JP7474618B2 - Busbars and battery packs - Google Patents

Description

This disclosure relates to bus bars used in battery packs and battery packs.

Conventionally, in order to increase the output of secondary batteries, battery packs in which multiple batteries are connected in parallel or series have been used. Patent Document 1 discloses the configuration of bus bars that connect multiple batteries in parallel in such battery packs.

JP 2019-114540 A

Generally, a busbar generates heat when electricity is passed through it due to its own electrical resistance, causing the temperature to rise. Busbars through which large currents flow, such as battery packs used as power sources for electric vehicles, generate a particularly large amount of heat, raising concerns about excessive temperature rise in the busbar. Therefore, the technology of Patent Document 1 may not only deteriorate the busbar itself, but also deteriorate the connected battery, and may even cause accidents such as battery fire. For this reason, technology capable of suppressing temperature rise in the busbar has been desired.

This disclosure can be realized in the following forms:

(1) According to one embodiment of the present disclosure, a busbar is provided. In a battery pack in which a plurality of rectangular batteries having positive and negative terminals on the same plane are arranged along a first direction, and the positive and negative terminals are arranged in a staggered manner, the busbar is a busbar that connects terminals of the same polarity of the plurality of batteries to each other, and includes a plurality of terminal connection parts that are respectively connected to the plurality of terminals of the same polarity, a pair of main body parts that are connected to the plurality of terminal connection parts, extend in the first direction, and are formed parallel to each other, and a first conductive part that conducts the pair of main body parts to each other, and the busbar further includes at least one second conductive part that is formed in parallel to the first conductive part and conducts the pair of main body parts to each other. According to this embodiment of the busbar, since it includes at least one second conductive part that is formed in parallel to the first conductive part and conducts the pair of main body parts to each other, the current flow path of the busbar can be increased and the current flowing between the pair of main body parts can be dispersed. Therefore, the current density of the busbar during current flow can be reduced, and the amount of heat generated can be suppressed. This prevents the temperature of the busbar from rising excessively due to electrical resistance when electricity is passed through it.

(2) In the busbar of the above embodiment, at least one of the first conductive portion and the second conductive portion may be provided in the first direction between the terminal connection portions adjacent to each other along the first direction. According to the busbar of this embodiment, at least one of the first conductive portion and the second conductive portion is provided in the first direction between the terminal connection portions adjacent to each other along the first direction, so that the current flowing into the main body portion through the terminal connection portion or the current flowing into the terminal connection portion through the main body portion can be effectively dispersed. Therefore, the temperature rise of the busbar during current flow can be further suppressed.

(3) In the busbar of the above embodiment, a plurality of the conductive portions may be provided in the first direction between the terminal connection portions adjacent to each other along the first direction. According to the busbar of this embodiment, a plurality of conductive portions are provided in the first direction between the terminal connection portions adjacent to each other along the first direction, so that the current flowing through the terminal connection portions into the main body portion or the current flowing through the main body portion into the terminal connection portions can be more effectively dispersed. Therefore, the temperature rise of the busbar during current flow can be further suppressed.

(4) In the busbar of the above embodiment, the total number of the first conductive portions and the second conductive portions may be greater than the number of the terminal connection portions aligned along the first direction. According to the busbar of this embodiment, the total number of the first conductive portions and the second conductive portions is greater than the number of the terminal connection portions aligned along the first direction, so that the current flowing into the main body portion through the terminal connection portions or the current flowing into the terminal connection portions through the main body portion can be more effectively dispersed. Therefore, the temperature rise of the busbar during current flow can be further suppressed.

(5) In the busbar of the above embodiment, each of the pair of body portions may be connected to three or more of the terminal connection portions. According to this embodiment of the busbar, even in a configuration in which a pair of body portions are each connected to three or more terminal connection portions, which is prone to temperature rise, the busbar has a second conductive portion in addition to a first conductive portion, so that the current density can be reduced. Therefore, the temperature rise of the busbar when current is applied can be suppressed.

(6) According to another aspect of the present disclosure, a battery pack is provided. The battery pack includes the bus bar of the above aspect and the plurality of batteries. The battery pack of this aspect further includes a second conductive portion that is formed in parallel with the first conductive portion and that connects the pair of main body portions to each other, so that the current path of the bus bar can be dispersed. This allows the current density of the bus bar to be reduced when a current is applied, thereby suppressing the amount of heat generated. This allows the temperature rise of the bus bar when a current is applied to be suppressed.

(7) In the battery pack of the above embodiment, the busbar may connect the positive terminals of the batteries to each other, and the downstream terminal connection portion located most downstream in the current path of the busbar among the multiple terminal connection portions may overlap with the first conductive portion or the second conductive portion at least in the first direction. According to the battery pack of this embodiment, in the busbar connecting the positive terminals of the batteries to each other, the downstream terminal connection portion located most downstream in the current path of the busbar and the first conductive portion or the second conductive portion overlap with each other at least in the first direction. Therefore, the distance from the downstream terminal connection portion to the branch point between the main body portion and the first conductive portion or the second conductive portion can be shortened, and the distance through which a relatively large current flows in the busbar can be shortened. Therefore, the temperature rise of the busbar during current flow can be further suppressed.

(8) In the battery pack of the above embodiment, the busbar may connect the negative terminals of the batteries to each other, and the upstream terminal connection portion located most upstream in the current path of the busbar among the multiple terminal connection portions may overlap with the first conductive portion or the second conductive portion at least in the first direction. According to the battery pack of this embodiment, in the busbar connecting the negative terminals of the batteries to each other, the upstream terminal connection portion located most upstream in the current path of the busbar among the multiple terminal connection portions overlaps with the first conductive portion or the second conductive portion at least in the first direction. Therefore, the distance from the upstream terminal connection portion to the branch point between the main body portion and the first conductive portion or the second conductive portion can be shortened, and the distance through which a relatively large current flows in the busbar can be shortened. Therefore, the temperature rise of the busbar during current flow can be further suppressed.

