WO2024256258A1 - Battery assembly - Google Patents

Abstract

The invention relates to a battery assembly (10) comprising at least one battery cell (1), a main printed circuit board (2) which is electrically connected to the battery cell (1), and a fuse board (3) which is electrically connected to the main printed circuit board (2), wherein the fuse board (3) has an electric fuse (4), preferably at least two electric fuses (4), and the fuse board (3) is designed as a component which is separate from the main printed circuit board (2) and is arranged at a distance (5) to the main printed circuit board (2).

Description

Description

title

battery arrangement

State of the art

The present invention relates to a battery arrangement, a battery pack, and a consumer.

Battery arrangements are known which have a circuit board which, for example, includes a battery management system. The battery management system can be used, for example, to monitor the properties of the batteries and to control the provision of electrical energy by the battery. Battery arrangements often also have electrical fuses which, for example, interrupt the connection between the cells and/or other components when a certain electrical current is reached. It is known that such fuses are integrated into the main current path.

disclosure of the invention

The battery arrangement according to the invention with the features of claim 1 is characterized by a particularly advantageous construction, which can optimally utilize the available installation space. In particular, this can be done by means of a particularly simple, robust and cost-effective construction. This is achieved according to the invention by a battery arrangement comprising at least one battery cell, a main board, and a fuse board. The main board is electrically connected, in particular directly, to the at least one battery cell. The fuse board is electrically connected to the main board. The fuse board has an electrical fuse. In addition, the fuse board is designed as a Mainboard is a separate component and is arranged at a predetermined distance from the mainboard.

In particular, a printed circuit board is considered to be a main board and/or a fuse board, preferably one which can contain electronic components.

Preferably, an electrical fuse is considered to be a fuse element which prevents current transmission between at least two elements of the battery arrangement as soon as a predefined maximum fuse current is exceeded.

In other words, a battery arrangement is provided which has at least one battery cell which is intended to provide electrical energy for a consumer. The battery cell is electrically connected to the main board. In particular, the main board can be set up to monitor operating parameters of the at least one battery cell and/or to control a provision of electrical energy by the battery cell. The main board can particularly preferably comprise a battery management system. In addition to the main board, a fuse board is provided which can, for example, be at least partially designed as a circuit board. The fuse board is arranged as a separate component from the main board and is arranged at a predetermined distance from the main board. This means that the main board and fuse board can be arranged independently of one another. The at least one electrical fuse of the battery arrangement is provided on the fuse board.

The battery arrangement offers the advantage that a particularly flexible geometry can be provided for a wide range of requirements, in particular with regard to the available installation space. By designing the main board and fuse board as separate components, the available installation space can be optimally utilized by arranging the boards independently of one another. This can, for example, avoid enlarging the outer contour of the battery arrangement. In addition, a simplified production of the Battery arrangement is made possible because, for example, various connection and fastening options for the fuse board are possible, which, for example, do not require additional soldering processes. In particular, very low contact resistance and an optimal thermal connection of the fuse board are still possible. For example, it can also be made possible that heat-generating power components can be spatially separated from the battery cells by the special separation of the fuse board and the main board in order to avoid undesirable heat input into the battery cells.

The subclaims contain preferred developments of the invention.

The battery arrangement preferably comprises at least one power contact element which electrically and mechanically connects the main board and the fuse board to one another. In particular, a connecting element which is designed to enable current transmission within a high-current path of the battery arrangement can be regarded as a power contact element. Because the power contact element simultaneously establishes the electrical and mechanical connection between the main board and the fuse board, a particularly simple, cost-effective and compact construction can be provided.

The power contact element is particularly preferably electrically connected to the electrical fuse. This means that there is an electrical connection between the power contact element and the electrical fuse. For example, this can provide electrical protection via the electrical fuse and via the power contact element of the other components connected to it, such as in particular the battery cells, and in particular against an overcurrent. This can provide a particularly high level of effectiveness of the electrical fuse in order to reliably prevent damage caused by excessive electrical currents.

Preferably, the power contact element is at least partially formed as a sheet metal element. Preferably, the sheet metal-shaped power contact element has a Thickness of at least 0.1 mm, in particular up to a maximum of 1.5 mm, preferably from 0.5 mm to 1 mm. This enables a particularly simple and cost-effective construction which can provide reliable, efficient power transmission. Advantageously, the power contact element can at least partially have a coated surface, for example using tin, silver, nickel or gold, and/or an increased surface roughness in a contact area with an adjacent component, such as the fuse board. This enables particularly efficient power transmission.

