DE102022209539A1 - Battery cell module - Google Patents

Abstract

The invention relates to a battery cell module (1) with a cell stack (4) made of battery cells (5) and a housing (2) through which coolant can flow. In addition, the battery cell module (1) has a conductor group (7) with a conductor (8) and a flexible contact element (10) for the respective cell stack (4). The contact element (10) has a temperature sensor (11) around which coolant can flow.

Description

The invention relates to a battery cell module for a motor vehicle with a cell stack consisting of several stacked battery cells according to the preamble of claim 1.

In a battery cell module, a critical temperature of, for example, 60 ° C should not be exceeded when charging and discharging the battery cells. If the battery cell module is actively cooled, the coolant should have a defined temperature and the temperature should be permanently monitored. The temperature is usually monitored via 1-2 measuring points at the system level. This means that the temperature in the battery cell module can be predicted directly using software models only.

The object of the invention is therefore to provide an improved or at least alternative embodiment for a battery cell module of the generic type, in which the disadvantages described are overcome.

This object is achieved according to the invention by the subject matter of independent claim 1. Advantageous embodiments are the subject of the dependent claims.

The present invention is based on the general idea of measuring the temperature of the coolant at the inlet and/or outlet of the battery cell module.

The battery cell module according to the invention is designed for a motor vehicle, in particular for a battery-operated motor vehicle. The battery cell module has at least one cell stack made up of several battery cells stacked together and a housing through which a coolant can flow. The respective cell stack is accommodated in the housing so that the coolant can flow directly around it. The battery cell module also has at least one conductor group for the respective cell stack with a conductor for detecting voltage on the battery cells and with a flexible contact element. In the respective conductor group, the contact element is electrically contacted to the outside and with the conductor and the conductor is electrically contacted with the battery cells of the respective cell stack. According to the invention, the contact element has a temperature sensor in at least one of the respective conductor groups around which the coolant can flow. The temperature sensor is designed to detect the temperature of the coolant that flows around the contact element.

The cooling liquid can flow directly through the housing and as a result the respective cell stack and the battery cells of the cell stack are directly acted upon by the cooling liquid. In other words, the cell stack and the battery cells of the cell stack are in direct contact with one another. This allows the cell stack and the battery cells of the cell stack to be cooled particularly effectively. The coolant can expediently be dielectric. The contact element of the respective conductor group is arranged in the housing so that the coolant can flow around or be acted upon directly, and the temperature of the coolant can be recorded directly in the housing of the battery cell module. This allows the cooling of the battery cell module to be controlled effectively and safely. In particular, the service life of the battery cells and the aging of the cell stack can be better predicted. The efficiency of a cooling management system with pumps, heat exchangers and other elements can also be improved.

Due to its flexibility, the contact element can bridge the distance between the conductor of the respective conductor group and other elements when making contact. The contact element of the respective conductor group is flexible and can be, for example, a flexible circuit board or an FPC (FPC: Flexible Printed Circuit) or a flexible flat cable or an FFC (FFC: Flexible Flat Cable). The contact element of the respective conductor group can be externally connectable to a control unit of a battery management system. The control device can be a CSC (CSC: Cell Supervision Circuit) or CMC (CMC: Cell Monitoring Circuit) or slave. Temperature data recorded by the temperature sensor can then be transmitted directly to the control unit of the battery management system.

The leader of the respective conductor group can be a flexible printed circuit board or an FPC (FPC: Flexible Printed Circuit) or a flexible cable or a flexible flat cable or an FFC (FFC: Flexible Flat Cable) or a printed circuit board or a PCB (PCB: Printed Circuit board) and be arranged in the housing so that the coolant can flow directly around or be acted upon. The conductor of the respective conductor group can in particular electrically conductively connect a current busbar that electrically connects the battery cells of the cell stack and the contact element. The temperature sensor can in particular be an NTC thermistor. The temperature sensor can in particular be a surface-mounted component. The temperature sensor can be attached directly to the contact element.

The respective conductor group can have at least one support structure for supporting the flexible contact element. The support structure can be attached below the contact element at least in the area of the temperature sensor and thereby spatially fix the temperature sensor. As a result, the temperature sensor can be spatially fixed in the housing and the accuracy of the temperature measurements can be improved. Alternatively, the contact element with the temperature sensor can be fixed - for example in a cohesive manner - on a surface of the battery cell module surrounding the contact element. In particular, the contact element can be glued to the surface of the battery cell module surrounding the contact element.

At least one inlet leading into the housing from the outside and at least one outlet leading out of the housing can be formed in the housing for the cooling liquid. The coolant can flow into the housing via the inlet and the coolant can flow out of the housing from the outlet. The respective inlet and the respective outlet can be fluidly connected to one another via several flow paths and the flow paths can lie directly adjacent to the respective cell stack within the housing. The flow paths can be limited or defined in particular by outer contours of the cell stack and the battery cells of the cell stack and by inner contours of the housing or a wall of the housing within the housing.

The respective conductor group can be arranged in the housing in such a way that the temperature sensor of the contact element is arranged adjacent to the inlet or the outlet of the housing. This allows the temperature of the coolant to be detected at the inlet or at the outlet. The battery cell module can also have two conductor groups and the contact elements of the two conductor groups can each have the temperature sensor. The conductor groups can then be arranged in the housing in such a way that the temperature sensor of the contact element of one conductor group is arranged adjacent to the inlet and the temperature sensor of the other contact element of the other conductor group is arranged adjacent to the outlet of the housing. This allows the temperature of the coolant to be detected at both the outlet and the inlet, thereby improving the efficiency of cooling the battery cell module.

Further important features and advantages of the invention emerge from the subclaims, from the drawings and from the associated description of the figures based on the drawings.