The present disclosure can be realized in various forms, such as a secondary battery device equipped with a battery pack, a method for manufacturing a bus bar, a method for manufacturing a battery pack, etc.

FIG. 2 is a perspective view showing a schematic configuration of a battery pack. FIG. 2 is a top view showing a schematic configuration of a battery pack. FIG. 1 is a perspective view showing a schematic configuration of a battery. FIG. 4 is a perspective view showing a detailed configuration of a bus bar. FIG. 4 is a top view showing a detailed configuration of the bus bar. FIG. 6 is a view taken along the arrow A in FIG. 5 . FIG. 11 is a perspective view showing a detailed configuration of a bus bar according to a second embodiment. FIG. 11 is a top view showing a detailed configuration of a bus bar according to a second embodiment. FIG. 13 is a perspective view showing a detailed configuration of a bus bar according to a third embodiment. FIG. 13 is a top view showing a detailed configuration of a bus bar according to a third embodiment. FIG. 13 is a perspective view showing a detailed configuration of a bus bar according to a fourth embodiment. FIG. 13 is a top view showing a detailed configuration of a bus bar according to a fourth embodiment. FIG. 13 is an explanatory diagram showing a simulation of the maximum temperature. FIG. 4 is an explanatory diagram showing a simulation of the temperature distribution of the sample 1. FIG. 4 is an explanatory diagram showing a simulation of the temperature distribution of the sample 2. FIG. 13 is an explanatory diagram showing a simulation of the temperature distribution of the sample 3. FIG. 13 is an explanatory diagram showing a simulation of the temperature distribution of sample 4. FIG. 13 is an explanatory diagram showing a simulation of a current density distribution of Sample 2. FIG. 11 is an explanatory diagram showing a simulation of a current density distribution around a downstream terminal connection portion.

A. First embodiment:
FIG. 1 is a perspective view showing a schematic configuration of a battery pack 100 including a bus bar 20 according to an embodiment of the present disclosure. FIG. 2 is a top view showing a schematic configuration of the battery pack 100. A plurality of battery packs 100 are arranged side by side to be modularized as described later, and constitute a part of a secondary battery device (not shown). In this embodiment, the secondary battery device is mounted on an electric vehicle (not shown), but may be mounted on any moving body or stationary power source that uses electricity as a power source, not limited to electric vehicles. The battery pack 100 includes a plurality of rectangular batteries 10 and two bus bars 20. In addition, in FIG. 1 and FIG. 2, two conductive members 90 (described later) are illustrated together with the battery pack 100.

Figure 3 is a perspective view showing the schematic configuration of battery 10. Battery 10 in this embodiment is configured to include a lithium ion battery, but is not limited to lithium ion batteries and may be configured to include any type of secondary battery, such as a nickel-metal hydride battery. Battery 10 has a battery body 12, two negative electrode terminals 14, and two positive electrode terminals 16. That is, battery 10 in this embodiment is formed by connecting two unit batteries, each having one negative electrode terminal 14 and one positive electrode terminal 16.

The battery body 12 has a flat, approximately rectangular parallelepiped external shape. The negative terminal 14 and the positive terminal 16 are formed on the upper surface 13 of the battery body 12, protruding upward. That is, the negative terminal 14 and the positive terminal 16 are arranged on the same plane. The negative terminal 14 and the positive terminal 16 are each formed with a female screw (not shown). In the following description, in a plane parallel to the upper surface 13 of the battery body 12, the short side direction of the battery 10 is also referred to as the first direction D1, and the long side direction of the battery 10, i.e., the direction perpendicular to the first direction D1, is also referred to as the second direction D2. The two unit batteries constituting the battery 10 are connected by swapping the arrangement of the negative terminal 14 and the positive terminal 16 in the second direction D2. Thus, in the battery 10, the negative terminal 14 and the positive terminal 16 are formed side by side along the second direction D2, and the negative terminal 14 and the positive terminal 16 are formed side by side along the first direction D1. Further, on the upper surface 13 of the battery body 12, measuring terminals 18 are formed between the negative electrode terminal 14 and the positive electrode terminal 16 that are formed side by side along the second direction D2. Each measuring terminal 18 is used when measuring the intermediate potential.

1 and 2, in the battery pack 100 of this embodiment, three batteries 10 are arranged along the first direction D1, and the negative terminals 14 and the positive terminals 16 are arranged in a staggered manner. Therefore, in the battery pack 100, the negative terminals 14 and the positive terminals 16 are arranged alternately along the first direction D1. To explain the staggered arrangement in detail, at one end side (lower side in FIG. 2) of the second direction D2, the positive terminal 16 is arranged at the most end side (left side in FIG. 2) of the first direction D1, and the positive terminals 16 and the negative terminals 14 are arranged alternately toward the other end side (right side in FIG. 2) of the first direction D1. On the other hand, at the other end side (upper side in FIG. 2) of the second direction D2, the negative terminal 14 is arranged at the most end side (left side in FIG. 2) of the first direction D1, and the positive terminals 16 and the negative terminals 14 are arranged alternately toward the other end side (right side in FIG. 2) of the first direction D1. The number of batteries 10 in the battery pack 100 is not limited to three, and may be any number, such as two or four. The battery pack 100 is modularized by arranging multiple batteries 100 along the first direction D1. For convenience of illustration, only one battery pack 100 is shown in Figs. 1 and 2.

