JP2023070980A - battery monitoring module - Google Patents

Abstract

To provide a battery monitoring module capable of changing an arrangement of wires while attaining reduction of cost.SOLUTION: A battery monitoring module comprises: a first FPC 100A which includes a plurality of first wires 120A only on one side of a base film and in which the plurality of first wires 120A is connected to electrodes of which the potentials are V(0), V(2), ..., V(2n-2) and V(2n); a second FPC 100B which includes a plurality of second wires 120B only on one side of the base film and in which the plurality of second wires 120B is connected to electrodes of which the potentials are V(1), V(3), ..., V(2n-3) and V(2n-1); and a third FPC 100C which includes a plurality of third wires 120C only on one side of the base film. The plurality of third wires 120C is arranged in the other of electrodes of V(0), V(1), V(2), V(3), ..., V(2n-3), V(2n-2), V(2n-1) and V(2n).SELECTED DRAWING: Figure 1

Description

The present invention relates to a battery monitoring module attached to a battery.

For example, a battery mounted on an electric vehicle or the like is provided with a voltage monitoring device for monitoring the voltage of the battery. This voltage monitoring device is provided with a battery monitoring module having a flexible printed circuit board (hereinafter referred to as FPC). A conventional battery monitoring module will be described with reference to FIGS. 8 to 10. FIG. FIG. 8 is an illustration of the electrical wiring of the battery monitoring module attached to the battery. FIG. 9 is a plan view showing a state in which a conventional battery monitoring module is attached to a battery. FIG. 10 is an explanatory diagram of a layout for cutting out an FPC used for a conventional battery monitoring module from an FPC material.

In the battery, a plurality of cells 10 each having a positive electrode and a negative electrode on both sides in the width direction are arranged such that the positive electrodes and negative electrodes of adjacent cells 10 are adjacent to each other. The plurality of cells 10 are configured such that adjacent positive electrodes and negative electrodes are electrically connected by bus bars 11 serving as electrodes, thereby being connected in series.

Here, the potentials of the plurality of electrodes are V(0), V(1), V(2), V(3), . . . , V(2n−3), V( 2n-2), V(2n-1), and V(2n). In FIGS. 8 and 9, V ( ) is omitted and only numbers in ( ) are shown for potentials. As shown in FIGS. 8 and 9, the potentials of the plurality of electrodes are configured to alternately increase on both sides in the width direction in the cell arrangement direction.

A battery monitoring module 500 is attached to the top of the battery configured as described above (see FIG. 9). Battery monitoring module 500 includes FPC 510 and connector 520 connected to the end of FPC 510 . In general, between adjacent wires in an FPC and between adjacent terminals in a connector connected to the FPC, the larger the potential difference, the more likely a short circuit due to migration or the like occurs. In particular, when the distance between adjacent wires or the distance between adjacent terminals is short, such a problem becomes apparent. The fact that it is desirable to reduce the potential difference between wires is the same for the ECU circuit connected to the FPC. It is possible to reduce and simplify the ECU circuit board. Thus, it is desirable to minimize the potential difference between adjacent wirings and between terminals. Therefore, the potentials of the wirings connected to the connector 520 are V(0), V(1), V(2), V(3), . . . , V(2n−3), V(2n−2) , V(2n−1), V(2n) (see FIG. 8).

However, in the case of an FPC (single-sided FPC) in which a conductor (copper foil, etc.) is provided only on one side of a base film, it is not possible to obtain the configuration described above simply by devising a printed wiring pattern. This is because the wires must cross each other as shown in FIG. Therefore, in the conventional battery monitoring module, an FPC 510 (double-sided FPC) in which conductors are provided on both sides of a base film is used. In FIG. 9, the wiring provided on one surface of the base film is indicated by solid lines, and the wiring provided on the other surface is indicated by dotted lines. By adopting a double-sided FPC in this way, the potentials of a plurality of wirings connected to the connector 520 can be set to V(0), V(1), V(2), V(3), . . . , V(2n). -3), V(2n-2), V(2n-1), and V(2n).

However, in the case of the double-sided FPC, there is a problem that manufacturing difficulty increases as the size increases, resulting in an increase in cost. In addition, there is a problem that an unnecessary portion of the FPC used for the battery monitoring module is discarded after being cut out from the FPC material. That is, in order to secure an exhaust path at the center in the width direction of the battery, the FPC 510 is bifurcated into a portion 511 arranged on one side in the width direction of the battery and a portion 512 arranged on the other side. shape. Therefore, when the FPC 510 is cut out from the FPC material 510X as shown in FIG. 10, the portion X between the branch portions is discarded, resulting in a large amount of discarded material.

In addition, there is also known a technique of connecting a single-sided FPC and a double-sided FPC with a connector to configure the potentials of a plurality of wirings as described above (see Patent Document 1). However, this technique requires a separate connector for connecting the single-sided FPC and the double-sided FPC, making it difficult to reduce costs.

There is also known a technique of configuring the potentials of a plurality of wirings as described above using a single-sided FPC by folding back the wiring portion to the connector (see Patent Document 2). However, with this technique, it is difficult to reduce costs because a connector (SMT connector) that is connected by surface mounting cannot be adopted.

Furthermore, there is also known a technique of configuring the potentials of a plurality of wirings as described above using a single-sided FPC by folding the FPC at a plurality of locations (see Patent Document 3). However, in the case of this technique, there is a problem that the folded portions exist at a plurality of locations, so that the space for arranging the FPC becomes large, and space saving cannot be achieved.

Japanese Patent No. 6837033 Japanese Patent Application Laid-Open No. 2020-13829 Japanese Patent No. 6774460

SUMMARY OF THE INVENTION It is an object of the present invention to provide a battery monitoring module capable of changing the arrangement of wiring while reducing costs.

