WO2023237257A1 - Arrangement for the dissipation of heat - Google Patents

Abstract

The invention relates to an arrangement for the dissipation of heat of a power battery cell (BT) to a carrier (TR). The arrangement has a power battery cell (BT) which has a peripheral side surface (SF), a base surface (BF) and a cover surface (DF). The arrangement has a carrier (TR) which is designed for heat dissipation from the power battery cell (BT) to a carrier environment (UM). At least one power battery cell (BT) is secured to the carrier (TR). The associated base surface (BF) is heat-conductively connected to the carrier (TR). The associated side surface (SF) is heat-conductively connected to a side cooling means (SK). The side cooling means (SK) is heat-conductively connected to the carrier (TR). In summary, according to the invention, the heat being released from the power battery cell (BT) is transferred via the heat-conducting connections to the carrier (TR) and from here to the carrier environment (UM).

Description

Description/Description

Arrangement for dissipating heat

The invention relates to an arrangement for dissipating heat from a power battery cell to a carrier, with the help of which improved integration of the power battery cell in a rail vehicle is made possible.

A power battery cell is understood to be a basic (generally smallest) electrochemical, electricity-producing unit of a battery. This consists of two electrodes, an electrolyte, a separator and a housing.

Integration of power battery cells, for example lithium-ion cells, into battery modules or in battery storage systems in a rail vehicle is very demanding due to conflicting target requirements for energy density, power density and safety.

In particular, the effects of the well-known “thermal runaway” must be taken into account, in which a lithium-ion cell can be destroyed as a power battery cell due to internal or external effects (e.g. overtemperature, internal short circuit, external short circuit, mechanical defect, etc.). .

During a "thermal runaway" a large amount of thermal energy is released, which causes a self-reinforcing destruction process of the power battery cell.

At the same time, the large amount of thermal energy released in neighboring power battery cells causes further “thermal runaway”. This process is also known as “thermal runaway propagation”. For a battery storage system in a rail vehicle that is considered safe, it is imperative to prevent a “thermal runaway” or limit its consequences as best as possible.

From a mechanical point of view, power battery cells in rail vehicles must be installed in a battery module or be integrated and positioned in a battery storage system. There they must be held firmly and protected from mechanical stress.

However, the mechanical components required for this lead to a reduction in the specific energy and power density of the battery module. of the battery storage.

There are different methods known that attempt to meet these conflicting design goals (optimization for high energy density on the one hand, high safety requirements on the other).

It is known to hold a power battery cell using a plastic frame. This frame is arranged in such a way that a cooling liquid can flow around a housing of the power battery cell. The coolant protects against “thermal runaway propagation” while simultaneously providing good, homogeneous cooling of the power battery cell.

A heat management system for battery packs for use in an electric car is known from publication US 2009/0023056 A1. The battery pack thermal management system contains thermistors connected to cells of a battery pack. A battery monitoring board is connected to the thermistors. The thermal management system cools this Battery pack to predetermined temperatures to increase the longevity of the battery pack in the electric vehicle.

It is the object of the present invention to provide an improved arrangement for dissipating heat from a power battery cell to a carrier, with the help of which an improved integration of the power battery cell in a rail vehicle is made possible, in particular with which a high energy density can be achieved with a high level of safety .

This task is solved by the features of patent claim 1. Advantageous further developments are specified in the dependent patent claims.

The invention relates to an arrangement for dissipating heat from a power battery cell to a carrier. The arrangement has a power battery cell that has a circumferential side surface, a bottom surface and a cover surface.

The arrangement has a carrier which is designed to dissipate heat from the power battery cell to a carrier environment. At least one power battery cell is attached to the carrier.

The associated floor surface is connected to the carrier in a heat-conducting manner. Preference is given to the entire or the entire floor surface is connected to the support in a heat-conducting manner.

The associated side surface is connected to a side cooling system in a heat-conducting manner. Preference is given to the entire or the entire side surface is connected to the side cooling in a heat-conducting manner. The side cooling, in turn, is connected to the carrier in a heat-conducting manner.

In summary, this ensures that the heat released by the power battery cell reaches the carrier via the heat-conducting connections and from there to the carrier environment. to be led .

In an advantageous development, the power battery cell is cylindrical.