The conductive member 90 has a generally rectangular plate-like appearance in plan view with the first direction D1 as its longitudinal direction, and electrically connects adjacent battery packs 100 in series in the first direction D1. More specifically, the conductive member 90 connects the negative terminal 14 of a certain battery pack 100 to the positive terminal 16 of the battery pack 100 adjacent to the battery pack 100. The conductive member 90 has two through holes 92 formed side by side along the first direction D1, each penetrating the plate thickness direction. Each through hole 92 is used to connect the conductive member 90 to the negative terminal 14 and the positive terminal 16, as described below.

Each of the two bus bars 20 has a substantially plate-like external shape and electrically connects the three batteries 10 in parallel to each other in the assembled battery 100. One of the two bus bars 20 connects the negative terminals 14 of the batteries 10 to each other, and the other of the two bus bars 20 connects the positive terminals 16 of the batteries 10 to each other. That is, each bus bar 20 connects the terminals of the same polarity of the batteries 10 to each other. As described below, each bus bar 20 is assembled on the negative terminals 14 or positive terminals 16 of the batteries 10. The bus bar 20 (hereinafter also referred to as the negative bus bar 24) that connects the negative terminals 14 of the batteries 10 to each other and the bus bar 20 (hereinafter also referred to as the positive bus bar 26) that connects the positive terminals 16 of the batteries 10 to each other have the same configuration and are assembled opposite each other in a state of being inverted in the plate thickness direction. In the following description, the case where the bus bar 20 is the positive bus bar 26 will be described as a representative example.

Figure 4 is a perspective view showing the detailed configuration of the busbar 20. Figure 5 is a top view showing the detailed configuration of the busbar 20. Figure 6 is a view taken along the arrow A in Figure 5. The busbar 20 has a plurality of terminal connection portions 40, a pair of main body portions 50, a first conductive portion 61, and a second conductive portion 62.

The multiple terminal connections 40 are each connected to the positive terminals 16 of the batteries 10. As described above, the battery pack 100 of this embodiment includes three batteries 10, and each battery 10 has two positive terminals 16, so the bus bar 20 of this embodiment has six terminal connections 40. In other words, the bus bar 20 of this embodiment has three terminal connections 40 arranged along the first direction D1, and the bus bar 20 connects three batteries 10. Each terminal connection 40 is formed along a plane along the first direction D1 and the second direction D2, that is, along a plane parallel to the top surface 13 of the battery 10.

The pair of body parts 50 are formed parallel to each other, extending in the first direction D1. In the following description, one of the pair of body parts 50 is also referred to as the first body part 51, and the other of the pair of body parts 50 is also referred to as the second body part 52. That is, the first body part 51 and the second body part 52 are each connected to three terminal connection parts 40 arranged along the first direction D1. In other words, the first body part 51 and the second body part 52 are each formed in a straight line connecting the farthest terminal connection parts 40 among the three terminal connection parts 40 arranged along the first direction D1. In this embodiment, the dimensions of the first body part 51 and the second body part 52 along the first direction D1 are equal to each other.

The terminal connection parts 40 are formed so as to protrude from one of the pair of body parts 50 in a direction away from the other of the pair of body parts 50 along the second direction D2. More specifically, the three terminal connection parts 40 connected to the first body part 51 are formed so as to protrude from the second body part 52 in the second direction D2, and the three terminal connection parts 40 connected to the second body part 52 are formed so as to protrude from the first body part 51 in the second direction D2. Each terminal connection part 40 has a through hole 42 penetrating in the plate thickness direction. As described later, each through hole 42 is used to connect the bus bar 20 and the positive terminal 16. In the following description, the terminal connection part 40 located at the most downstream side in the current path of the bus bar 20 as the positive bus bar 26 among the multiple terminal connection parts 40 of the bus bar 20 is also called the downstream terminal connection part 44.

In the negative busbar 24, the direction of current flow is reversed. Therefore, in the negative busbar 24, the terminal connection 40 that functions as the downstream terminal connection 44 in the positive busbar 26 functions as the upstream terminal connection 45 located most upstream in the current path of the busbar 20. The downstream terminal connection 44 of the positive busbar 26 and the upstream terminal connection 45 of the negative busbar 24 are connected to each other by the conductive member 90, so that adjacent battery packs 100 in the first direction D1 are electrically connected in series.

In the following description, the terminal connection portion 40 that is located point-symmetrically with respect to the downstream terminal connection portion 44 is also referred to as the symmetric terminal connection portion 48. In this embodiment, the "point-symmetrical position" means a point-symmetrical position with the center of gravity of the busbar 20 as the center point on a plane along the first direction D1 and the second direction D2.

The pair of main body portions 50 are formed along a plane parallel to the formation surface of the terminal connection portion 40. The pair of main body portions 50 and each terminal connection portion 40 are connected via a bent portion 46. The bent portion 46 is formed along a direction approximately perpendicular to the first direction D1 and the second direction D2. In this embodiment, the dimension of the bent portion 46 along the first direction D1 is approximately equal to the dimension of the terminal connection portion 40 along the first direction D1.

The first conductive portion 61 and the second conductive portion 62 each electrically connect the pair of body portions 50 to each other. The first conductive portion 61 and the second conductive portion 62 are each formed along the second direction D2 on the same plane as the pair of body portions 50. Therefore, the second conductive portion 62 is formed in parallel to the first conductive portion 61. In the following description, the first conductive portion 61 and the second conductive portion 62 are each also simply referred to as conductive portion 60.

In this embodiment, at least one of the first conductive portion 61 and the second conductive portion 62 is provided in the first direction D1 between the terminal connection portions 40 adjacent to each other along the first direction D1. Therefore, the current flowing through the terminal connection portion 40 to the main body portion 50 or the current flowing through the main body portion 50 to the terminal connection portion 40 is effectively dispersed.