The present invention employs the following means to solve the above problems.

That is, the battery monitoring module of the present invention is
A battery in which a plurality of cells having positive and negative electrodes on both sides in the width direction are arranged so that the positive and negative electrodes of adjacent cells are adjacent to each other, and connected in series by connecting the positive and negative electrodes of adjacent cells. In the attached battery monitoring module,
The battery is configured such that the potential of an electrode composed of at least one of a positive electrode and a negative electrode increases alternately on both sides in the width direction in the cell arrangement direction,
V(0), V(1), V(2), V(3), . , V(2n−1), V(2n), then
Only one surface of the base film has a plurality of first wirings, and the plurality of first wirings have potentials of V(0), V(2), . . . , V(2n−2), a first flexible printed wiring board respectively connected to the electrodes serving as V(2n);
Only one surface of the base film has a plurality of second wirings, and the plurality of second wirings have potentials of V(1), V(3), . . . , V(2n−3), a second flexible printed wiring board connected to the electrodes that become V(2n−1);
a third flexible printed wiring board having a plurality of third wirings only on one surface of the base film;
with
A portion of the first flexible printed wiring board is superimposed on the third flexible printed wiring board, and the plurality of first wirings and the plurality of third wirings are combined with the first flexible printed wiring board and the third wiring. 3 are electrically connected to each other within a region where the flexible printed wiring boards are overlapped,
A portion of the second flexible printed wiring board is superimposed on the third flexible printed wiring board, and the plurality of second wirings and the plurality of third wirings are connected to the second flexible printed wiring board and the third flexible printed wiring board. 3 flexible printed wiring boards are electrically connected to each other in the overlapped area,
The potentials of the plurality of third wirings are V(0), V(1), V(2), V(3), . . . , V(2n-3), V(2n-2), V(2n- 1) and V(2n).

According to the present invention, by using three types of flexible printed wiring boards having a plurality of wirings on only one side of the base film, the arrangement of the wirings can be changed, and the potential difference between adjacent wirings can be reduced. can do. In the present invention, the plurality of wirings provided on each of the first to third flexible printed wiring boards may include wirings used for purposes other than electrically connecting to the electrodes of the battery. In other words, the present invention includes a case where the wirings provided on the first flexible printed wiring board have wirings other than the plurality of first wirings electrically connected to the electrodes of the battery. The same applies to the wiring provided on the second flexible printed wiring board and the wiring provided on the third flexible printed wiring board. In this case, wiring used for purposes other than connecting to the electrodes of the battery may be provided between the plurality of wirings (first to third wirings) connected to the electrodes of the battery. Further, the relationship between the potential of the wiring used for purposes other than connecting to the battery electrodes and the potential of the plurality of wirings (first to third wirings) connected to the battery electrodes is not particularly limited. never

The first flexible printed wiring board may be composed of a plurality of flexible printed wiring boards, and a part of each flexible printed wiring board may be overlapped with the third flexible printed wiring board.

As a result, even if each flexible printed wiring board constituting the first flexible printed wiring board is small, the first flexible printed wiring board as a whole can be made large.

The second flexible printed wiring board may be composed of a plurality of flexible printed wiring boards, and a part of each flexible printed wiring board may be overlapped with the third flexible printed wiring board.

Thereby, even if each flexible printed wiring board constituting the second flexible printed wiring board is small, the entire second flexible printed wiring board can be made large.

It is preferable to provide a connector that is connected to the third flexible printed wiring board by surface mounting.

Thereby, the manufacturing cost can be reduced.

Also, the battery monitoring module of the present invention is
A battery in which a plurality of cells having positive and negative electrodes on both sides in the width direction are arranged so that the positive and negative electrodes of adjacent cells are adjacent to each other, and connected in series by connecting the positive and negative electrodes of adjacent cells. In the attached battery monitoring module,
The battery is configured such that the potential of an electrode composed of at least one of a positive electrode and a negative electrode increases alternately on both sides in the width direction in the cell arrangement direction,
V(0), V(1), V(2), V(3), . , V(2n−1), V(2n), then
Only one surface of the base film has a plurality of first wirings, and the plurality of first wirings have potentials of V(0), V(2), . . . , V(2n−2), a first flexible printed wiring board respectively connected to the electrodes serving as V(2n);
Only one surface of the base film has a plurality of second wirings, and the plurality of second wirings have potentials of V(1), V(3), . . . , V(2n−3), a second flexible printed wiring board connected to the electrodes that become V(2n−1);
with
A part of one of the first flexible printed wiring board and the second flexible printed wiring board is superimposed on the other, and the plurality of first wirings and the plurality of second wirings are arranged in the first wiring. The flexible printed wiring board and the second flexible printed wiring board are electrically connected within a region where the flexible printed wiring board and the second flexible printed wiring board are overlapped,
The potentials of the plurality of first or second wirings on the other flexible printed wiring board are V(0), V(1), V(2), V(3), . . . , V(2n−3), V (2n-2), V(2n-1) and V(2n) are arranged in this order.

According to the present invention, by using two types of flexible printed wiring boards having a plurality of wirings on only one surface of a base film, it is possible to change the arrangement of wirings and reduce the potential difference between adjacent wirings. can do. In addition, in the present invention, a plurality of wirings provided on each of the first and second flexible printed wiring boards may include wirings used for a purpose other than the purpose of electrically connecting to the electrodes of the battery. In other words, the present invention includes a case where the wirings provided on the first flexible printed wiring board have wirings other than the plurality of first wirings electrically connected to the electrodes of the battery. The same applies to wiring provided on the second flexible printed wiring board. In this case, wiring used for purposes other than connecting to the electrodes of the battery may be provided between the plurality of wirings (first and second wirings) connected to the electrodes of the battery. Moreover, the relationship between the potential of the wiring used for purposes other than connecting to the battery electrodes and the potential of the plurality of wirings (first and second wirings) connected to the battery electrodes is not particularly limited. never

One of the flexible printed wiring boards is folded back so that a plurality of first or second wirings are connected to the respective electrodes of the battery, while the other flexible printed wiring board is partially bent. preferably superimposed.

