JP7138580B2 - assembled battery - Google Patents

Description

The present disclosure relates to assembled batteries.

2. Description of the Related Art Conventionally, a configuration is known in which, when a fuse terminal is fastened to a fuse block, a bus bar positioned outside the fuse terminal is fastened to the fuse block together with the fuse terminal (see, for example, Patent Document 1).

U.S. Patent Application Publication No. 2011/0111649

Although the bus bar functions as a washer, it may come into contact with the fuse body and apply stress to the fuse body due to its rotation during fastening.

An object of the present disclosure made in view of such a point of view is to provide an assembled battery in which the stress applied to the fuse body can be reduced.

In order to solve the above problem, an assembled battery according to a first aspect includes a fuse, a busbar, and a case. The fuse has a fuse body and a fuse terminal connected to the fuse body. The bus bar is connected to the fuse terminal. The case has a fuse holding portion that holds the bus bar and the fuse. The case has a busbar positioning portion that determines the position of the busbar. The fuse terminal is fastened to the case via the bus bar. A clearance between the busbar and the fuse body is larger than a clearance between the busbar and the busbar positioning portion.

According to the assembled battery according to the first aspect, the stress applied to the fuse body can be reduced.

1 is an external perspective view showing an example of a structure of an assembled battery according to one embodiment; FIG. It is a perspective view which shows an example of a battery cell. It is a trihedral view showing an example of a fuse. FIG. 2 is an enlarged view of a portion enclosed by a dashed line in FIG. 1; 4 is a plan view showing a configuration example of a fuse holding portion; FIG. FIG. 4 is a diagram showing an example of a configuration in which a fuse is placed on a fuse holding portion; FIG. 7 is a cross-sectional view taken along the line AA of FIG. 6; FIG. 7 is a cross-sectional view taken along the line BB of FIG. 6; It is a figure which shows an example of the structure by which the fuse and bus bar are mounted on the fuse holding|maintenance part.

An embodiment according to the present disclosure will be described below with reference to the drawings. The drawings are schematic. The dimensions, ratios, etc. on the drawings do not necessarily match the actual ones. The depiction of each component in each drawing may be partially simplified.

As shown in FIG. 1 , an assembled battery 100 according to one embodiment includes a case 110 and a holder 120 .

Assume that the assembled battery 100 according to the present embodiment is used by being mounted on a vehicle such as a vehicle having an internal combustion engine, or a hybrid vehicle that can run on the power of both the internal combustion engine and the electric motor. Assume that the assembled battery 100 according to the present embodiment is mounted on a vehicle or the like such that the positive direction of the Z axis faces upward. The assembled battery 100 may be mounted, for example, under the seat of the vehicle. The assembled battery 100 may be mounted, for example, on the center console of the vehicle. The assembled battery 100 is not limited to use in vehicles, and may be used in other applications.

The assembled battery 100 includes battery cells 150 illustrated in FIG. Battery cell 150 is provided in assembled battery 100 while being surrounded by case 110 and holder 120 . A configuration in which battery cells 150 are surrounded by case 110 and holder 120 is also called a battery module. Case 110 and holder 120 may be made of resin such as PBT (Poly-Butylene Terephthalate), for example.

As shown in FIG. 2, the battery cell 150 has a substantially rectangular parallelepiped shape with six faces. Two of the six sides of battery cell 150 have a larger area than the other four sides. Among the surfaces of the battery cell 150, the two surfaces having relatively large areas are also called flat surfaces. The battery cells 150 are arranged so that the flat surfaces are located on the positive direction side and the negative direction side of the Z axis.

Assume that in the assembled battery 100 according to the present embodiment, the battery cells 150 are divided into two stages and three stages and stacked in the Z-axis direction. That is, the assembled battery 100 is assumed to include five battery cells 150 . The number of battery cells 150 may be four or less, or may be six or more. It is assumed that the battery cells 150 stacked in two stages are arranged on the positive direction side of the Y-axis. It is assumed that the battery cells 150 stacked in three stages are arranged on the negative direction side of the Y-axis. The number of stacked battery cells 150 can be appropriately changed according to the number of battery cells 150 accommodated in the assembled battery 100 . The arrangement of the battery cells 150 is not limited to these examples, and can be changed as appropriate.