The busbar 20 and conductive member 90 of this embodiment are made of copper plate and formed by punching and bending. In this embodiment, the dimension of the conductive portion 60 in the first direction D1 is approximately the same as the dimension of the main body portion 50 in the second direction D2. In addition, the busbar 20 of this embodiment is formed to have a substantially constant thickness.

The negative busbar 24 and the positive busbar 26 shown in Figs. 1 and 2 have the same configuration as described above, and are assembled facing each other with the plates inverted in the plate thickness direction. The terminal connection portion 40 of the negative busbar 24 and the terminal connection portion 40 of the positive busbar 26 are assembled on the same plane. Therefore, the main body portion 50 of the negative busbar 24 is located below the terminal connection portion 40, and the main body portion 50 of the positive busbar 26 is located above the terminal connection portion 40. With this configuration, the negative busbar 24 and the positive busbar 26 are insulated from each other without contacting each other. In addition, when viewed from above, at least a portion of each main body portion 50 overlaps.

When assembling the battery pack 100, the negative busbar 24 is placed on the negative terminal 14 of the three batteries 10, and the positive busbar 26 is placed on the positive terminal 16. Then, the conductive member 90 is placed across the downstream terminal connection portion 44 located at the most downstream side in the current path of the positive busbar 26 and the upstream terminal connection portion 45 located at the most upstream side in the current path of the negative busbar 24. At this time, each busbar 20 and the conductive member 90 are placed in a position where the through hole 42 formed in each busbar 20 and the through hole 92 formed in the conductive member 90 correspond to the female threads formed in the negative terminal 14 and the positive terminal 16, respectively. Then, bolts (not shown) are inserted into the through holes 42, 92, and the male threads of the bolts and the female threads of each terminal 14, 16 are screwed together and fastened, so that each busbar 20 and the conductive member 90 are fixed to each terminal 14, 16 and electrically connected. In addition, each bus bar 20 and conductive member 90 may be electrically connected to each terminal 14, 16 by any method, such as welding, not limited to fastening with bolts.

In this embodiment, the conductive portion 60 of the negative busbar 24 and the conductive portion 60 of the positive busbar 26 are assembled by overlapping each other when viewed from the top-bottom direction. The conductive portion 60 is located in the first direction D1 between the negative terminal 14 and the positive terminal 16 that are adjacent to each other along the first direction D1. Note that the conductive portion 60 does not have to be located in the first direction D1 between the negative terminal 14 and the positive terminal 16 that are adjacent to each other along the first direction D1. In addition, each main body portion 50 is located in the second direction D2 between the terminals 14, 16 formed on each battery 10 and the measurement terminal 18.

The busbar 20 of the first embodiment described above includes the second conductive portion 62 that is formed in parallel to the first conductive portion 61 and that connects the pair of body portions 50 to each other. This increases the number of current paths in the busbar 20 and disperses the current flowing between the pair of body portions 50, compared to a configuration that does not include the second conductive portion 62. This reduces the current density of the busbar 20 when current is applied, thereby reducing the amount of heat generated. This prevents the temperature of the busbar 20 from rising excessively due to electrical resistance when current is applied. This in turn prevents deterioration of the busbar 20 and the battery 10 caused by the temperature rise of the busbar 20.

In addition, the second conductive portion 62 is formed in parallel with the first conductive portion 61 and connects the pair of main body portions 50 to each other, thereby increasing the mechanical strength of the busbar 20 and improving vibration resistance.

In addition, at least one of the first conductive portion 61 and the second conductive portion 62 is provided in the first direction D1 between the terminal connection portions 40 adjacent to each other along the first direction D1. This makes it possible to effectively disperse the current flowing through the terminal connection portion 40 into the main body portion 50 or the current flowing through the main body portion 50 into the terminal connection portion 40. This further suppresses the temperature rise of the busbar 20 when electricity is applied.

The pair of main body portions 50 and each terminal connection portion 40 are connected via a bent portion 46 formed along a direction approximately perpendicular to the second direction D2 and the first direction D1, respectively. Therefore, when the negative electrode bus bar 24 and the positive electrode bus bar 26 are inverted in the plate thickness direction and assembled to the battery 10, the negative electrode bus bar 24 and the positive electrode bus bar 26 do not come into contact with each other, thereby suppressing the occurrence of a short circuit.

The pair of main body parts 50 are each connected to three terminal connection parts 40. That is, the bus bar 20 has three terminal connection parts 40 arranged in a row along the first direction D1, and the bus bar 20 connects three batteries 10 in parallel. For this reason, the bus bar 20 of this embodiment tends to have a large current flow and a temperature rise compared to a bus bar that connects two batteries 10 in parallel, that is, a configuration in which a pair of main body parts 50 are each connected to two terminal connection parts 40. However, according to the bus bar 20 of this embodiment, since it has the second conductive part 62 in addition to the first conductive part 61, the current density can be reduced, and as a result, the temperature of the bus bar 20 can be prevented from rising excessively due to electrical resistance when electricity is passed through it.

B. Second embodiment:
FIG. 7 is a perspective view showing a detailed configuration of the busbar 20b of the second embodiment. FIG. 8 is a top view showing a detailed configuration of the busbar 20b of the second embodiment. The busbar 20b of the second embodiment is different from the busbar 20 of the first embodiment in that it has a pair of main body portions 50b instead of the pair of main body portions 50, and further has two second conductive portions 62b in addition to the second conductive portion 62. Since the other configurations are the same as those of the busbar 20 of the first embodiment, the same reference numerals are given to the same configurations, and detailed descriptions thereof are omitted. In the following description, the first conductive portion 61 and the second conductive portions 62, 62b are also simply referred to as conductive portions 60b, respectively. For convenience of description, the busbar 20b of this embodiment is a positive electrode busbar 26. However, it is of course possible to use the busbar 20b as a negative electrode busbar 24. In the case of using the negative electrode busbar 24, the direction of current flow is reversed, so that the downstream terminal connection portion 44 functions as the upstream terminal connection portion 45.