It is preferable to provide a connector connected to the other flexible printed wiring board by surface mounting.

Thereby, the manufacturing cost can be reduced.

The first flexible printed wiring board may be composed of a plurality of flexible printed wiring boards having ends overlapped with each other and a plurality of wirings electrically connected to each other.

As a result, even if each flexible printed wiring board constituting the first flexible printed wiring board is small, the first flexible printed wiring board as a whole can be made large.

The second flexible printed wiring board may be composed of a plurality of flexible printed wiring boards having ends overlapped with each other and a plurality of wirings electrically connected to each other.

Thereby, even if each flexible printed wiring board constituting the second flexible printed wiring board is small, the entire second flexible printed wiring board can be made large.

In addition, each of the above configurations can be employed in combination as much as possible.

As described above, according to the present invention, it is possible to change the arrangement of wiring while reducing costs.

FIG. 1 is a plan view showing a state in which a battery monitoring module according to Embodiment 1 of the present invention is attached to a battery. FIG. 2 is an explanatory diagram of a layout for cutting out the flexible printed wiring board used for the battery monitoring module according to the first embodiment of the present invention from the material of the flexible printed wiring board. FIG. 3 is a schematic cross-sectional view showing a structure for electrically connecting wirings of two flexible printed wiring boards. FIG. 4 is a plan view showing a state in which a battery monitoring module according to Embodiment 2 of the present invention is attached to a battery. FIG. 5 is an explanatory diagram of a layout for cutting out the flexible printed wiring board used for the battery monitoring module according to the second embodiment of the present invention from the material of the flexible printed wiring board. FIG. 6 is a plan view showing a state in which a battery monitoring module according to Embodiment 3 of the present invention is attached to a battery. FIG. 7 is a plan view showing a state in which a battery monitoring module according to Embodiment 4 of the present invention is attached to a battery. FIG. 8 is an illustration of the electrical wiring of the battery monitoring module attached to the battery. FIG. 9 is a plan view showing a state in which a conventional battery monitoring module is attached to a battery. FIG. 10 is an explanatory diagram of a layout for cutting out a flexible printed wiring board used for a conventional battery monitoring module from a flexible printed wiring board material.

BEST MODE FOR CARRYING OUT THE INVENTION A mode for carrying out the present invention will be exemplarily described in detail below based on an embodiment with reference to the drawings. However, unless otherwise specified, the dimensions, materials, shapes, relative arrangements, etc. of the components described in this embodiment are not intended to limit the scope of the present invention only to them. .

(Example 1)
A battery monitoring module according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 3. FIG. The battery monitoring module according to this embodiment is preferably provided in a voltage monitoring device for monitoring the voltage of a battery mounted on an electric vehicle, for example.

<Configuration of battery monitoring module>
FIG. 1 is a plan view showing a state in which a battery monitoring module according to Embodiment 1 of the present invention is attached to a battery. FIG. 1 also shows an enlarged view of the portion surrounded by the dotted line. In the battery, a plurality of cells 10 each having a positive electrode and a negative electrode on both sides in the width direction are arranged such that the positive electrodes and negative electrodes of adjacent cells 10 are adjacent to each other. The plurality of cells 10 are configured such that adjacent positive electrodes and negative electrodes are electrically connected by bus bars 11 serving as electrodes, thereby being connected in series.

Here, the potential of the electrode composed of at least one of the positive electrode and the negative electrode is V(0), V(1), V(2), V(3) in order from the lowest to the highest. , . . . , V(2n−3), V(2n−2), V(2n−1), V(2n). Note that n is an integer. In FIG. 1, V ( ) is omitted and only numbers in ( ) are shown for potentials. As shown in FIG. 1, the potential of the electrodes is alternately increased on both sides in the width direction in the direction in which the cells are arranged (from top to bottom in FIG. 1).

A battery monitoring module 100 is attached to the top of the battery configured as described above. The battery monitoring module 100 includes a first flexible printed wiring board (hereinafter referred to as "first FPC 100A"), a second flexible printed wiring board (hereinafter referred to as "second FPC 100B"), and a third flexible printed wiring board (hereinafter referred to as “third FPC 100C”). The battery monitoring module 100 also has a connector 110 connected to the third FPC 100C. When battery monitoring module 100 is used in a voltage monitoring device mounted on an electric vehicle, connector 110 is connected to connector 51 provided in ECU 50 . In addition, in FIG. 1, only the configuration of the main part of the battery monitoring module is shown. In general, the battery monitoring module also includes a case for fixing the FPC, a temperature sensor for measuring the temperature of the battery (cell), etc., but they are omitted in FIG.

Each of the first FPC 100A, the second FPC 100B and the third FPC 100C is a single-sided FPC having a conductor (copper foil or the like) forming a plurality of wirings only on one side of the base film.

The first FPC 100A is arranged above the battery and on one side in the width direction. A plurality of first wirings 120A in the first FPC 100A are connected to electrodes having potentials of V(0), V(2), . Note that the enlarged view in FIG. 1 shows only part of the wiring.

The second FPC 100B is arranged above the battery on the other side in the width direction. A plurality of second wirings 120B in the second FPC 100B are connected to electrodes having potentials V(1), V(3), . . . , V(2n−3), V(2n−1). be.

