DE102018220558A1 - Battery cell and battery module - Google Patents

Abstract

The invention relates to a battery cell (2) comprising an electrode unit with an anode connected to a negative terminal (11) and with a cathode connected to a positive terminal (12), and a cell housing (3) in which the electrode unit is arranged, and which is prismatic. The cell housing (3) is designed in the form of a U-profile and has a base leg and a first side leg and a second side leg, and a free space is formed between the first side leg and the second side leg, which is delimited by the base leg. The invention also relates to a battery module (5) comprising a plurality of battery cells (2) according to the invention, the battery cells (2) being arranged in such a way that at least one side leg of a battery cell (2) projects into the free space of another battery cell (2) .

Description

The invention relates to a battery cell which comprises an electrode unit with an anode connected to a negative terminal and with a cathode connected to a positive terminal, and which comprises a cell housing in which the electrode unit is arranged and which is prismatic. The invention also relates to a battery module which comprises a plurality of battery cells according to the invention.

State of the art

It is becoming apparent that electric vehicles will increasingly be used in the future. Rechargeable batteries are used in such electric vehicles, primarily to supply electrical drive devices with electrical energy. Lithium battery cells are particularly suitable for such applications. Lithium battery cells are characterized, among other things, by high energy densities, thermal stability and extremely low self-discharge. Several lithium battery cells of this type are electrically connected to one another in series and in parallel and connected to form battery modules. A battery system of the electric vehicle comprises a plurality of battery modules designed in this way and interconnected with one another.

Lithium-ion battery cells, for example, have a liquid electrolyte. Lithium battery cells of new technologies have solid electrolytes and have relatively high energy densities. The chemical components of such lithium battery cells are highly active, but can only be operated optimally within a certain temperature range, for example above 80 ° C. and below 90 ° C. Battery systems with such lithium battery cells are also referred to as medium-temperature batteries (Mid-T batteries) and have a relatively high internal electrical resistance outside the temperature range mentioned. Therefore, medium temperature batteries cannot be operated optimally outside of this temperature range.

A battery system of an electric vehicle thus comprises several battery modules, which in turn are composed of several battery cells. The battery cells have a cell housing in which an electrode unit is arranged. The battery modules have a module frame which surrounds the battery cells. In addition to greater crash safety, the module frame also offers protection against accidental contact with live parts of the battery modules.

From the document DE 10 2016 213 221 A1 a generic battery cell is known. The battery cell has a cell housing which is prismatic, in particular cuboid. The electrode unit is arranged in the cell housing.

Disclosure of the invention

A battery cell is proposed which comprises an electrode unit with an anode electrically connected to a negative terminal and with a cathode electrically connected to a positive terminal. The battery cell also comprises a cell housing in which the electrode unit is arranged and which is prismatic.

The battery cell is designed, for example, as a medium-temperature battery cell with a solid electrolyte. The battery cell thus advantageously has a high energy density. It is also conceivable that the battery cell is designed as a lithium-ion battery cell with a liquid electrolyte. The battery cell can then be operated optimally in a relatively wide temperature range, for example in a temperature range between 5 ° C. and 40 ° C.

According to the invention, the cell housing is designed in the form of a U-profile and has a base leg and a first side leg and a second side leg. The two side legs preferably run parallel, spaced apart from one another and at right angles to the base leg. The base leg connects the two side legs.

In this case, a free space is formed between the first side leg and the second side leg, which is delimited by the base leg. The free space preferably has an at least approximately rectangular cross section and is delimited on three sides by the base leg and by the two side legs. The free space is open on a fourth side, which lies opposite the base leg.

According to an advantageous embodiment of the invention, the cell housing has a top surface and a bottom surface opposite the top surface. The negative terminal and the positive terminal are arranged on the top surface. The negative terminal and the positive terminal are thus arranged on the same surface of the cell housing.

The top surface and the bottom surface are at least approximately congruent and run parallel to one another. The top surface and the bottom surface are spaced apart in a vertical direction. The first side leg and the second side legs are spaced apart in a longitudinal direction which is perpendicular to the vertical direction. A transverse direction is perpendicular to the vertical direction and perpendicular to the longitudinal direction. The top surface and the bottom surface are thus oriented at right angles to the vertical direction.