It is understood that the features mentioned above and those to be explained below can be used not only in the combination specified in each case, but also in other combinations or alone, without departing from the scope of the present invention.

Preferred exemplary embodiments of the invention are shown in the drawings and are explained in more detail in the following description, with the same reference numbers referring to the same or similar or functionally the same components.

Show it schematically

• 1 a view of a battery cell module according to the invention;
• 2 a view of the battery cell module according to the invention with a housing open on one side;
• 3 Another view of the battery cell module according to the invention with the housing open on one side.

1 shows a view of a battery cell module 1 according to the invention for a motor vehicle, in particular for a battery-operated motor vehicle. The battery cell module 1 has a housing 2 through which a coolant can flow, with an inlet 3a and an outlet 3b for the coolant. The coolant can appropriately be dielectric. The coolant flows into the housing 2 via the inlet 3a and the coolant flows out of the housing 2 via the outlet 3b. The cooling liquid flows directly around all elements accommodated in the housing 2 within the housing 2 and cools them.

2 shows a view of the battery cell module 1 according to the invention with the housing 2 open on one side. As in 2 can be seen, the battery cell module 1 comprises a total of four cell stacks 4, which are arranged in the housing 2 so that the coolant can flow directly around them. The respective cell stack 4 comprises a plurality of battery cells 5 stacked together in the stacking direction SR in this exemplary embodiment, which are electrically contacted with one another via current bus bars 6. In addition, the battery cell module 1 has a conductor group 7 for each of the cell stacks 4. The respective conductor group 7 has a conductor 8 - here an FPC. The conductor 8 is provided for detecting voltage and temperature on the battery cells 5 of the respective cell stack 4 and is electrically connected to the respective busbars 6 at contact points 9. It goes without saying that the respective busbars 6 and the respective contact points 9 each assigned to a positive pole and a negative pole.

3 shows a further view of the battery cell module 1 according to the invention with the housing 2 open on one side. As in 3 can be seen, one of the respective conductor groups 7 has a flexible contact element 10 - here an FPC or a flexible circuit board - with a temperature sensor 11. The temperature sensor 11 can in particular be a surface-mounted NTC thermistor. The temperature sensor 11 is arranged on the contact element 10 so that the coolant can flow around it and can detect the temperature of the coolant. The temperature sensor 11 is arranged in the area of the inlet 3a or the outlet 3b. In the battery cell module 1, the temperature of the coolant inside the housing 2 at the inlet 3a and/or at the outlet 3b can therefore be detected by means of the temperature sensor 11 and the cooling of the battery cell module 1 can thereby be reliably controlled.

Claims (10)

Battery cell module (1) for a motor vehicle, - wherein the battery cell module (1) has at least one cell stack (4) made of several battery cells (5) stacked together, - wherein the battery cell module (1) has a housing (2) through which a coolant can flow and the respective cell stack (4) is accommodated in the housing (2) so that the coolant can flow directly around it, - the battery cell module (1) for the respective cell stack (4) having at least one conductor group (7) with a conductor (8) for detecting voltage the battery cells (5) and with a flexible contact element (10), - wherein in the respective conductor group (7) the contact element (10) with the conductor (8) and to the outside and the conductor (8) with the battery cells (5) of the respective cell stack (4) are electrically contacted, characterized in that in at least one of the respective conductor groups (7) the contact element (10) has a temperature sensor (11) around which the coolant can flow for detecting the temperature of the coolant flowing around the contact element (10). . Battery cell module Claim 1 , characterized in that the contact element (10) of the respective conductor group (7) is represented by a flexible circuit board or a flexible flat cable. Battery cell module Claim 1 or 2 , characterized in that - the respective conductor group (7) has a support structure for supporting the contact element (10), and - that the support structure is fastened below the contact element (10) at least in the area of the temperature sensor (11) and the temperature sensor (10) spatially fixed. Battery cell module according to one of the preceding claims, characterized in that the conductor (8) of the respective conductor group (7) has a current busbar (6) which electrically connects the battery cells (5) of the cell stack (4) with the contact element (10) of the respective conductor group (7 ) connects electrically conductively. Battery cell module according to one of the preceding claims, characterized in that the temperature sensor (11) is an NTC thermistor. Battery cell module according to one of the preceding claims, characterized in that the temperature sensor (11) is a surface-mounted component. Battery cell module according to one of the preceding claims, characterized in that - in the housing (2) for the coolant at least one inlet (3a) leading from the outside into the housing (2) and at least one outlet (3a) leading out of the housing (2) to the outside ( 3b) are shaped, and - that the respective inlet (3a) and the respective outlet (3b) are fluidly connected to one another via several flow paths and the flow paths within the housing (2) are immediately adjacent to the respective cell stack (4). Battery cell module Claim 7 , characterized in that the respective conductor group (7) is arranged in the housing (2) in such a way that the temperature sensor (9) of the contact element (8) to the inlet (3a) or to the outlet (3b) of the housing (2) is arranged adjacently. Battery cell module Claim 7 or 8th , characterized in that - the battery cell module (1) has two conductor groups (7) and the contact elements (10) of the two conductor groups (7) each have the temperature sensor (11), and - that the conductor groups (7) in the housing (2 ) are arranged such that the temperature sensor (11) of the contact element (10) of one conductor group (7) to the inlet (3a) and the temperature sensor (11) of the other contact element (10) of the other conductor group (7) to the outlet ( 3b) of the housing (2) are arranged adjacently. Battery cell module according to one of the preceding claims, characterized in - that the contact element (11) of the respective conductor group (7) can be connected externally to a control device of a battery management system, and - that temperature data recorded by the temperature sensor (11) can be transferred directly to the control device of the battery management system.