Particularly preferably, the power contact element is in surface contact with the fuse board. This makes it easy to achieve a low contact resistance. Furthermore, this makes it easy to provide a mechanical mount for the fuse board using the power contact element. In addition, this makes it possible to establish good thermal contact.

Preferably, the contact element is in surface contact with the two opposite sides of the fuse board. This means that the preferably plate-shaped fuse board is contacted by the contact element on its two opposite sides. This makes it possible to provide particularly good electrical, mechanical and thermal contact.

The power contact element is further preferably connected to the fuse board by means of a force-fit connection, preferably a screw connection. Alternatively or additionally, the contact element is connected to the fuse board by means of a material connection, preferably a welded connection and/or a soldered connection. This enables a reliable electrical and mechanical connection to be made while being simple and cost-effective to manufacture.

Preferably, the power contact element is made of a metal, in particular copper or brass. Preferably, the power contact element is made exclusively of the metal. This allows highly efficient power transmission with a simple and cost-effective construction. The power contact element can preferably be designed as a metallic wire. This makes it possible to provide a particularly flexible geometry in a particularly simple manner.

Preferably, the fuse board and the main board are arranged parallel to one another and at least at the predetermined distance along a direction orthogonal to the main board. Preferably, the predetermined distance is not equal to zero. This makes it possible to provide a particularly advantageous compact geometry of the battery arrangement. In particular, an enlargement of the main board in its plane can be avoided.

The main board is further preferably arranged between the fuse board and the at least one battery cell, in particular along the direction orthogonal to the main board. This means that the fuse board is arranged on the side of the main board facing away from the battery cell. This makes it possible to provide a large distance between the fuse board, and thus the electrical fuse, and the battery cell. For example, this makes it possible to particularly effectively avoid a thermal influence of the battery cell on the electrical fuse.

The fuse board preferably has several electrical fuses connected in parallel. This can increase the current carrying capacity of the entire system.

The electrical fuse preferably has a switchable fuse. In particular, a switchable fuse is considered to be an electrical fuse which can be triggered either when a predetermined load current is exceeded or by means of an external control signal, i.e. which interrupts the current transmission. The electrical fuse can preferably be designed as a surface-mounted component of the fuse circuit board. For example, such a surface-mounted component can also be referred to as an SMT component. The fuses are preferably designed in such a way that in the case of activation, i.e. when the fuse is triggered by means of the external control signal, all fuses controlled together. This allows the power transmission to be interrupted in a simple and particularly effective manner in the event of a load.

Preferably, the battery arrangement further comprises a cell holder for receiving the at least one battery cell. The fuse board rests on the cell holder and/or is mechanically connected directly to the cell holder. This makes it possible to provide a particularly simple and robust mechanical construction of the battery arrangement.

The battery arrangement preferably also comprises a protective element for protecting, in particular, the electrical fuse, from moisture and/or dust. In particular, the protective element is designed as a potting compound on the fuse board, with the electrical fuse preferably being embedded in the potting compound. Preferably, at least partial areas of the contact elements and/or the fuse board are also embedded in the potting compound. Advantageously, as large a part of the contact elements as possible, for example at least those partial areas that run directly above the fuse board, are also embedded in the potting compound.

This makes it possible to provide a particularly robust battery arrangement with reliable protection of the electrical fuse, which enables protection of the electrical fuse against environmental influences.

Particularly preferably, the battery arrangement further comprises at least one electrical control contact element, which is designed for the electrical connection, and in particular for controlling, the fuse board. Preferably, the electrical control contact element is additionally designed to mechanically connect the fuse board and the main board to one another. Particularly preferably, the distance between the fuse board and the main board is additionally defined by the control contact element. This makes it possible to provide a particularly simple and compact design of the battery arrangement, which has few components.

Preferably, the battery arrangement further comprises a heat sink, wherein the fuse board is directly mechanically connected to the heat sink. This allows particularly effective heat dissipation from the fuse board to be provided in order to ensure particularly reliable functioning of the electrical To ensure safety, a cell holder of the battery arrangement can be provided as a heat sink, for example, or alternatively preferably another component which enables heat to be dissipated from the fuse board.

Furthermore, the invention leads to a battery pack, in particular a removable battery pack, which comprises the battery arrangement described. The battery pack preferably has a housing within which the battery arrangement is accommodated, in order to protect the battery arrangement.

Furthermore, the invention relates to a consumer, in particular a tool, preferably a hand-held tool, which comprises the described battery pack and/or the described battery arrangement.