Compared to the pair of body parts 50 of the first embodiment, the pair of body parts 50b are formed by extending in the first direction D1, so that the positions of both ends in the first direction D1 of the first body part 51 and the second body part 52 are the same.

The two second conductive portions 62b are formed on both ends of the busbar 20b in the first direction D1. Both of the two second conductive portions 62b are formed parallel to the first conductive portion 61 along the second direction D2. Therefore, both of the two second conductive portions 62b are formed in parallel to the first conductive portion 61. In this embodiment, the pair of main body portions 50 and each of the second conductive portions 62b are connected to each other via an R-shape.

In this embodiment, the downstream terminal connection portion 44, which is located most downstream in the current path of the busbar 20b, and the second conductive portion 62b overlap each other in the first direction D1. That is, the downstream terminal connection portion 44 and the second conductive portion 62b are formed on the same straight line along the second direction D2. In other words, the downstream terminal connection portion 44 and the second conductive portion 62b overlap each other when viewed from the second direction D2.

In this embodiment, the total number of the first conductive portions 61 and the second conductive portions 62, 62b, i.e., the number of conductive portions 60b, is four, and the number of terminal connection portions 40 aligned along the first direction D1 is three. Therefore, the total number of the first conductive portions 61 and the second conductive portions 62, 62b is greater than the number of terminal connection portions 40 aligned along the first direction D1. Also, in this embodiment, the dimension of the main body portion 50b along the second direction D2 and the dimensions of the first conductive portions 61 and the second conductive portions 62, 62b along the first direction D1 are both approximately the same.

In this embodiment, the busbar 20b has a point-symmetric shape. In the busbar 20b, the second conductive portion 62b connected to the downstream terminal connection portion 44 and the second conductive portion 62b connected to the symmetric terminal connection portion 48 are located in point-symmetric positions. In this embodiment, "point-symmetric positions" refer to point-symmetric positions with the center of gravity of the busbar 20b as the center point on a plane along the first direction D1 and the second direction D2.

The busbar 20b of the second embodiment described above has the same effects as the first embodiment. In addition, since it further has the second conductive portion 62b, the current paths of the busbar 20b can be further dispersed. Therefore, the temperature rise of the busbar 20b during current flow can be further suppressed.

In addition, since the total number of the first conductive portions 61 and the second conductive portions 62, 62b is greater than the number of the terminal connection portions 40 arranged along the first direction D1, the current flowing through the terminal connection portions 40 to the main body portion 50b or the current flowing through the main body portion 50b to the terminal connection portions 40 can be more effectively dispersed. Therefore, the temperature rise of the busbar 20b during current flow can be further suppressed.

The downstream terminal connection portion 44 and the second conductive portion 62b are formed to overlap each other in the first direction D1. This shortens the distance from the downstream terminal connection portion 44 to the branch point between the main body portion 50 and the first conductive portion 61 or the second conductive portion 62, 62b, thereby shortening the distance through which a relatively large current flows within the busbar 20b. This further suppresses the temperature rise of the busbar 20b when current is applied.

The second conductive portion 62b connected to the downstream terminal connection portion 44 and the second conductive portion 62b connected to the symmetric terminal connection portion 48 are located in point symmetrical positions. Here, the negative busbar 24 and the positive busbar 26 are used by being inverted in the plate thickness direction. Therefore, the busbar 20b can be made into the negative busbar 24 simply by inverting the front and back directions. In the negative busbar 24, the downstream terminal connection portion 44 functions as the upstream terminal connection portion 45 located most upstream in the current path of the busbar 20b. Therefore, while the negative busbar 24 and the positive busbar 26 have the same configuration, in the negative busbar 24, the distance from the upstream terminal connection portion 44 to the branch point between the main body portion 50 and the first conductive portion 61 or the second conductive portion 62, 62b can be shortened, so that the distance through which a relatively large current flows in the busbar 20b can be shortened. Therefore, the temperature rise of the busbar 20b during current flow can be further suppressed.

C. Third embodiment:
FIG. 9 is a perspective view showing a detailed configuration of the busbar 20c of the third embodiment. FIG. 10 is a top view showing a detailed configuration of the busbar 20c of the third embodiment. The busbar 20c of the third embodiment differs from the busbar 20b of the second embodiment in the configuration of the terminal connection portion 40. Since the other configurations are the same as the busbar 20b of the second embodiment, the same configurations are given the same reference numerals and detailed description thereof is omitted. For convenience of explanation, the busbar 20c of this embodiment is a positive electrode busbar 26. However, it is of course possible to use the negative electrode busbar 24. In the case of using the negative electrode busbar 24, the direction of current flow is reversed, so that the downstream terminal connection portion 44c functions as the upstream terminal connection portion 45.

The busbar 20c of the third embodiment differs from the busbar 20b of the second embodiment in the configuration of the downstream terminal connection portion 44c, which is located most downstream in the current path of the busbar 20c among the six terminal connection portions 40, and the symmetrical terminal connection portion 48c, which is located point-symmetrically with respect to the downstream terminal connection portion 44c.

In this embodiment, the dimensions of the downstream terminal connection portion 44c and the symmetric terminal connection portion 48c along the first direction D1 are greater than the dimensions of the other terminal connection portions 40, excluding the downstream terminal connection portion 44c and the symmetric terminal connection portion 48c, along the first direction D1. In addition, the dimensions of the downstream terminal connection portion 44c and the symmetric terminal connection portion 48c along the first direction D1 are both greater than the dimensions of the main body portion 50b along the second direction D2. In this embodiment, the downstream terminal connection portion 44c and the symmetric terminal connection portion 48c both have their dimensions enlarged along the first direction D1 toward the side approaching the terminal connection portion 40 adjacent to the first direction D1. In addition, in this embodiment, the downstream terminal connection portion 44c and the second conductive portion 62b overlap each other in the first direction D1.