According to an advantageous development of the invention, the negative terminal is arranged on the first side leg, and the positive terminal is arranged on the second side leg. This means that the space is also between the two terminals.

According to an advantageous embodiment of the invention, a width of the free space between the first side leg and the second side leg is at least as large as a sum of a width of the first side leg and a width of the second side leg.

The width of the free space is an expansion of the free space in the longitudinal direction. The width of the free space thus corresponds to a distance in the longitudinal direction between the first side leg and the second side leg. The width of the first side leg is an extension of the first side leg in the longitudinal direction, and the width of the second side leg is an extension of the second side leg in the longitudinal direction.

The width of the free space between the first side leg and the second side leg is preferably at most twice as large as a sum of a width of the first side leg and a width of the second side leg.

According to a preferred embodiment of the invention, the electrode unit is designed as an electrode stack and has a plurality of anode layers and cathode layers stacked one on top of the other. The anode layers and cathode layers are oriented parallel to the top surface. The anode layers and cathode layers are thus also oriented at right angles to the vertical direction.

A separator layer is arranged in the electrode stack between the anode layers and the cathode layers. The anode layers together form the anode of the electrode unit. The cathode layers together form the cathode of the electrode unit. The separator layers together form a separator of the electrode unit, which separates the anode from the cathode.

However, it is also conceivable that the electrode unit is designed as an electrode coil. In this case, the anode and the cathode are designed in the form of a film and, with the interposition of a separator, which is also in the form of a film, are wound into the electrode winding. Such an electrode coil is also called a jelly roll.

A battery module is also proposed which comprises a plurality of battery cells according to the invention. According to the invention, the battery cells are arranged such that at least one side leg of a battery cell projects into the space between the side legs of another battery cell.

According to a preferred embodiment of the invention, a first row of battery cells and a second row of battery cells are provided. The battery cells of the first row and the battery cells of the second row are arranged such that side legs of battery cells of the first row protrude into free spaces of battery cells of the second row. The battery cells of the first row and the battery cells of the second row are also arranged in such a way that side legs of battery cells of the second row protrude into free spaces of battery cells of the first row.

According to a preferred development of the invention, a terminal of battery cells of the first row is electrically connected to a terminal of a battery cell of the second row by means of a cell connector. In particular, a negative terminal of a battery cell of the first row is electrically connected to a positive terminal of a battery cell of the second row, and vice versa. This creates a series connection of the battery cells in the battery module.

According to a preferred embodiment of the invention, a module frame is provided, in which the battery cells are arranged. A cooling device for cooling the battery cells and a heating device for heating the battery cells are arranged in the module frame. The cooling device is designed, for example, in the form of a coolant circuit, and the heating device is designed, for example, in the form of a heating circuit.

A battery cell according to the invention and a battery module according to the invention are advantageously used in an electric vehicle. However, other uses are also conceivable, for example in other motor vehicles such as hybrid vehicles, plug-in hybrid vehicles and in stationary systems.

Advantages of the invention

By means of the battery cells according to the invention, battery modules according to the invention can be constructed which have high mechanical stability. Such battery modules also have a compact structure. The interlocking of the cells means that only a light module frame is required. This advantageously reduces the weight, installation space and cost of such a battery module. In particular, battery modules of this type are suitable for automotive use, that is to say they are suitable for use in an electric vehicle. The assembly of battery cells in a battery module is relatively easy to carry out and is protected against polarity reversal.
Due to the geometrical arrangement of the battery cells and in particular the terminals, only short cell connectors are required to connect the battery cells. As a result, there are only minor electrical losses during operation of the battery module. If the electrode units are designed as an electrode stack, the electrode units expand essentially in the vertical direction and thus parallel to the adjacent battery cells. As a result, the setting of the correct pressing force when mounting the battery cells in the battery module is less problematic. The connection of a cooling device and a heating device is relatively simple as a circular structure or ring structure. The battery module is modularly expandable, since connections of the cooling device and the heating device are arranged in the module frame. This also completely fills the installation space within the module frame.

Figure list

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

• 1 eine schematische perspektivische Darstellung einer Batteriezelle,
• 2 eine Draufsicht auf die Batteriezelle aus 1,
• 3 eine schematische Darstellung eines Batteriemoduls gemäß einer ersten Ausführungsform und
• 4 eine schematische Darstellung eines Batteriemoduls gemäß einer zweiten Ausführungsform.