A portion of the first FPC 100A is overlapped with the third FPC 100C, and the plurality of first wirings 120A and the plurality of third wirings 120C of the third FPC 100C are overlapped with each other. Electrically connected to each other within the region.

Further, part of the second FPC 100B is overlapped with the third FPC 100C, and the plurality of second wirings 120B and the plurality of third wirings 120C are electrically connected to each other within the region where the FPCs are overlapped. connected

More specifically, among the plurality of third wirings 120C, the leftmost third wiring 120C in FIG. Connected. Among the plurality of third wirings 120C, the second third wiring 120C from the left in FIG. 1 is electrically connected to the second wiring 120B whose potential is V(1) through a connection portion P1. be. Among the plurality of third wirings 120C, the third wiring 120C from the left in FIG. 1 is electrically connected to the first wiring 120A whose potential is V(2) through a connection portion P2. be. Furthermore, among the plurality of third wirings 120C, the fourth third wiring 120C from the left in FIG. 1 is electrically connected to the second wiring 120B whose potential is V(3) by a connection portion P3. be. Among the plurality of third wirings 120C, the fifth and subsequent third wirings 120C from the left in FIG. Each is connected to the second wiring.

, V(2n-3), V(2n-3), V(2n-3), V(2n-3), V(2n-3), V(2n-3), V(2n-3), V(2n-3), 2n-2), V(2n-1) and V(2n).

The first FPC 100A is arranged in a linear shape at the upper portion of the battery, and is configured to protrude sideways at the portion superimposed on the third FPC 100C, forming an L shape as a whole. . FIG. 2A shows a layout for cutting out the first FPC 100A from the FPC material 100AX. Since the first FPC 100A does not have a bifurcated structure as in the prior art, the area of the waste portion AX is small, and the amount of waste can be reduced.

The second FPC 100B is also configured in a straight line at the part arranged on the upper part of the battery, and is configured so as to protrude sideways at the part superimposed on the third FPC 100C, and has an L shape as a whole. . FIG. 2B shows a layout for cutting out the second FPC 100B from the FPC material 100BX. In the second FPC 100B, similarly to the first FPC 100A, the area of the waste portion BX is small, and the amount of waste can be reduced.

The third FPC 100C has a linear configuration as a whole. FIG. 2(c) shows a layout for cutting out the third FPC 100C from the FPC material 100CX. In the third FPC 100C, the amount of waste can be almost eliminated.

Since the first FPC 100A and the second FPC 100B are arranged separately in the width direction above the battery, an exhaust path is secured in the center of the battery in the width direction.

<Electrical connection>
Various known techniques can be employed for the electrical connection between the first wiring 120A and the third wiring 120C and the electrical connection between the second wiring 120B and the third wiring 120C. The configurations of the two types of electrical connections will be described below with reference to FIG. Note that FIG. 3 illustrates an electrical connection portion between the second wiring 120B and the third wiring 120C.

FIG. 3A is a schematic cross-sectional view showing the structure of an electrical connection when a through-hole type electrical connection is employed. The second FPC 100B has a base film 101
B, a conductor portion 102B (corresponding to wiring 120B) such as a copper foil provided on one surface of the base film 101B, and a cover film 103B covering the conductor portion 102B. By etching the conductor portion 102B of the material, a plurality of wirings 120B are formed, and then the cover film 103B is joined. The third FPC 100C also has the same configuration as the second FPC 100B, and includes a base film 101C, a conductor portion 102C (corresponding to the wiring 120C), and a cover film 103C. The second FPC 100B and the third FPC 100C are bonded with an adhesive (adhesive) 211. FIG. Although not shown, the configuration of the first FPC 100A is also the same.

In the third FPC 100C, the cover film 103C is provided with the through holes 103HC, thereby partially exposing the conductor portion 102C. Further, in the second FPC 100B, a through hole 100HB is provided at a position corresponding to the exposed portion of the conductor portion 102C. The conductor portion 102B and the conductor portion 102C are electrically connected by a solder portion 230 provided so as to fill the inside of the through hole 103HC and the through hole 100HB. That is, the wiring 120B and the wiring 120C are electrically connected.

In the electrical connection section described above, the solder section 230 can be obtained by printing the cream solder and then heating it in a reflow furnace. Also, the solder portion 230 can be obtained by heating with a hot press after solder plating. If the former method cannot be adopted due to restrictions on the reflow process, the latter method can be adopted to obtain the solder portion 230 by local heating.

In addition, in order to suppress the stress from acting on the electrical connection when an external force acts on the battery monitoring module 100, the adhesive ( Adhesive) 212 is desirable for bonding. As a result, rigidity is increased, and vibration resistance is also improved. Vibration resistance is further improved by fixing this reinforcing member to a case (not shown). A plate-like member or a film-like member can be used as the reinforcing member. Also, in order to suppress short circuits and deterioration of the electrical connection, it is desirable to coat the solder portion 230 with an insulating material such as a resin material (see coating portion 240).

FIG. 3(b) shows a schematic cross-sectional view of the structure of an electrical connection when a different type of electrical connection is employed. As described above, the second FPC 100B includes the base film 101B, the conductor portion 102B (corresponding to the wiring 120B), and the cover film 103B. Similarly, the third FPC 100C also includes a base film 101C, a conductor portion 102C (corresponding to the wiring 120C), and a cover film 103C. The second FPC 100B and the third FPC 100C are bonded with an adhesive (adhesive) 250. FIG.