When energized, the current that flows through the busbar 20c flows from each terminal connection portion 40 through a pair of body portions 50 and the conductive portion 60b to the downstream terminal connection portion 44c. For this reason, the temperature of the busbar 20c tends to increase toward the downstream side when energized, and the temperature tends to increase most easily at the downstream terminal connection portion 44c. However, in the busbar 20c of this embodiment, the dimension of the downstream terminal connection portion 44c along the first direction D1 is large, so that the current density at the downstream terminal connection portion 44c can be reduced, and as a result, the temperature rise of the busbar 20c can be effectively suppressed.

Instead of the conductive member 90 for electrically connecting the battery pack 100 in series, a conductive member 90c that covers the entire downstream terminal connection portion 44c in the first direction D1 may be connected to the battery pack 100 including the busbar 20c of this embodiment, as shown by the dashed line in FIG. 11. The conductive member 90c has a larger dimension along the first direction D1 than the conductive member 90 connected to the battery pack 100 of the first embodiment. By connecting the conductive member 90c that covers the entire downstream terminal connection portion 44c in the first direction D1, the contact area between the downstream terminal connection portion 44c and the conductive member 90c can be further increased. Therefore, the current density of the busbar 20c can be further dispersed, and the temperature rise of the busbar 20c can be further suppressed.

The busbar 20c of the third embodiment described above has the same effects as the second embodiment. In addition, the downstream terminal connection portion 44c is formed with a large dimension along the first direction D1, so that the increase in current density at the downstream terminal connection portion 44c can be suppressed, and the temperature rise of the busbar 20c can be effectively suppressed.

In addition to the downstream terminal connection portion 44c, the busbar 20c is also formed with a large dimension along the first direction D1 for the symmetrical terminal connection portion 48c that is point-symmetrical with respect to the downstream terminal connection portion 44c. Here, the negative busbar 24 and the positive busbar 26 are used by being inverted in the plate thickness direction. Therefore, the busbar 20c can be made into the negative busbar 24 simply by inverting the front and back directions. Therefore, while the negative busbar 24 and the positive busbar 26 have the same configuration, the dimension along the first direction D1 of the upstream terminal connection portion 45 located most upstream in the current path of the busbar 20c can be made large in the negative busbar 24, and the dimension along the first direction D1 of the downstream terminal connection portion 44c located most downstream in the current path of the busbar 20c can be made large in the positive busbar 26. In other words, the busbar 20c, which is formed so that the downstream terminal connection portion 44c located at the most downstream side and the symmetrical terminal connection portion 48 located at the most upstream side in the current path of the busbar 20c as the positive electrode busbar 26 have large dimensions along the first direction D1, can be used as both the negative electrode busbar 24 and the positive electrode busbar 26.

In addition, in the embodiment in which a conductive member is connected that covers the entire downstream terminal connection portion 44c in the first direction D1, the current density of the busbar 20c can be further dispersed, thereby further suppressing the temperature rise of the busbar 20c when current is applied.

D. Fourth embodiment:
FIG. 11 is a perspective view showing a detailed configuration of the busbar 20d of the fourth embodiment. FIG. 12 is a top view showing a detailed configuration of the busbar 20d of the fourth embodiment. The busbar 20d of the fourth embodiment is different from the busbar 20b of the second embodiment in that the busbar 20d has a pair of main body portions 50d instead of the pair of main body portions 50b, and has two second conductive portions 62d instead of the two second conductive portions 62b. Since the other configurations are the same as the busbar 20b of the second embodiment, the same configurations are given the same reference numerals, and detailed descriptions thereof are omitted. In the following description, the first conductive portion 61 and the second conductive portions 62, 62d are also simply referred to as conductive portions 60d. In addition, a case where the busbar 20d is a positive electrode busbar 26 will be described as a representative example.

The pair of body parts 50d are formed to extend in the first direction D1 compared to the pair of body parts 50 of the first embodiment, and the dimension along the first direction D1 is smaller than that of the pair of body parts 50b of the second embodiment.

The two second conductive portions 62d are formed in parallel with the first conductive portion 61 near the ends of the pair of main body portions 50d in the first direction D1 that are opposite the ends extending in the first direction D1. In this embodiment, the pair of main body portions 50d and each of the second conductive portions 62d are connected to each other via an R-shape.

In this embodiment, the downstream terminal connection portion 44, which is located most downstream in the current path of the bus bar 20d as the positive electrode bus bar 26, and the second conductive portion 62d partially overlap each other in the first direction D1. In other words, the downstream terminal connection portion 44 and the second conductive portion 62d partially overlap each other when viewed from the second direction D2.

The busbar 20d of the fourth embodiment described above provides the same effects as the second embodiment.

E. Experiments:
E-1. Experiment 1
A simulation experiment was conducted on the maximum temperature and temperature distribution for the bus bars 20, 20b to 20d of the first to fourth embodiments. The simulation was conducted under boundary conditions where the total current output from each battery 10 was 200 [A] in a windless atmospheric environment at 20°C for the battery pack 100 in which the bus bars 20, 20b to 20d were assembled. Note that the maximum temperature means the maximum value of the temperature change in each of the bus bars 20, 20b to 20d, based on a state in which no current flows. The bus bars 20, 20b to 20d used in the simulation are all positive electrode bus bars 26.