Show it:

• 1 1 shows a schematic perspective illustration of a battery cell,
• 2nd a plan view of the battery cell 1 ,
• 3rd a schematic representation of a battery module according to a first embodiment and
• 4th is a schematic representation of a battery module according to a second embodiment.

Embodiments of the invention

In the following description of the embodiments of the invention, the same or similar elements are denoted by the same reference symbols, with a repeated description of these elements being dispensed with in individual cases. The figures represent the subject matter of the invention only schematically.

1 shows a schematic perspective view of a battery cell 2nd . The battery cell 2nd comprises a cell housing 3rd , which is prismatic, in particular in the form of a U-shaped profile. The cell housing 3rd can be made electrically conductive and made, for example, of aluminum. The cell housing 3rd but can also be made of an electrically insulating material, for example plastic.

The battery cell 2nd includes a negative terminal 11 and a positive terminal 12 . Via the terminals 11 , 12 can one from the battery cell 2nd provided voltage can be tapped. Furthermore, the battery cell 2nd through the terminals 11 , 12 also be loaded. The terminals 11 , 12 are spaced apart from each other on a top surface 37 of the prismatic cell housing 3rd arranged. The cell housing 3rd the battery cell 2nd also has a bottom surface which is the top surface 37 lies opposite and is hidden in the illustration shown here.

The top surface 37 and the bottom surface are congruent and run parallel to each other. The top surface 37 and the bottom surface are spaced apart in a vertical direction z. A longitudinal direction x is perpendicular to the vertical direction z. A transverse direction is perpendicular to the vertical direction z and perpendicular to the longitudinal direction x.

Inside the cell housing 3rd the battery cell 2nd an electrode unit is arranged which has two electrodes, namely an anode and a cathode. The anode is with the negative terminal 11 electrically connected, and the cathode is with the positive terminal 12 electrically connected.

In the present case, the electrode unit is designed as an electrode stack and has a plurality of anode layers and cathode layers stacked one on top of the other. A separator layer is arranged between the anode layers and the cathode layers. The anode layers together form the anode of the electrode unit. The cathode layers together form the cathode of the electrode unit. The separator layers together form a separator of the electrode unit, which separates the anode from the cathode. The anode layers, the cathode layers and the separator layers are parallel to the top surface 37 of the cell housing 3rd and thus also oriented at right angles to the vertical direction z.

The cell housing 3rd is, as already mentioned, in the form of a U-profile and has a base leg 33 as well as a first side leg 31 and a second side leg 32 on. The two side legs 31 , 32 run parallel to each other and at right angles to the base leg 33 . The base leg 33 connects the two side legs 31 , 32 . The first side leg 31 and the second side leg 32 are spaced apart in the longitudinal direction x.

Between the first side leg 31 and the second side leg 32 is a space 35 formed by the base leg 33 is limited. The freedom 35 has a rectangular cross section and is from the base leg 33 as well as from the two side legs 31 , 32 limited on three sides. On a fourth side, which is the base leg 33 opposite is the free space 35 open.

The negative terminal 11 is on the first side leg 31 arranged, and the positive terminal 12 is on the second side leg 32 arranged. The freedom 35 is therefore also between the negative terminal 11 and the positive terminal 12 .

2nd shows a plan view of the battery cell 2nd out 1 . The first side leg 31 and the second side leg 32 of the cell housing 3rd are, as already mentioned, arranged spaced apart in the longitudinal direction x. A distance between the first side leg 31 and the second side leg 32 in the longitudinal direction x corresponds to a width A of the free space 35 .

The width A of the free space 35 is an expansion of the free space 35 in the longitudinal direction x. A width B of the first side leg 31 is an expansion of the first side leg 31 in the longitudinal direction x. A width C of the second side leg 32 is an extension of the second side leg 32 in the longitudinal direction x.

The width A of the free space 35 between the first side leg 31 and the second side leg 32 is slightly larger than, but not twice as large as, a sum of the width B of the first side leg 31 and the width C of the second side leg 32 . This geometrical configuration of the cell housing 3rd allowed a first side leg each 31 and a second side leg 32 from other battery cells 2nd in the free space 35 can protrude into it and the free space 35 fill in almost completely.