The power battery cell is preferably a lithium-ion cell.

In an advantageous development, the side cooling is designed as a metal sleeve, preferably as an aluminum sleeve, which encloses the side surface of the power battery cell.

In an advantageous development, the side surface is connected to the side cooling via a thermally conductive adhesive.

In an advantageous development, the adhesive is electrically insulating.

In an advantageous development, the carrier is made of metal, in particular aluminum.

In an advantageous development, the base surface is connected to the carrier via a thermally conductive adhesive.

In an advantageous development, the adhesive is electrically insulating. In an advantageous development, the carrier is connected to a cooling plate in a thermally conductive manner.

In an advantageous development, the carrier is connected to the cooling plate in an electrically insulated manner.

In an advantageous development, two power battery cells are attached to the carrier adjacent to one another. The associated side cooling systems are at a distance from one another. The gap is filled with air or with a thermal insulation material.

In an advantageous development, the power battery cell is contacted via the cover surface.

In an advantageous development, the side cooling is connected to the carrier by an adhesive connection, a welded connection, a soldered connection or by a press connection.

In an advantageous development, the carrier is designed in the shape of a plate.

In an advantageous development, the arrangement described is part of a rail vehicle.

The present invention increases the energy and power density of power battery cells or achieved by battery storage systems. At the same time, possible “thermal runaway propagation” is made more difficult or prevented.

This is achieved in particular by the distance between the side cooling of adjacent power battery cells is filled with air or with a thermal insulation material.

The present invention achieves improved temperature control of the power battery cell, minimized aging of the power battery cell and homogenization of the temperature and aging of the power battery cells.

Furthermore, a reduction of thermal gradients in the power battery cells as well as a good thermal connection of each power battery cell to a thermal system is achieved.

The present invention makes railway or. Rail vehicle-specific requirements regarding safety, temperature control, energy and performance are achieved.

The present invention achieves improved cooling of the power battery cells: through the side and bottom cooling, larger areas are used for heat dissipation.

The present invention achieves thermal decoupling of neighboring power battery cells and thereby achieves greater system safety.

Due to the present invention, in a power battery cell under consideration that is in the state of “thermal runaway”, gases and flames released there are specifically dissipated upwards or in the direction of the cover surface by the design of the side cooling.

The present invention makes it possible to consider a power battery cell that is in the “Thermal” state Runaway", the design of the side cooling prevents neighboring power battery cells from being (directly) exposed to ejected material ("ejecta") from the affected power battery cell.

In summary, the present invention minimizes the risks and effects of a “side rupture” in a power battery cell that is in “thermal runaway”.

The present invention, in particular through the direct integration of the power battery cells into the carrier, saves previously required fastening components, weight and costs.

The present invention achieves a modular and therefore easily scalable structure of the components.

In addition to heat dissipation, the present invention also enables the attachment and positioning of a power battery cell or multiple power battery cells on one carrier optimized and simplified.

The present invention has further advantages over the known prior art:

- previously required purely mechanical battery cell holders are replaced by simple, cost-effective sleeves that serve as side cooling to dissipate heat,

- The battery cells are positioned and fixed using the sleeves; previously required spacers or holders are no longer required. The invention is explained in more detail below with the help of a drawing. This shows:

FIG. 1 shows an overview of an embodiment of the invention, FIG. 2 with reference to FIG. 1 further details on the embodiment of the invention.

FIG. 1 shows an overview of an embodiment of the invention.

The arrangement serves to dissipate heat from a power battery cell BT to a carrier TR.

The power battery cell BT has a circumferential side surface SF, a bottom surface BF and a cover surface DF.

The carrier TR is designed to dissipate heat from power battery cells BT to a carrier environment UM. Shown here is the situation in which four power battery cells BT are attached to the carrier TR.

The bottom surfaces BF of the power battery cells BT are connected to the carrier TR in a heat-conducting manner.

The respective side surfaces SF are connected in a heat-conducting manner to the associated side cooling systems SK.

Each side cooling SK is connected to the carrier TR in a heat-conducting manner.

In summary, the heat released by the power battery cells BT reaches the carrier TR via the heat-conducting connections and from there to the carrier environment UM. Two power battery cells BT are attached adjacent to each other on the carrier TR at a predetermined distance.