The surface of the battery cell 150 on the positive side of the X axis is also referred to as a cap surface 151 . Battery cell 150 includes positive electrode 152 and negative electrode 153 on cap surface 151 . The cap surface 151 has a substantially rectangular shape with long sides and short sides. The positive electrode 152 and the negative electrode 153 are provided near both ends of the cap surface 151 in the long side direction. The battery cell 150 can supply power to an external device or receive power supplied from an external device through the positive electrode 152 and the negative electrode 153 .

The five battery cells 150 included in the assembled battery 100 are connected in series via inter-electrode busbars. Among the electrodes of the battery cells 150 connected in series, the positive electrode 152 located at the end on the positive electrode side and the negative electrode 153 located at the end on the negative electrode side are the total positive electrode busbar 164 and the total negative electrode, respectively. It is connected to the busbar 165 . The inter-electrode busbars, total positive electrode busbars 164 and total negative electrode busbars 165 may be made of a material with high electrical conductivity such as copper or aluminum.

Battery cell 150 is housed in case 110 facing the negative direction of the X-axis. That is, the case 110 accommodates the portion of the battery cell 150 opposite to the cap surface 151 . The battery cell 150 is held by the holder 120 on the cap surface 151 side. The holder 120 is joined to the battery cell 150 with an adhesive or the like, for example. The holder 120 holds, together with the battery cell 150 , inter-electrode busbars electrically connected to the positive electrode 152 and the negative electrode 153 . The inter-electrode bus bar protrudes in the positive direction of the X-axis from the portion where the holder 120 holds the battery cell 150 .

The assembled battery 100 includes a positive terminal 250 and a negative terminal 270 . Positive electrode terminal 250 is connected to overall positive electrode bus bar 164 via positive bus bar 230 , relay 220 and fuse 240 . The positive bus bar 230 includes a first bus bar 231 , a second bus bar 232 , a third bus bar 233 and a fourth bus bar 234 . Relay 220 includes a first relay 221 and a second relay 222 . First bus bar 231 connects positive terminal 250 and fuse 240 . Second bus bar 232 connects fuse 240 and first relay 221 . The third busbar 233 connects the first relay 221 and the second relay 222 . The fourth bus bar 234 connects the second relay 222 and the total plus electrode bus bar 164 . The negative electrode terminal 270 is connected to the total negative electrode busbar 165 via the negative busbar 235 . The positive bus bar 230 and the negative bus bar 235 may be made of a material having high electrical conductivity, such as copper. It is assumed that the shape of the positive electrode bus bar 230 and the negative electrode bus bar 235 is plate-like. The shape of the positive bus bar 230 and the negative bus bar 235 may include bent portions. The positive bus bar 230 and the negative bus bar 235 are also simply referred to as bus bars.

The positive terminal 250 and the negative terminal 270 protrude in the positive direction of the Z-axis and are connectable to an external device. The assembled battery 100 can supply power discharged by the battery cells 150 to an external device or charge the battery cells 150 with the power of the external device via the positive terminal 250 and the negative terminal 270 .

Fuse 240 is shown in three views in FIG. The trihedral view shown in FIG. 3 includes a top view located on the upper left, a first side view located below the top view, and a second side view located on the right of the top view. The plan view shows the configuration of the fuse 240 viewed from the positive direction of the Z-axis. The first side view shows the configuration of the fuse 240 viewed from the positive direction of the X-axis. The second side view shows the configuration of the fuse 240 viewed from the positive direction of the Y-axis.