3rd shows a schematic representation of a battery module 5 according to a first embodiment. The battery module 5 shows a first row 21st of battery cells 2nd and a second row 22 of battery cells 2nd on. The battery module 5 also has a module frame 27 on in which the battery cells 2nd are arranged.

The battery cells 2nd the front row 21st are arranged such that a first side leg 31 a battery cell 2nd the second row 22 and a second side leg 32 another battery cell 2nd the second row 22 in the free space 35 the battery cell 2nd the front row 21st protrude into it. The battery cells are an exception 2nd the front row 21st that are in the front row 21st are each arranged outside. In the open spaces 35 the battery cells on the outside 2nd the front row 21st only a first side leg protrudes 31 a battery cell 2nd the second row 22 or a second side leg 32 a battery cell 2nd the second row 22 .

The battery cells 2nd the second row 22 are arranged such that a first side leg 31 a battery cell 2nd the front row 21st and a second side leg 32 another battery cell 2nd the front row 21st in the free space 35 the battery cell 2nd the second row 22 protrude into it.

One negative terminal each 11 a battery cell 2nd the front row 21st is with a positive terminal 12 a battery cell 2nd the second row 22 using a cell connector 25th electrically connected. One positive terminal each 12 a battery cell 2nd the front row 21st is with a negative terminal 11 a battery cell 2nd the second row 22 using a cell connector 25th electrically connected. The cell connectors 25th are shown here transparently.

The battery cells are an exception 2nd the front row 21st that are in the front row 21st are each arranged outside. The positive terminal 12 the one outside battery cell 2nd is with a positive pole of the battery module, not shown here 5 electrically connected. The negative terminal 11 the other battery cell on the outside 2nd is with a negative pole of the battery module, not shown here 5 electrically connected. This creates in the battery module 5 a series connection of the battery cells 2nd .

As shown in 3rd can be removed are in the battery module 5 according to the first embodiment, the battery cells 2nd the second row 22 mirror image of the battery cells 2nd the front row 21st educated.

The battery module 5 also includes a cooling device 50 for cooling the battery cells 2nd and a heater 40 for heating the Battery cells 2nd . The cooling device 50 and the heater 40 are in the module frame 27 arranged. Here is the cooling device 50 designed in the form of a liquid circuit and has a cooling inlet valve 52 on. The heater 40 is designed in the form of a liquid circuit and has a heating inlet valve 42 on. The fluid circuit of the heater 40 is largely in this representation of the liquid circuit of the cooling device 50 covered. The heater 40 can for example also be designed in the form of a heating circuit.

4th shows a schematic representation of a battery module 5 according to a second embodiment. The battery module 5 shows a first row 21st of battery cells 2nd and a second row 22 of battery cells 2nd on. The battery module 5 also has a module frame 27 on in which the battery cells 2nd are arranged.

The battery cells 2nd the front row 21st are arranged such that a first side leg 31 a battery cell 2nd the second row 22 and a second side leg 32 another battery cell 2nd the second row 22 in the free space 35 the battery cell 2nd the front row 21st protrude into it. The battery cells are an exception 2nd the front row 21st that are in the front row 21st are each arranged outside. In the open spaces 35 the battery cells on the outside 2nd the front row 21st only a first side leg protrudes 31 a battery cell 2nd the second row 22 or a second side leg 32 a battery cell 2nd the second row 22 .

The battery cells 2nd the second row 22 are arranged such that a first side leg 31 a battery cell 2nd the front row 21st and a second side leg 32 another battery cell 2nd the front row 21st in the free space 35 the battery cell 2nd the second row 22 protrude into it.

One negative terminal each 11 a battery cell 2nd the front row 21st is with a positive terminal 12 an adjacent battery cell 2nd the front row 21st using a cell connector 25th electrically connected. One negative terminal each 11 a battery cell 2nd the second row 22 is with a positive terminal 12 an adjacent battery cell 2nd the second row 22 using a cell connector 25th electrically connected. The cell connectors 25th are shown here transparently.