The second FPC 100B and the third FPC 100C are provided with a through hole 100HB and a through hole 100HC that communicate with each other. A reinforcing member 260 having a pin-shaped portion 261 is provided on the surface of the third FPC 100C opposite to the joint surface with the second FPC 100B. The pin-shaped portion 261 is arranged to pass through a through hole 100HB and a through hole 100HC provided in the second FPC 100B and the third FPC 100C, respectively. The conductor portion 102B and the conductor portion 102C are electrically connected by a solder portion 270 provided so as to fill the inside of the through hole 100HB and the through hole 100HC. That is, the wiring 120B and the wiring 120C are electrically connected. Even when such a configuration is adopted, it is desirable to coat the solder portion 270 with an insulating material such as a resin material in order to suppress short circuits and deterioration of the electrical connection (see coating portion 280).

The structure shown in FIG. 3 is merely an example, and an electrical connection portion using an anisotropic conductive film (ACF), silver paste, or the like can also be employed.

<Excellent points of the battery monitoring module according to the present embodiment>
According to the battery monitoring module 100 of this embodiment, three types of single-sided FPCs having a plurality of wirings on only one side of the base film can be used to change the arrangement of the wirings. Thus, in this embodiment, it is not necessary to use a double-sided FPC, and the arrangement of wiring can be changed. In addition, it is possible to reduce the amount of discarded portions after the FPC used for the battery monitoring module is cut out from the FPC material. Further, since the connector 110 may be electrically connected to the plurality of third wirings 120C provided on one surface of the third FPC 100C, a connector (SMT connector) that is connected by surface mounting should be adopted. can be done. Therefore, cost reduction can be achieved. In the case of this embodiment, since it is not necessary to provide a folded portion in the FPC, the layout space of the FPC does not become large.

Also, the potential difference between adjacent wirings in the FPC and between adjacent terminals in the connector 110 connected to the third FPC 100C can be reduced. Therefore, it is possible to suppress the occurrence of a short circuit due to migration or the like. Moreover, the potential difference between adjacent terminals in the connector 51 provided in the ECU 50 is also reduced, and the circuit board in the ECU 50 can be simplified. It should be noted that the plurality of wirings provided on each of the first to third FPCs may employ a configuration having wirings used for purposes other than the purpose of electrically connecting to the electrodes of the battery. That is, it is also possible to employ a configuration in which the wirings provided in the first FPC 100A include wirings other than the plurality of first wirings 120A electrically connected to the electrodes of the battery. The same applies to the second wiring 120B provided on the second FPC 100B and the third wiring 120C provided on the third FPC 100C. In this case, wiring used for purposes other than connecting to the electrodes of the battery may be provided between the plurality of wirings (first to third wirings) connected to the electrodes of the battery. The relationship between the potential of the wiring used for purposes other than connecting to the battery electrodes and the potential of the plurality of wirings (first to third wirings) connected to the battery electrodes is not particularly limited. never Therefore, for example, in the third wiring 120C, a wiring used for another purpose may be provided between the wiring with the potential of V(2) and the wiring with the potential of V(3). In this case, the potential of the wiring need not be higher than V(2) and lower than V(3). Generally, in a battery monitoring module, wiring for temperature measurement is provided in addition to wiring for voltage measurement, and the potential of the wiring for temperature measurement is lower than the potential of the wiring for voltage measurement. . When the wiring for temperature measurement is provided between the wirings for voltage measurement, it is desirable to make the distance between the wirings sufficiently long in order to suppress the occurrence of migration or the like. Therefore, for example, when a wiring for temperature measurement is provided between a wiring having a potential of V(2) and a wiring having a potential of V(3), the wiring for temperature measurement and a wiring having a potential of V(2) are arranged. and the distance between the wiring for temperature measurement and the wiring whose potential is V(3).

(Example 2)
A battery monitoring module according to a second embodiment of the present invention will be described with reference to FIGS. 4 and 5. FIG. The battery monitoring module according to this embodiment is also preferably provided in a voltage monitoring device for monitoring the voltage of a battery mounted on an electric vehicle, for example.

<Configuration of battery monitoring module>
FIG. 4 is a plan view showing a state in which a battery monitoring module according to Embodiment 2 of the present invention is attached to a battery. FIG. 4 also shows an enlarged view of the portion surrounded by the dotted line. The configuration of the battery is as described in the first embodiment. As in Example 1, the potential of the electrode composed of at least one of the positive electrode and the negative electrode is V(0), V(1), V(2), V(2), V(0), V(1), V(2), V(3), . . . , V(2n−3), V(2n−2), V(2n−1), V(2n). Note that n is an integer. In FIG. 4, V ( ) is omitted and only the numbers in ( ) are shown for the potential. As shown in FIG. 4, similarly to the first embodiment, the potential of the electrodes is configured to alternately increase on both sides in the width direction in the cell arrangement direction.

A battery monitoring module 100 is attached to the top of the battery configured as described above. The battery monitoring module 100 according to this embodiment includes a first flexible printed wiring board (hereinafter referred to as "first FPC 100D") and a second flexible printed wiring board (hereinafter referred to as "second FPC 100E"). ) and The battery monitoring module 100 also has a connector 110 connected to the second FPC 100E. When battery monitoring module 100 is used in a voltage monitoring device mounted on an electric vehicle, connector 110 is connected to connector 51 provided in ECU 50 . As in the first embodiment, FIG. 4 shows only the configuration of the essential parts of the battery monitoring module.

Both the first FPC 100D and the second FPC 100E are single-sided FPCs having a conductor (copper foil or the like) forming a plurality of wirings only on one side of the base film.

The first FPC 100D is arranged on one side in the width direction above the battery. A plurality of first wirings 120D in the first FPC 100D are connected to electrodes having potentials of V(0), V(2), . Note that the enlarged view in FIG. 1 shows only part of the wiring.