Their associated side cooling systems SK have a distance D from one another, which is further described below.

FIG. 2 shows and describes further details of the design of the invention with reference to FIG. 1.

The power battery cells BT are cylindrical.

The side cooling systems SK are designed as metal sleeves, preferably aluminum sleeves. These preferably completely enclose the respective side surfaces SF of the power battery cells BT.

Each side surface SF is connected to the side cooling SK via a thermally conductive adhesive KL. It is preferably an electrically insulating adhesive KL.

The carrier TR is plate-shaped and made of metal, in particular aluminum.

The base surfaces BF are each connected to the carrier TR via a thermally conductive adhesive KL. It is preferably an electrically insulating adhesive KL.

The carrier TR is connected in a thermally conductive manner to a cooling plate KP. The carrier TR is preferably electrically insulated and connected to the cooling plate KP in a heat-conducting manner.

The power battery cells BT shown here are attached adjacent to one another on the carrier TR. Their associated side cooling systems SK are at a distance D from one another.

The distance D is filled with air LU or with a thermal insulation material.

A contact KONT of the power battery cells BT is carried out via the cover surfaces DF of the two power battery cells BT.

The "sandwich structure" shown in FIG. 2 shows the electrical insulation measures between the arrangement according to FIG. 1 and the cooling plate KP. This electrical insulation remains undamaged even in the event of a "thermal runaway". receive .

Those made of metal or Side cooling SK made of aluminum prevents the thermal runaway from jumping to neighboring line battery cells BT with the thermal insulation measures at distance D - the thermal conduction path from line battery cell to line battery cell is prevented.

At the same time, any heat released is specifically transferred to the cooling plate KP and temporarily stored there.

Claims

Patent claims

1. Arrangement for dissipating heat from a power battery cell (BT) to a carrier (TR),

- with a power battery cell (BT) which has a circumferential side surface (SF), a bottom surface (BF) and a top surface (DF),

- with a carrier (TR), which is designed to dissipate heat from the power battery cell (BT) to a carrier environment (UM),

- in which at least one power battery cell (BT) is attached to the carrier (TR),

- in which the base surface (BF) is connected to the support (TR) in a heat-conducting manner,

- in which the side surface (SF) is connected to a side cooling (SK) in a heat-conducting manner,

- in which the side cooling (SK) is connected to the carrier (TR) in a heat-conducting manner,

- so that heat released by the power battery cell (BT) reaches the carrier (TR) via the heat-conducting connections and from there to the carrier environment (UM).

2. Arrangement according to claim 1, in which the power battery cell (BT) is cylindrical.

3. Arrangement according to claim 1 or 2, in which the side cooling (SK) is designed as a metal sleeve, preferably as an aluminum sleeve, which encloses the side surface (SF) of the power battery cell (BT).

4. Arrangement according to one of the preceding claims, in which the side surface (SF) is connected to the side cooling via a thermally conductive adhesive (KL). Arrangement according to claim 4, in which the adhesive (KL) is electrically insulating. Arrangement according to claim 1, in which the carrier (TR) is made of metal, in particular aluminum. Arrangement according to claim 1, in which the base surface (BF) is connected to the carrier (TR) via a thermally conductive adhesive (KL). Arrangement according to claim 7, in which the adhesive (KL) is electrically insulating. Arrangement according to one of the preceding claims, in which the carrier (TR) is connected in a thermally conductive manner to a cooling plate (KP). Arrangement according to claim 9, in which the carrier (TR) is connected to the cooling plate (KP) in an electrically insulated manner. Arrangement according to one of the preceding claims,

- in which two power battery cells (BT) are attached adjacent to each other on the carrier (TR),

- in which the associated side cooling systems (SK) are at a distance (D) from one another, and

- in which the distance (D) is filled with air (LU) or with a thermal insulation material. Arrangement according to one of the preceding claims, in which a contact (KONT) of the power battery cell

(BT) is carried out over the cover surface (DF). Arrangement according to one of the preceding claims, in which the side cooling (SK) is connected to the carrier (TR) by an adhesive connection, a welded connection, a soldered connection or by a press connection. Rail vehicle with an arrangement according to one of claims 1 to 13.