Short description of the drawings

The invention is described below using exemplary embodiments in conjunction with the figures. In the figures, functionally identical components are each identified with the same reference numerals. In the following:

Figure 1 is a perspective view of a battery arrangement according to a first embodiment of the invention,

Figure 2 is a detailed sectional view of the battery arrangement of Figure 1,

Figure 3 is a further detailed view of the battery arrangement of Figure 1,

Figure 4 is a detailed sectional view of a battery arrangement according to a second embodiment of the invention,

Figure 5 is a detailed view of a removable battery pack with the battery arrangement of Figure 4,

Figure 6 is a detailed view of a battery arrangement according to a third embodiment of the invention, and

Figure 7 is a detailed view of the battery arrangement of Figure 7. Preferred embodiments of the invention

Figure 1 shows a perspective view of a battery arrangement 10 according to a first embodiment of the invention. Figures 2 and 3 show detailed views of the battery arrangement 10 of Figure 1.

The battery arrangement 10 serves as an energy storage device for a consumer (not shown), such as a power tool, preferably one that can be operated by hand. Preferably, at least one electric motor of the consumer can be supplied with the electrical energy stored in the battery arrangement 10. Preferably, the battery arrangement 10 is part of a removable battery pack that can be detachably connected to a tool part of the consumer, in particular by means of a connection mechanism that is not described in more detail. This means that the removable battery pack of the battery arrangement 10 can be replaced, for example, with an identically constructed removable battery pack.

An electrical connection between the battery arrangement 10 and the other components, such as the electric motor, of the consumer is made by means of connection elements 25 of the battery arrangement 10. The connection elements 25 can preferably be designed in the form of so-called contact tulips. Preferably, a different electrical potential is applied to the two connection elements 25.

The battery arrangement 10 further comprises a plurality of battery cells 1, which can be electrically connected to one another in parallel and/or in series.

The battery cells 1 are held in position relative to one another by means of a cell holder 15. The cell holder 15 can also assume a protective function for the battery cells 1.

In addition, the battery arrangement 10 comprises a main board 2, which is electrically connected to the battery cells 1, for example by means of cell connectors not shown in detail. The main board 2 can be a Battery management system which is set up to monitor operating parameters of the battery cells 1 and/or to control the output of electrical energy of the battery arrangement 10

The battery arrangement 10 also comprises a fuse board 3, which is also designed as a printed circuit board. The fuse board 3 is designed as a separate component from the main board 2. In addition, the fuse board 3 is arranged at a predetermined distance 5 from the main board 2.

In detail, the fuse board 3 is arranged parallel to the main board 2 and along a direction 20 orthogonal to the main board 2 on a side of the main board 2 opposite the battery cells 1.

The fuse board 3 has two electrical fuses 4. The electrical fuses 4 are each designed as a switchable fuse. This means that if a current flow through the electrical fuse 4 reaches or exceeds a predetermined maximum fuse current, the electrical fuse 4 automatically interrupts the current transmission, in particular by melting the electrical fuse 4. Alternatively or additionally, the current transmission through the electrical fuse 4 is interrupted if the electrical fuse 4 is actuated by means of a switching signal.

The electrical fuses 4 are protected from moisture and/or dust by means of a protective element 9 on the fuse board 3. The protective element 9 can be designed as a potting compound on the fuse board 3.

The two electrical fuses 4 are arranged electrically parallel to each other in order to increase the current carrying capacity.

Preferably, the fuse board 3 with the electrical fuses 4 is provided exclusively to provide the electrical protection of the battery arrangement 10. This means that the fuse board 3 fulfills prefers no other purpose than the integration of the electrical fuses 4 into the main current path of the battery arrangement 10.

The battery arrangement 10 offers the advantage that a particularly flexible geometry and an efficient and reliable mode of operation can be provided. In particular, the available installation space can be optimally utilized due to the possibility of flexible arrangement of the fuse board 3 relative to the main board 2. In addition, a maximum dimension in the plane of the main board 2 can be kept small, whereby a particularly compact battery arrangement 10 can be provided. Furthermore, an optimized thermal connection of the electrical fuses 4 can be made possible in order to be able to provide optimal function and thus particularly reliable operation of the battery arrangement 10.

The fuse board 3 and the main board 2 are electrically and mechanically connected to each other by means of two power contact elements 6.