The second FPC 100E is arranged above the battery on the other side in the width direction. A plurality of second wirings 120E in the second FPC 100E are connected to electrodes having potentials V(1), V(3), . . . , V(2n−3), V(2n−1). be. In the case of this embodiment, among the plurality of arranged second wirings 120E, alternate wirings (even-numbered wirings from the left in the figure) have potentials of V(1) and V(3). , .

A part of the first FPC 100D is overlapped with the second FPC 100E, and the plurality of first wirings 120D and the plurality of second wirings 120E are electrically connected to each other within the region where the FPCs are overlapped. connected The first FPC 100D is folded back at one folding portion 100bD so that a portion of the first FPC 100D overlaps the second FPC 100E. In addition, the plurality of first wirings 120D are electrically connected to alternate wirings (odd-numbered wirings from the left in the figure) in the plurality of arranged second wirings 120E.

More specifically, among the plurality of second wirings 120E, the leftmost second wiring 120E in FIG. Connected. Among the plurality of second wirings 120E, the second wiring 120E that is second from the left in FIG. 1 is directly connected to an electrode having a potential of V(1). Among the plurality of second wirings 120E, the third wiring 120E from the left in FIG. 1 is electrically connected to the first wiring 120D whose potential is V(2) through a connection portion P2. be. Furthermore, among the plurality of second wirings 120E, the fourth second wiring 120E from the left in FIG. 1 is directly connected to an electrode having a potential of V(3). Among the plurality of second wirings 120E, the fifth and subsequent odd-numbered second wirings 120E from the left in FIG. 1 also have potentials of V(4), V(6), . Each is connected to the first wiring 120D. Further, among the plurality of second wirings 120E, even-numbered second wirings 120E from the sixth left onward in FIG. 1 also have potentials of (5), V(7), .
, and V(2n-1), respectively.

, V(2n-3), V(2n-3), V(2n-3), V(2n-3), V(2n-3), 2n-2), V(2n-1) and V(2n).

The first FPC 100D has a linear configuration as a whole. FIG. 5A shows a layout for cutting out the first FPC 100D from the FPC material 100DX. In the first FPC 100D, the waste amount can be almost eliminated.

The second FPC 100E is also configured linearly as a whole. FIG. 5B shows a layout for cutting out the second FPC 100E from the FPC material 100EX. In the second FPC 100E as well, the waste amount can be almost eliminated.

Since the first FPC 100D and the second FPC 100E are arranged separately in the width direction above the battery, an exhaust path is secured in the center of the battery in the width direction.

As for the configuration of the electrical connection portion between the first wiring 120D and the second wiring 120E, in addition to the structure shown in FIG. be able to.

With the battery monitoring module 100 according to the present embodiment configured as described above, the same effect as in the case of the first embodiment can be obtained. As in the first embodiment, it is possible to employ a configuration in which the plurality of wirings provided on each of the first and second FPCs has wirings used for purposes other than the purpose of electrically connecting to the electrodes of the battery. Also in this embodiment, the connector 110 may be electrically connected to the plurality of second wirings 120E provided on one surface of the second FPC 100E. connector) can be adopted. Moreover, in the case of this embodiment, although the first FPC 100D has a folded portion at one place, it is sufficient to use two types of FPCs, so that the cost can be further reduced. In addition, in this embodiment, a folded portion is provided at one portion of the first FPC 100D, and a portion of the folded portion is overlapped with the second FPC 100E to electrically connect the first wiring 120D and the second wiring 120E. The configuration for connection is shown. However, a configuration is adopted in which a folded portion is provided at one location on the second FPC 100E, and a portion of the folded portion is overlapped with the first FPC 100D to electrically connect the first wiring 120D and the second wiring 120E. can also In this case, the potentials of the plurality of first wirings 120D are V(0), V(1), V(2), V(3), . . . , V(2n-3), V(2n-2 ), V(2n−1), and V(2n). A connector 110 is connected to the first FPC 100D.

(Example 3)
Embodiment 3 of the present invention is shown in FIG. In the configuration of Embodiment 1 above, if the number of cells to be arranged increases as the size of the battery increases, one FPC alone cannot be attached to the top of all the cells due to various reasons such as the size of the FPC material. Sometimes. Therefore, in the present embodiment, in the configuration of the first embodiment, both the first flexible printed wiring board and the second flexible printed wiring board are composed of a plurality of flexible printed wiring boards. Since other basic configurations and functions are the same as those of the first embodiment, the same components are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

FIG. 6 is a plan view showing a state in which a battery monitoring module according to Embodiment 3 of the present invention is attached to a battery. The configuration of the battery is as described in the first embodiment. The potential of the electrode composed of at least one of the positive electrode and the negative electrode is also as described in the first embodiment. Note that wiring is omitted in FIG.

The battery monitoring module 100 according to this embodiment also includes first to third flexible printed wiring boards, as in the first embodiment. In the case of this embodiment, the first flexible printed wiring board is composed of two flexible printed wiring boards (hereinafter referred to as "first FPC 100F1" and "first FPC 100F2"). The second flexible printed wiring board is also composed of two flexible printed wiring boards (hereinafter referred to as "second FPC 100G1" and "second FPC 100G2"). The battery monitoring module 100 also has a connector 110 connected to the third FPC 100H. When the battery monitoring module 100 is used in a voltage monitoring device mounted on an electric vehicle, the connector 110 is connected to a connector provided on the ECU. Note that FIG. 6 shows only the configuration of the main part of the battery monitoring module.

Each of the first FPC 100F1, the first FPC 100F2, the second FPC 100G1, the second FPC 100G2 and the third FPC 100H has a conductor (copper foil, etc.) forming a plurality of wirings only on one surface of the base film. Single-sided FPC.