Fuse 240 has a fuse body 242 and fuse terminals 244 connected to opposite ends of fuse body 242 . Fuse 240 limits the current flowing from one fuse terminal 244 to the other fuse terminal 244 to a predetermined value or less. Fuse body 242 includes a fuse element that blocks current exceeding a predetermined value. Fuse terminals 244 protrude from both ends of fuse body 242 . The two fuse terminals 244 are connected to the first bus bar 231 and the second bus bar 232, respectively.

In this embodiment, the fuse body 242 is assumed to have a substantially rectangular parallelepiped shape. The fuse body 242 has a first surface 242a, a second surface 242b, a third surface 242c and a fourth surface 242d.

The first surface 242 a and the second surface 242 b correspond to the widest surfaces of the surfaces forming the outer shape of the fuse body 242 . The first surface 242a and the second surface 242b are located opposite to each other. It is assumed that when the fuse 240 is mounted on the case 110, the first surface 242a faces the positive direction of the Z axis. The first surface 242a is also referred to as a fuse top surface. It is assumed that the second surface 242b faces the negative side of the Z axis. The second surface 242b is also referred to as a fuse bottom surface.

The third surface 242c and the fourth surface 242d correspond to surfaces that intersect the first surface 242a and the second surface 242b. The fourth surface 242d corresponds to the two surfaces of the outer shape of the fuse body 242 on which the fuse terminals 244 are located. The third surface 242 c corresponds to the other two surfaces of the surfaces forming the outer shape of the fuse body 242 . The third surface 242c is also called a fuse side surface.

The fuse body 242 further has a projecting portion projecting toward the fuse terminal 244 from a portion of the fourth surface 242d. The protrusion has a fifth surface 242e that constitutes its outer shape. The fifth surface 242e corresponds to a surface that is substantially parallel to the fourth surface 242d among the surfaces that form the outer shape of the protrusion, and is located farther than the fourth surface 242d when viewed from the center of the fuse body 242. ing. The fuse terminal 244 is connected to the fuse body 242 on the fifth surface 242e. That is, the fuse terminal 244 protrudes from the fifth surface 242e. The shape of the fifth surface 242e is H-shaped as shown in the second side view shown in FIG. This improves the rigidity of the protrusion. The shape of the fifth surface 242e is not limited to the H shape, and may be other various shapes.

The shape of the fuse terminal 244 is plate-like. The fuse terminal 244 has a first surface 244a corresponding to the widest surface among the surfaces forming the outer shape of the fuse terminal 244, and a second surface 244b intersecting with the first surface 244a. The first surface 244 a is also called a plate surface of the fuse terminal 244 . The second surface 244 b is also referred to as a side surface of the fuse terminal 244 . It is assumed that when the fuse 240 is mounted on the case 110, the first surface 244a faces the positive direction side and the negative direction side of the Z axis. Fuse terminal 244 has a third surface 244c corresponding to the inner surface of the hole passing through first surface 244a. The shape of the third surface 244c may be cylindrical, but is not limited to this and may include other various shapes.

An example of a configuration in which fuse 240 is mounted on case 110 will be described with reference to FIGS. 4 to 8. FIG. Case 110 has a top surface 112 facing in the positive direction of the Z-axis. Case 110 has first fuse holding portion 410 and second fuse holding portion 420 on top surface 112 . The first fuse holding portion 410 and the second fuse holding portion 420 are also simply referred to as fuse holding portions. The two fuse retainers retain fuse terminals 244 . That is, the fuse 240 is mounted on the upper surface 112 by being held by the fuse holding portion of the case 110 . The fuse terminal 244 held by the first fuse holding portion 410 is also called a first fuse terminal. The fuse terminal 244 held by the second fuse holding portion 420 is also called a second fuse terminal.