<Sample>
Sample 1: bus bar 20 according to the first embodiment
Sample 2: Bus bar 20b according to the second embodiment
Samples 3 and 5: Busbar 20c according to the third embodiment
Sample 4: Bus bar 20d according to the fourth embodiment

Sample 5 is a sample in which conductive member 90c is assembled instead of conductive member 90. Note that samples 1 to 4 all have the same conductive member 90 assembled as in the first embodiment.

<Maximum temperature simulation results>
Fig. 13 is an explanatory diagram showing a simulation of the maximum temperature. In Fig. 13, the vertical axis shows the temperature change (ΔT (°C)) with respect to a state where no current is flowing as a reference. In Fig. 13, the temperature suppressed due to improved heat dissipation and the temperature suppressed due to suppressed heat generation are shown for Samples 2 to 5, respectively, with Sample 1 as a reference. The heat dissipation property of a sample is correlated with the surface area of the sample.

For example, when comparing sample 1 and sample 2, the temperature change of sample 1 was estimated to be 20.2°C, while the temperature change of sample 2 was estimated to be 11.3°C. Compared to sample 1, the temperature change of sample 2 was suppressed by 4.0°C due to improved heat dissipation caused by an increased surface area, and the temperature change was suppressed by 4.9°C due to the suppression of the amount of heat generated (reduced current density). Thus, the temperature rise of sample 2 is more suppressed than that of sample 1. Similarly, the temperature rise of samples 3 to 5 is also more suppressed than that of sample 1. The reason for this is that samples 2 to 5 further have other second conductive parts 62b and 62d in addition to the second conductive part 62 that sample 1 has. Also, samples 3 and 5, which have downstream terminal connection part 44c formed with a large dimension along the first direction D1, have a further suppressed temperature rise compared to samples 2 and 4, which have downstream terminal connection part 44 formed with a smaller dimension along the first direction D1 than downstream terminal connection part 44c. The reason for this is that downstream terminal connection part 44c, which is most likely to increase in temperature when current is applied, is formed large. Furthermore, a comparison of sample 3 and sample 5 shows that increasing the contact area between the downstream terminal connection portion 44c and the conductive member 90c can further suppress temperature rise.

<Temperature distribution simulation results>
14 to 17 are explanatory diagrams showing simulations of temperature distributions in samples 1 to 4, respectively. In Fig. 14 to 17, differences in temperature are indicated by hatching. From the results shown in Fig. 14 to 17, it can be seen that in all samples, the temperature tends to increase toward the downstream side of the current path. Furthermore, in Samples 2 to 4, the temperature increase is suppressed compared to Sample 1.

E-2. Experiment 2
A simulation experiment of the current density distribution was carried out for the same samples 2, 3, and 5 as in Experiment 1. The simulation was carried out under boundary conditions in which the total current output from each battery 10 was 200 [A] for the battery pack 100 to which the bus bars 20b and 20c were assembled, in a windless atmospheric environment at 20° C.

<Simulation results of current density distribution>
FIG. 18 is an explanatory diagram showing a simulation of the current density distribution of the sample 2. In FIG. 18, the difference in current density is indicated by hatching. In FIG. 18, the current density when the sample 2 is viewed from two directions, the front and back, is shown. In FIG. 18, the bus bar 20b viewed from the front side indicates the bus bar 20b viewed from the top side of the assembled battery 100 shown in FIG. 1, and the bus bar 20b viewed from the back side indicates the bus bar 20b viewed from the battery 10 side of the assembled battery 100 shown in FIG. 1. From the results shown in FIG. 18, it can be seen that the current density of the main body portion 50b tends to increase toward the downstream side of the current path. It can also be seen that the current density tends to increase especially around the bent portion 46 connecting the main body portion 50b and the downstream terminal connection portion 44.

Figure 19 is an explanatory diagram showing a simulation of the current density distribution around the downstream terminal connection parts 44, 44c. In Figure 19, the difference in current density is shown by hatching. In Figure 19, the periphery of the downstream terminal connection parts 44, 44c is shown enlarged in the simulation for samples 2, 3, and 5. Compared to sample 2, samples 3 and 5 have a larger dimension along the first direction D1 of the downstream terminal connection part 44c. Therefore, in samples 3 and 5, the current flowing through the main body part 50b to the downstream terminal connection part 44c and the current flowing through the second conductive part 62b to the downstream terminal connection part 44c are suppressed from being added together. In addition, in samples 3 and 5, even if the currents are added together, the distance over which the current flows is short, so an increase in the current density is suppressed. In addition, sample 5 has a reduced current density at the downstream terminal connection part 44c compared to sample 3. The reason for this is that the contact area between the downstream terminal connection portion 44c and the conductive member 90c is larger, so the current in the busbar 20c can be better dispersed.

F. Other embodiments:
F-1. Other embodiment 1:
In the above embodiments, the conductive members 90, 90c and the bus bars 20, 20b to 20d are made of copper, but they may be made of any conductive material such as aluminum, silver, etc. With such a configuration, the same effects as those of the above embodiments can be achieved.

F-2. Other embodiment 2:
In each of the above embodiments, at least one of the first conductive portion 61 and the second conductive portion 62 is provided between the terminal connection portions 40 adjacent to each other along the first direction D1, but the present disclosure is not limited thereto. For example, there may be a portion in the first direction D1 where the conductive portion 60 is not provided between the terminal connection portions 40 adjacent to each other along the first direction D1. Also, for example, there may be an aspect in which a plurality of conductive portions 60 are provided in the first direction D1 between the terminal connection portions 40 adjacent to each other along the first direction D1. According to this aspect, the current flowing into the main body portions 50, 50b, 50d through the terminal connection portion 40 or the current flowing into the downstream terminal connection portions 44, 44c through the main body portions 50, 50b, 50d can be more effectively dispersed, so that the temperature rise of the busbars 20, 20b to 20d can be further suppressed.