As in the first embodiment, the first FPC composed of the first FPC 100F1 and the first FPC 100F2 is arranged above the battery on one side in the width direction. Regarding the fact that the plurality of first wirings in the first FPC are respectively connected to electrodes having potentials of V(0), V(2), . are also the same as in the first embodiment.

Also, the second FPC composed of the second FPC 100G1 and the second FPC 100G2 is arranged above the battery in the other widthwise direction, as in the first embodiment. A plurality of second wirings in the second FPC 100 are connected to electrodes having potentials V(1), V(3), . . . , V(2n−3), V(2n−1). The points are the same as those of the first embodiment.

In this embodiment, a portion of the first FPC 100F1 and a portion of the first FPC 100F2 are respectively superimposed on the third FPC 100H. Then, the plurality of first wirings and the plurality of third wirings in the third FPC 100H are electrically connected within the region where the FPCs are overlapped.

A part of the second FPC 100G1 and a part of the second FPC 100G2 are respectively overlapped with the third FPC 100H. Then, the plurality of second wirings and the plurality of third wirings are electrically connected within the region where the FPCs are overlapped. Which wiring is connected to which wiring is the same as in the case of the first embodiment. Thus, also in this embodiment, the potentials of the plurality of third wirings are V(0), V(1), V(2), V(3), . . . , V(2n−3), V( 2n-2), V(2n-1) and V(2n). The configuration of the electrical connection portion is as described in the first embodiment.

With the battery monitoring module 100 according to the present embodiment configured as described above, the same effect as in the case of the first embodiment can be obtained. As in the first embodiment, it is possible to employ a configuration in which a plurality of wirings provided on each of the first to third FPCs have wirings used for purposes other than the purpose of electrically connecting to the electrodes of the battery. In this embodiment, although the number of FPCs is increased, it can also be applied to a large battery. Also, in this embodiment, both the first FPC and the second FPC are configured by two FPCs. Each of the second FPCs may be composed of three or more. Note that the third FPC may also be made longer by connecting a plurality of FPCs.

(Example 4)
Embodiment 4 of the present invention is shown in FIG. In the present embodiment, as in the third embodiment, both the first flexible printed wiring board and the second flexible printed wiring board are composed of a plurality of flexible printed wiring boards in the configuration of the first embodiment. indicate the case. Since other basic configurations and functions are the same as those of the first embodiment, the same components are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

FIG. 7 is a plan view showing a state in which a battery monitoring module according to Embodiment 4 of the present invention is attached to a battery. The configuration of the battery is as described in the first embodiment. The potential of the electrode composed of at least one of the positive electrode and the negative electrode is also as described in the first embodiment. Note that wiring is omitted in FIG.

The battery monitoring module 100 according to this embodiment also includes first to third flexible printed wiring boards, as in the first embodiment. In the case of this embodiment, the first flexible printed wiring board is composed of two flexible printed wiring boards (hereinafter referred to as "first FPC 100I1" and "first FPC 100I2"). The second flexible printed wiring board is also composed of two flexible printed wiring boards (hereinafter referred to as "second FPC 100J1" and "second FPC 100J2"). The battery monitoring module 100 also has a connector 110 connected to the third FPC 100K. When the battery monitoring module 100 is used in a voltage monitoring device mounted on an electric vehicle, the connector 110 is connected to a connector provided on the ECU. Note that FIG. 7 shows only the configuration of the main part of the battery monitoring module.

The first FPC 100I1, the first FPC 100I2, the second FPC 100J1, the second FPC 100J2, and the third FPC 100K each have a conductor (copper foil, etc.) forming a plurality of wirings only on one side of the base film. Single-sided FPC.

In this embodiment, the end of the first FPC 100I1 and the end of the first FPC 100I2 are joined together, and the plurality of first wirings provided respectively are electrically connected to each other. In addition, the end of the second FPC 100J1 and the end of the second FPC 100J2 are also joined, and the plurality of second wirings provided respectively are electrically connected to each other. It should be noted that the structure described in the first embodiment can be adopted for the electrical connection portion between a plurality of wirings.

As in the first embodiment, the first FPC composed of the first FPC 100I1 and the first FPC 100I2 is arranged above the battery on one side in the width direction. Regarding the fact that the plurality of first wirings in the first FPC are respectively connected to electrodes having potentials of V(0), V(2), . are also the same as in the first embodiment.

Also, the second FPC composed of the second FPC 100J1 and the second FPC 100J2 is arranged above the battery in the other widthwise direction, as in the first embodiment. A plurality of second wirings in the second FPC are connected to electrodes having potentials of V(1), V(3), . . . , V(2n−3), V(2n−1) The points are the same as those of the first embodiment.

In this embodiment, part of the first FPC 100I1 is superimposed on the third FPC 100K. Then, the plurality of first wirings and the plurality of third wirings in the third FPC 100K are electrically connected within the region where the FPCs are overlapped.

Also, part of the second FPC 100J1 is superimposed on the third FPC 100K. Then, the plurality of second wirings and the plurality of third wirings are electrically connected within the region where the FPCs are overlapped. Which wires are to be connected to which wires is as described in the first embodiment. Thus, also in this embodiment, the potentials of the plurality of third wirings are V(0), V(1), V(2), V(3), . . . , V(2n−3), V( 2n-2), V(2n-1) and V(2n). The configuration of the electrical connection portion is as described in the first embodiment.