The first fuse holding portion 410 and the second fuse holding portion 420 respectively have a first wall portion 418 and a second wall portion 428 that define their outlines. The first wall portion 418 and the second wall portion 428 are also simply referred to as walls. In FIG. 5, the first wall portion 418 and the second wall portion 428 are each shown as a configuration surrounded by dashed lines. The wall portion is located on the outer circumference of the substantially rectangular shape when viewed from the positive direction of the Z-axis. That is, the fuse holding portion has a substantially rectangular shape when viewed from the positive direction of the Z-axis. A first wall portion 418 a that is a part of the first wall portion 418 protrudes toward the second fuse holding portion 420 from the side facing the second fuse holding portion 420 . A second wall portion 428 a that is a part of the second wall portion 428 protrudes toward the first fuse holding portion 410 from the side facing the first fuse holding portion 410 .

As shown in FIG. 5 , the first fuse holding portion 410 and the second fuse holding portion 420 respectively have a first support portion 415 and a second support portion 425 that support the fuse terminals 244 . The first support portion 415 and the second support portion 425 are also simply referred to as support portions. The support portion corresponds to the surface facing the positive direction of the Z-axis. The fuse 240 is mounted on the case 110 with the fuse terminals 244 supported by the support portions. The first fuse holding portion 410 further has a first connection portion 419 that connects the first support portion 415 to the first wall portion 418 . The second fuse holding portion 420 further has a second connection portion 429 that connects the second support portion 425 to the second wall portion 428 . The first connection portion 419 and the second connection portion 429 are also simply referred to as connection portions. The connecting portion determines the positional relationship between the wall portion and the support portion.

The first fuse holding portion 410 and the second fuse holding portion 420 respectively have a first fastening portion 414 and a second fastening portion 424 . The first fastening portion 414 and the second fastening portion 424 are also simply referred to as fastening portions. The fastening portion may be included in the support portion. One fuse terminal 244 of the two fuse terminals 244 is fastened to the first fastening portion 414 by a first fastening member 281 (see FIG. 4). In other words, the first fastening member 281 fastens the fuse terminal 244 to the first fastening portion 414 . The first fastening member 281 fastens the first bus bar 231 together with the fuse terminal 244 to the first fastening portion 414 . The first bus bar 231 overlaps the fuse terminal 244 at the first fastening portion 414 . The other fuse terminal 244 is fastened to the second fastening portion 424 by a second fastening member 282 (see FIG. 4). In other words, the second fastening member 282 fastens the fuse terminal 244 to the second fastening portion 424 . The second fastening member 282 fastens the second bus bar 232 together with the fuse terminal 244 to the second fastening portion 424 . The second bus bar 232 overlaps the fuse terminal 244 at the second fastening portion 424 . The first fastening member 281 and the second fastening member 282 are also simply referred to as fastening members. The fastening member may include a threaded member such as a bolt. The fastening portion may include a threaded member such as a nut. When the fastening member is a bolt, the fastening member passes through a hole whose inner surface is the third surface 244c.

The first fuse holding part 410 has a first fuse Y positioning rib 412 . The first fuse Y positioning ribs 412 are located on the first wall portion 418a of the first wall portion 418 that protrudes in the negative direction of the X axis so as to face each other. The first fuse Y positioning rib 412 located on the side in the positive direction of the Y axis protrudes in the negative direction of the Y axis from the first wall portion 418a. The first fuse Y positioning rib 412 located on the negative side of the Y axis protrudes in the positive direction of the Y axis from the first wall portion 418a.

The second fuse holding part 420 has a second fuse Y positioning rib 422 . The second fuse Y positioning ribs 422 are positioned to face each other on a second wall portion 428a of the second wall portion 428 that protrudes in the positive direction of the X axis. The second fuse Y positioning rib 422 located on the side in the positive direction of the Y axis protrudes in the negative direction of the Y axis from the second wall portion 428a. The second fuse Y positioning rib 422 located on the negative side of the Y axis protrudes in the positive direction of the Y axis from the second wall portion 428a.