The power contact elements 6 form in particular parts of the main current path of the battery arrangement 10. In other words, the entire current always flows through the power contact elements 6 when the battery arrangement 10 is in operation. The fuse board 3 with the electrical fuses 4 is integrated between the power contact elements 6 and electrically connected to them in order to electrically secure the power contact elements 6. This means that when the electrical fuse(s) 4 are triggered, the current transmission of the entire battery arrangement 10 is completely interrupted.

In particular, one of the power contact elements 6 can be electrically connected directly to one of the two contact elements 25, wherein the other power contact element 6 is electrically connected to the battery cells 1. For example, the other contact element 25 can be electrically connected directly to the battery cells 1.

Preferably, the main board 2 is electrically connected to one or both of the power contact elements 6. The power contact elements 6 are designed as thick copper sheets to enable optimal current transmission with low electrical resistance.

The fuse board 3 is in surface contact with each of the power contact elements 6. In detail, the power contact elements 6 are designed as bent sheets such that each power contact element 6 is in surface contact with the two opposite sides 31, 32 of the fuse board 3 (see Figures 2 and 3). On the contact surfaces with the fuse board 3, each power contact element 6 preferably has a gold-plated surface area in order to be able to provide a particularly good electrical contact. Alternatively or additionally, each of the power contact elements 6 can have an increased surface roughness on the contact surface with the fuse board 3 in order to further improve the electrical contact.

A connection between the power contact element 6 and the fuse board 3 can be made by means of a screw connection 8, whereby, for example, two screws can be provided for each power contact element 6 (see Figure 3). A through-bolt connection is particularly advantageous, whereby the power contact element 6 can be pressed onto the fuse board 3 on both sides by means of the screw connection 8, which further improves the electrical contact.

Figure 4 shows a detailed sectional view of a battery arrangement 10 according to a second embodiment of the invention. The second embodiment essentially corresponds to the first embodiment of Figures 1 to 3, with the difference of an alternative arrangement and fastening of the fuse board 3. In the second embodiment of Figures 4 and 5, the fuse board 3 is arranged such that it is in direct contact with a heat sink 7. In particular, the fuse board 3 is mechanically connected to the heat sink 7. The heat sink therefore also serves to mechanically hold the fuse board 3.

The heat sink 7 is in particular a part of the cell holder 15. By arranging the fuse board 3 in mechanical contact with the heat sink 7, a particularly effective heat dissipation from the fuse board 3 and thus from the electrical fuses 4 can be enabled. This can ensure a particularly reliable function of the electrical fuses 4.

Figure 5 also shows a housing cover 16 of the battery arrangement 10, which can be provided to cover the battery arrangement 10 at least partially, in particular in the area of the circuit boards 2, 3. This can provide mechanical protection and protection against environmental influences, such as dust and/or moisture, for the battery arrangement 10. Preferably, such a housing cover 16 can be provided in every embodiment.

Figure 6 shows a detailed view of a battery arrangement 10 according to a third embodiment of the invention. The third embodiment essentially corresponds to the first embodiment of Figures 1 to 3, with the difference of an alternative design and connection of the power contact elements 6. In the third embodiment of Figures 6 and 7, the power contact elements are also designed as thick copper sheets. Other forms of power contact elements 6 are also conceivable. In the third embodiment, however, the power contact elements 6 are in contact with only one side of the fuse board 3, namely the underside facing the main board 2. This makes it possible to provide a particularly simple and cost-effective design of the battery arrangement 10.

In addition, in the second embodiment of Figures 6 and 7, an alternative connection of power contact elements 6 and fuse board 3 is provided. Here, each of the power contact elements 6 is connected to the fuse board 3 by means of two material-locking connections 8a. The material-locking connections 8a can preferably be designed as a welded connection and/or soldered connection. This means that a reliable electrical connection with low electrical resistance can also be provided with a reliable and simple and cost-effective mechanical connection of power contact elements 6 and fuse board 3. In particular, the fuse board 3 has Power contact element 6 has at least one recess 100, for example two recesses 100, into which the power contact elements 6 engage. The power contact elements 6 are designed in such a way that they reach through the recesses 100 and exit on the other side of the fuse board 3, as can be seen in Figure 7. The material connection is then made by soldering.

Figure 7 shows the back of the fuse board 3, which faces the main board 2, with a single switchable electrical fuse 4 being arranged on the back, for example. Alternatively, it is also conceivable to arrange no or at least two electrical fuses on the back. The same number of electrical fuses 4, a different number of electrical fuses 4, or no electrical fuse at all can be arranged on the front of the fuse board 3. For example, the front of the fuse board 3 has two further electrical fuses 4. The electrical fuses 4 are designed the same, for example, but it would also be conceivable that different electrical fuses 4 are used. For example, it would be conceivable to use both switchable and non-switchable or passive electrical fuses.

