at right angles to one another.

Furthermore, the additional flow spaces 42 arranged on the outer sides 10 can be seen.

From the 3b it can be seen here that temperature control fluid can flow into the further flow space 40 between the first cover element 51 and the housing 3 via the opening 6 of the first cover element 51 and can be distributed evenly to all flow spaces 4 and additional flow spaces 42 via this further flow space 40. The tempering fluid then flows into the further flow space 40 between the second cover element 51 and the housing element 3 and out of the battery module 1 via the opening 6 of the second cover element 52 .

4a shows a photograph of a battery cell 2 designed as a pouch cell 22.

The housing 30 here comprises a groove 81 in which a connecting lug 82 of the pouch cell 22, which is for example welded, is accommodated.

According to the illustration on the left, the groove 81 is arranged symmetrically in a middle position of the housing 30 . According to the illustration on the right, the groove 81 is arranged asymmetrically. The groove 81 can therefore be adapted to a respective embodiment of a pouch cell 22, e.g. to the geometry and position of the connecting strap 82.

Furthermore, the pouch cells can be equipped with damping and/or tolerance compensation elements (e.g. elastomer, compression spring or tolerance compensation element) on the side of the busbars. be pressed together at the sides in order to fasten them.

Claims (9)

Battery module with a plurality of battery cells (2), in particular lithium-ion battery cells (20), which are electrically conductively connected to one another in series and/or in parallel, and which are accommodated in a housing (3) of the battery module (1), the housing (3) having a plurality of battery cell receptacles (30), in each of which a battery cell (2) of the plurality of battery cells (2) is accommodated, wherein the housing (3) has a flow space (4) between two battery cell receptacles (30) arranged adjacent to one another, and wherein the battery module (1) further has a first cover element (51) and a second cover element (52), which are arranged opposite one another on the housing (3) in such a way that a further flow chamber (40) is formed between the housing (3) and the respective cover element (51, 52), which are each fluidly connected to the battery cell receptacles (30). , wherein the first cover element (51) and the second cover element (52) each have an opening (6) which allows the temperature control fluid to flow in and/or out of the battery module (1) or into the battery module (1). are trained. Battery module according to the preceding claim, characterized in that the battery cells (2) are designed as prismatic battery cells (21) or as pouch cells (22). Battery module according to one of the preceding claims, characterized in that the flow spaces (4) arranged between two battery cell receptacles (30) arranged adjacent to one another and the further flow spaces (40) formed between the housing (3) and the respective cover element (51, 52) in Are arranged essentially at right angles to each other. Battery module according to one of the preceding claims, characterized in that the housing (3) of the battery module (1) is made of a metallic material, in particular aluminum, and / or the first cover element (51) and the second cover element (52) from a polymeric material are formed. Battery module according to one of the preceding claims, characterized in that the flow spaces (4) arranged between two battery cell receptacles (30) arranged adjacent to one another also have supporting elements (41). Battery module according to one of the preceding claims, characterized in that the housing (3) of the battery module (1) also has additional flow spaces (42) on the outside (10). Battery module according to one of the preceding claims, characterized in that the first cover element (51) has recesses (7) which are sealed off from the further flow space (40) and in which cell connectors (8) are accommodated. Battery module according to the preceding claim, characterized in that the first cover element (51) is designed in two parts. Use of a battery module (1) according to one of the preceding claims in an electrically driven vehicle.

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