With the battery monitoring module 100 according to the present embodiment configured as described above, the same effect as in the case of the first embodiment can be obtained. As in the first embodiment, it is possible to employ a configuration in which a plurality of wirings provided on each of the first to third FPCs have wirings used for purposes other than the purpose of electrically connecting to the electrodes of the battery. In this embodiment, although the number of FPCs is increased, it can also be applied to a large battery. Also, in this embodiment, each of the first FPC and the second FPC is composed of two FPCs. good too. Also in the configuration of the second embodiment, as in the present embodiment, the first FPC 100D can be composed of a plurality of FPCs, and the second FPC 100E can be composed of a plurality of FPCs.

10 cell 11 bus bar 50 ECU
51 Connector 100 Battery monitoring module 100A, 100D, 100F1, 100F2, 100I1, 100I2 First FPC
100B, 100E, 100G1, 100G2, 100J1, 100J2 Second FPC
100C, 100H, 100K Third FPC
100AX, 100BX, 100CX, 100DX, 100EX Material 100HB, 100HC Through hole 100bD Folding part 101B, 101C Base film 102B, 102C Conductor part 103B, 103C Cover film 103HC Through hole 110 Connector 120A, 120D First Wiring 120B, 120E Second wiring 120C third wiring 211, 212, 250 adhesive (adhesive)
220,260 Reinforcing member 230,270 Solder part 240,280 Coating part 261 Pin-shaped part

Claims (9)

A battery in which a plurality of cells having positive and negative electrodes on both sides in the width direction are arranged so that the positive and negative electrodes of adjacent cells are adjacent to each other, and connected in series by connecting the positive and negative electrodes of adjacent cells. In the attached battery monitoring module,
The battery is configured such that the potential of an electrode composed of at least one of a positive electrode and a negative electrode increases alternately on both sides in the width direction in the cell arrangement direction,
V(0), V(1), V(2), V(3), . , V(2n−1), V(2n), then
Only one surface of the base film has a plurality of first wirings, and the plurality of first wirings have potentials of V(0), V(2), . . . , V(2n−2), a first flexible printed wiring board respectively connected to the electrodes serving as V(2n);
Only one surface of the base film has a plurality of second wirings, and the plurality of second wirings have potentials of V(1), V(3), . . . , V(2n−3), a second flexible printed wiring board connected to the electrodes that become V(2n−1);
a third flexible printed wiring board having a plurality of third wirings only on one surface of the base film;
with
A portion of the first flexible printed wiring board is superimposed on the third flexible printed wiring board, and the plurality of first wirings and the plurality of third wirings are combined with the first flexible printed wiring board and the third flexible printed wiring board. 3 are electrically connected within the region where the flexible printed wiring boards are superimposed,
A portion of the second flexible printed wiring board is superimposed on the third flexible printed wiring board, and the plurality of second wirings and the plurality of third wirings are connected to the second flexible printed wiring board and the third flexible printed wiring board. 3 flexible printed wiring boards are electrically connected to each other in the overlapped area,
The potentials of the plurality of third wirings are V(0), V(1), V(2), V(3), . . . , V(2n-3), V(2n-2), V(2n- 1) and V(2n) are arranged in the order of battery monitoring module. 2. The first flexible printed wiring board is composed of a plurality of flexible printed wiring boards, and a part of each flexible printed wiring board is overlapped with the third flexible printed wiring board. battery monitoring module. The second flexible printed wiring board is composed of a plurality of flexible printed wiring boards, and a part of each flexible printed wiring board is overlapped with the third flexible printed wiring board. battery monitoring module. 4. The battery monitoring module according to claim 1, further comprising a connector connected to the third flexible printed wiring board by surface mounting. A battery in which a plurality of cells having positive and negative electrodes on both sides in the width direction are arranged so that the positive and negative electrodes of adjacent cells are adjacent to each other, and connected in series by connecting the positive and negative electrodes of adjacent cells. In the attached battery monitoring module,
The battery is configured such that the potential of an electrode composed of at least one of a positive electrode and a negative electrode increases alternately on both sides in the width direction in the cell arrangement direction,
V(0), V(1), V
(2), V(3), ..., V(2n-3), V(2n-2), V(2n-1), V(2n), then
Only one surface of the base film has a plurality of first wirings, and the plurality of first wirings have potentials of V(0), V(2), . . . , V(2n−2), a first flexible printed wiring board respectively connected to the electrodes serving as V(2n);
Only one surface of the base film has a plurality of second wirings, and the plurality of second wirings have potentials of V(1), V(3), . . . , V(2n−3), a second flexible printed wiring board connected to the electrodes that become V(2n−1);
with
A part of one of the first flexible printed wiring board and the second flexible printed wiring board is superimposed on the other, and the plurality of first wirings and the plurality of second wirings are arranged in the first wiring. The flexible printed wiring board and the second flexible printed wiring board are electrically connected within a region where the flexible printed wiring board and the second flexible printed wiring board are overlapped,
The potentials of the plurality of first or second wirings on the other flexible printed wiring board are V(0), V(1), V(2), V(3), . . . , V(2n−3), V (2n-2), V(2n-1), and V(2n) are arranged in this order. One of the flexible printed wiring boards is folded back so that a plurality of first or second wirings are connected to the respective electrodes of the battery, while the other flexible printed wiring board is partially bent. 6. The battery monitoring module of claim 5, wherein the modules are superimposed. 7. The battery monitoring module according to claim 5, further comprising a connector connected to said other flexible printed wiring board by surface mounting. 6. The method according to claim 1, wherein the first flexible printed wiring board comprises a plurality of flexible printed wiring boards whose ends are overlapped with each other and whose wirings are electrically connected to each other. Battery monitoring module as described. 6. The method according to claim 1 or 5, wherein the second flexible printed wiring board is composed of a plurality of flexible printed wiring boards whose ends are overlapped with each other and whose wirings are electrically connected to each other. Battery monitoring module as described.

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