The electrical fuses 4 of the fuse board 3 are designed, for example, as switchable electrical fuses. The electrical fuses 4 are designed to be switchable via a control element 102 in the form of a contact pin 104. The fuse board 3 is connected to at least one control element 102. The fuse board 4 is preferably connected to at least two control elements 102, for example to four control elements 102. This advantageously means that the switching function is retained in the event of damage or if one of the control elements 102 breaks off. The four control elements 102 are connected, for example, to the fuse board 3 via circular recesses 106 in the fuse board 3 and to the switchable electrical fuses 4 via the fuse board 3. It is also conceivable that the fuse board 3 is connected to at least one control element 102 for each electrical fuse 4, as a result of which the electrical fuses 4 can also be switched independently of one another. The switchable electrical fuses 4 are designed, for example, in such a way that if the current flowing through the power contact elements 6 is too high, the electrical fuses 4 are triggered passively. This can advantageously provide overcurrent protection.

In addition, the switchable electrical fuses 4 are designed in such a way that if the temperature of a battery cell 1, several battery cells 1 or the battery pack is too high, the electrical fuses 4 are actively triggered by means of the control element 102. This can advantageously provide cell overtemperature protection.

Furthermore, the switchable electrical fuses 4 are designed in such a way that if the voltage of a battery cell 1, several battery cells 1 or the battery pack is too high, the electrical fuses 4 are actively triggered by means of the control element 102. Cell overvoltage protection can advantageously be provided in this way.

In addition, the fuse board 3 has a protective element 108, which is designed to protect the contact areas of the electrical contact elements 6 and the control elements 102 with the fuse board 3. The protective element 108 is designed, for example, as a potting compound.

Claims

claims 1 . Battery assembly comprising: - at least one battery cell (1), - a main board (2) which is electrically connected to the battery cell (1), and - a fuse board (3) which is electrically connected to the main board (2), - wherein the fuse board (3) has an electrical fuse (4), preferably at least two electrical fuses (4), and - wherein the fuse board (3) is designed as a separate component from the main board (2) and is arranged at a distance (5) from the main board (2), characterized in that the at least two electrical fuses (4) are designed as switchable electrical fuses (4). 2. Battery arrangement according to claim 1, further comprising at least one power contact element (6) which electrically and mechanically connects the main board (2) and the fuse board (3) to one another. 3. Battery arrangement according to claim 2, wherein the power contact element (6) is electrically connected to the electrical fuse (4). 4. Battery arrangement according to claim 2 or 3, wherein the power contact element (6) is at least partially sheet-like. 5. Battery arrangement according to one of claims 2 to 4, wherein the power contact element (6) is connected to the fuse board (3) by means of a force-fitting connection and/or by means of a material-fitting connection. 6. Battery arrangement according to one of claims 2 to 5, wherein the power contact element (6) is formed from a metal, in particular copper or brass. 7. Battery arrangement according to one of the preceding claims, wherein the main board (2) and the fuse board (3) are arranged parallel to each other and at least at the predetermined distance (5) along a direction (20) orthogonal to the main board (2). 8. Battery arrangement according to one of the preceding claims, wherein the battery arrangement has at least two control elements (102) which are designed to switch the electrical fuses (4). 9. Battery arrangement according to one of the preceding claims, wherein the fuse board (3) has a plurality of electrical fuses (4) connected in parallel to one another. 10. Battery arrangement according to one of the preceding claims, wherein the electrical fuse (4) comprises a switchable fuse. 11. Battery arrangement according to one of the preceding claims, further comprising a protective element (9) for protection against moisture and/or dust, in particular wherein the protective element (9) is designed as a potting compound on the fuse board (2). 12. Battery arrangement according to one of the preceding claims, further comprising at least one electrical control contact element which is designed for the electrical connection and in particular for controlling the fuse board (3). 13. Battery arrangement according to one of the preceding claims, further comprising a heat sink (7), wherein the fuse board (3) is directly mechanically connected to the heat sink (7). 14. Battery pack, in particular a removable battery pack, comprising a battery arrangement (10) according to one of the preceding claims 15. Consumer, in particular tool, in particular hand-operated tool, comprising a battery arrangement (10) according to one of claims 1 to 13 and/or a battery pack according to claim 14.