F-3. Other embodiment 3:
The configurations of the busbars 20, 20b to 20d in the above embodiments are merely examples and may be modified in various ways. For example, in the busbar 20c of the third embodiment, the dimension of the symmetric terminal connection portion 48c along the first direction D1 may be the same as the dimension of the other terminal connection portions 40 except for the downstream terminal connection portion 44c. Also, for example, in the busbars 20b to 20d of the second to fourth embodiments, one of the second conductive portions 62b, 62d may be omitted. Also, for example, in the busbars 20b to 20d of the second to fourth embodiments, at least one of the first conductive portion 61 and the second conductive portion 62 may be omitted. In short, it is sufficient that there are two or more bridge portions connecting a pair of main body portions 50. In other words, the busbars 20, 20b to 20d may include, in addition to the first conductive portion 61, at least one second conductive portion 62, 62b, 62d formed in parallel to the first conductive portion 61 to mutually conduct the pair of main body portions 50, 50b, 50d. In this embodiment, one of the two second conductive portions 62b, 62d corresponds to the first conductive portion in the present disclosure, and the other of the two second conductive portions 62b, 62d corresponds to the second conductive portion in the present disclosure. In this embodiment, the downstream terminal connection portion 44, 44c of the positive busbar 26 and the first conductive portion or the second conductive portion may overlap each other at least in part in the first direction D1. Similarly, the upstream terminal connection portion 45 of the negative busbar 24 and the first conductive portion or the second conductive portion may overlap each other at least in part in the first direction D1. In addition, for example, in the busbar 20d of the first, second, and fourth embodiments, the downstream terminal connection portion 44c may be formed to have a large dimension along the first direction D1, similar to the third embodiment. With such a configuration, the same effects as those of the above embodiments can be achieved.

F-4. Other embodiment 4:
The number of terminal connection parts 40 provided in each of the pair of main body parts 50, 50b, 50d does not have to be three, and may be four or more. In addition, the total number of the first conductive parts 61 and the second conductive parts 62, 62b, 62d may be any number as long as it is two or more. For example, each of the pair of main body parts 50 may be connected to four terminal connection parts 40, and may be provided with one first conductive part 61 and two second conductive parts 62 as the conductive parts 60 that conduct electricity between the pair of main body parts 50. In this case, it is preferable that at least one of the first conductive part 61 and the second conductive part 62 is provided in the first direction D1 between the terminal connection parts 40 adjacent to each other along the first direction D1. Furthermore, it is more preferable that two second conductive parts 62b, 62d are additionally provided, and the total number of the first conductive part 61 and the second conductive parts 62, 62b, 62d is greater than the number of the multiple terminal connection parts 40 arranged along the first direction D1.

The present disclosure is not limited to the above-described embodiments, and can be realized in various configurations without departing from the spirit of the present disclosure. For example, the technical features in each embodiment corresponding to the technical features in each form described in the Summary of the Invention column can be replaced or combined as appropriate to solve some or all of the above-described problems or to achieve some or all of the above-described effects. Furthermore, if a technical feature is not described in this specification as essential, it can be deleted as appropriate.

10...battery, 12...battery body, 13...upper surface, 14...negative terminal, 16...positive terminal, 18...measurement terminal, 20, 20b to 20d...busbars, 24...negative busbar, 26...positive busbar, 40...terminal connection, 42...through hole, 44, 44c...downstream terminal connection, 45...upstream terminal connection, 46...bent portion, 48, 48c...symmetrical terminal connection, 50, 50b, 50d...body, 51...first body, 52...second body, 60, 60b, 60d...conductive portion, 61...first conductive portion, 62, 62b, 62d...second conductive portion, 90, 90c...conductive member, 92...through hole, 100...battery assembly, D1...first direction, D2...second direction

Claims (8)

A bus bar is provided for connecting terminals of the same polarity of a plurality of rectangular batteries having positive and negative terminals on the same plane in a battery pack in which the positive and negative terminals are arranged in a staggered manner, the bus bar comprising:
A plurality of terminal connection parts respectively connected to the plurality of terminals of the same polarity;
a pair of main body portions each connected to the terminal connection portions and extending in the first direction and parallel to each other;
a first conductive portion that electrically connects the pair of main body portions to each other;
Equipped with
the bus bar further includes at least one second conductive portion formed in parallel to the first conductive portion and electrically connecting the pair of body portions to each other,
Busbar. The bus bar according to claim 1,
At least one of the first conductive portion and the second conductive portion is provided in the first direction between the terminal connection portions adjacent to each other along the first direction.
Busbar. The bus bar according to claim 2,
A plurality of the conductive portions are provided in the first direction between the terminal connection portions adjacent to each other along the first direction.
Busbar. The bus bar according to claim 2 or 3,
a total number of the first conductive portions and the second conductive portions is greater than a number of the terminal connection portions arranged along the first direction.
Busbar. The busbar according to any one of claims 1 to 4,
The pair of main body portions are each connected to three or more of the terminal connection portions.
Busbar. A power supply system comprising: the bus bar according to any one of claims 1 to 5; and the plurality of batteries.
Battery pack. 7. The battery pack according to claim 6,
the bus bar connects the positive terminals of the plurality of batteries to each other;
a downstream terminal connection portion located furthest downstream in a current path of the bus bar among the plurality of terminal connection portions, and the first conductive portion or the second conductive portion at least partially overlap with each other in the first direction.
Battery pack. 7. The battery pack according to claim 6,
the bus bar connects the negative terminals of the plurality of batteries to each other;
an upstream terminal connection portion located most upstream in a current path of the bus bar among the plurality of terminal connection portions, and the first conductive portion or the second conductive portion at least partially overlap with each other in the first direction.
Battery pack.

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