The battery cells are an exception 2nd the front row 21st and the second row 22 that in each row 21st , 22 are each arranged outside. The positive terminal 12 the one outside battery cell 2nd the front row 21st is with a positive pole of the battery module, not shown here 5 electrically connected. The negative terminal 11 the one outside battery cell 2nd the second row 22 is with a negative pole of the battery module, not shown here 5 electrically connected. The negative terminal 11 the other battery cell on the outside 2nd the front row 21st is with the positive terminal 12 the other battery cell on the outside 2nd the second row 22 electrically connected. This creates in the battery module 5 a series connection of the battery cells 2nd .

As shown in 4th can be removed are in the battery module 5 according to the first embodiment, the battery cells 2nd the second row 22 similar to the battery cells 2nd the front row 21st educated.

The battery module 5 also includes a cooling device 50 for cooling the battery cells 2nd and a heater 40 for heating the battery cells 2nd . The cooling device 50 and the heater 40 are in the module frame 27 arranged. Here is the cooling device 50 designed in the form of a liquid circuit and has a cooling inlet valve 52 on. The heater 40 is designed in the form of a liquid circuit and has a heating inlet valve 42 on. The fluid circuit of the heater 40 is largely in this representation of the liquid circuit of the cooling device 50 covered. The heater 40 can for example also be designed in the form of a heating circuit.

The invention is not restricted to the exemplary embodiments described here and the aspects emphasized therein. Rather, a large number of modifications are possible within the scope specified by the claims, which lie within the framework of professional action.

QUOTES INCLUDE IN THE DESCRIPTION

This list of documents listed by the applicant has been generated automatically and is only included 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 102016213221 A1 [0005]

Claims (11)

Battery cell (2) comprising an electrode unit with an anode connected to a negative terminal (11) and with a cathode connected to a positive terminal (12), and a cell housing (3) in which the electrode unit is arranged and which is prismatic characterized in that the cell housing (3) is designed in the form of a U-profile and has a base leg (33) and a first side leg (31) and a second side leg (32), and that between the first side leg (31) and the second side leg (32) is formed a free space (35) which is delimited by the base leg (33). Battery cell (2) after Claim 1 , characterized in that the cell housing (3) has a top surface (37) and a bottom surface opposite the top surface (37), and in that the negative terminal (11) and the positive terminal (12) are arranged on the top surface (37). Battery cell (2) after Claim 2 , characterized in that the negative terminal (11) is arranged on the first side leg (31) and that the positive terminal (12) is arranged on the second side leg (32). Battery cell (2) according to one of the preceding claims, characterized in that a width (A) of the free space (35) between the side legs (31, 32) is at least as large as a sum of a width (B) of the first side leg (31 ) and a width (C) of the second side leg (32). Battery cell (2) according to one of the preceding claims, characterized in that a width (A) of the free space (35) between the side legs (31, 32) is at most twice as large as a sum of a width (B) of the first side leg ( 31) and a width (C) of the second side leg (32). Battery cell (2) according to one of the Claims 4 to 5 , characterized in that the electrode unit is designed as an electrode stack and has a plurality of anode layers and cathode layers stacked one above the other, the anode layers and cathode layers being oriented parallel to the cover surface (37). Battery module (5) comprising a plurality of battery cells (2) according to one of the preceding claims, characterized in that the battery cells (2) are arranged in such a way that at least one side leg (31, 32) of a battery cell (2) into the free space ( 35) of another battery cell (2) protrudes into it. Battery module (5) after Claim 7 , characterized in that a first row (21) of battery cells (2) and a second row (22) of battery cells (2) are provided, with side legs (31, 32) of battery cells (2) of the first row (21) in Open spaces (35) of battery cells (2) of the second row (22) protrude into them. Battery module (5) after Claim 8 , characterized in that in each case one terminal (11, 12) of battery cells (2) of the first row (21) by means of a cell connector (25) each having a terminal (11, 12) of a battery cell (2) of the second row (22) connected is. Battery module (5) according to one of the Claims 7 to 9 , characterized in that a module frame (27) is provided, in which the battery cells (2) are arranged, and that a cooling device (50) for cooling the battery cells (2) and a heating device (40) for heating the battery cells (2) are arranged in the module frame (27). Use of a battery cell (2) according to one of the Claims 1 to 6 and / or a battery module (5) according to one of the Claims 7 to 10th in an electric vehicle.

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