The first fuse Y positioning rib 412 and the second fuse Y positioning rib 422 are also simply referred to as fuse Y positioning ribs. The fuse Y locating rib limits movement of the fuse body 242 in the Y direction by abutting against the third surface 242c of the fuse body 242, as shown in FIGS. As a result, the fuse Y positioning ribs can determine the Y-axis position of the fuse body 242 . The fuse Y positioning rib is also referred to as the first rib. The third surface 242 c with which the first rib abuts is also called the first side surface of the fuse body 242 .

As shown in FIG. 5 , first fuse holding portion 410 has first fuse X positioning ribs 413 . The first X positioning rib 413 extends along the Y axis from the first wall portion 418b of the first wall portion 418 and is located on the negative side of the X axis. It protrudes to the direction side. At least part of the first fuse X positioning rib 413 protrudes in the positive direction of the Z-axis from the first wall portion 418b.

The second fuse holding part 420 has a second fuse X positioning rib 423 . The second X positioning rib 423 extends along the Y axis from the second wall portion 428b of the second wall portion 428 and extends in the positive direction of the X axis from the second wall portion 428b. It protrudes to the direction side. At least part of the second fuse X positioning rib 423 protrudes in the positive direction of the Z-axis from the second wall portion 428b.

The first fuse X positioning rib 413 and the second fuse X positioning rib 423 are also simply referred to as fuse X positioning ribs. The fuse X positioning ribs limit movement of the fuse body 242 in the X-axis direction by abutting against the fourth surface 242d of the fuse body 242, as shown in FIG. As a result, the fuse X positioning ribs can determine the position of the fuse body 242 along the X axis. Fuse X positioning ribs are also referred to as second ribs. The fourth surface 242 d with which the second rib abuts is also referred to as the second side surface of the fuse body 242 .

In this embodiment, case 110 has two pairs of fuse X locating ribs and two pairs of fuse Y locating ribs. The number of fuse X positioning ribs and the number of fuse Y positioning ribs are not limited to two pairs, and may be one pair, three pairs or more. The number of fuse X locating ribs and the number of fuse Y locating ribs may be different. The fuse X locating ribs and the fuse Y locating ribs may be unpaired. For example, the fuse X positioning rib may abut the fourth surface 242d at one location from the negative direction of the X axis and abut the fourth surface 242d at two locations from the positive direction of the X axis. Rotation of fuse body 242 is restricted when at least two fuse X locating ribs abut fourth surface 242d or when at least two fuse Y locating ribs abut third surface 242c. As a result, the positional accuracy of the fuse body 242 in the rotational direction is improved. That is, since at least one of the first rib and the second rib has at least two ribs, the positional accuracy of the fuse body 242 in the rotational direction is improved. The fuse X locating rib and the fuse Y locating rib are also simply referred to as fuse locating ribs.

The fuse locating ribs may be replaced with protrusions projecting from the wall. In this case, the position of the fuse body 242 is determined by the projection contacting the first side or the second side of the fuse body 242 . The fuse positioning ribs are not limited to protrusions and may be replaced with other configurations. The fuse locating ribs and their interchangeable structures are also collectively referred to as fuse locating features.

As shown in FIGS. 4 to 6 , the second fuse holding portion 420 has a first busbar positioning portion 426 and a second busbar positioning portion 427 . The first busbar positioning portion 426 and the second busbar positioning portion 427 are also simply referred to as busbar positioning portions. The first busbar positioning portion 426 extends in the X-axis direction of the second wall portion 428 and extends from a portion of the second wall portion 428c located on the positive direction side of the Y-axis to the Z-axis direction. corresponds to the portion protruding in the positive direction of . The first busbar positioning portion 426 determines the position of the second busbar 232 in the Y-axis direction. The second busbar positioning portion 427 extends in the Y-axis direction of the second wall portion 428 and extends from a portion of the second wall portion 428d located on the negative side of the X-axis toward the Z-axis. corresponds to the portion protruding in the positive direction of . The second busbar positioning portion 427 determines the position of the second busbar 232 in the X-axis direction. The first busbar positioning portion 426 and the second busbar positioning portion 427 may determine the position of the second busbar 232 by abutment of the second busbar 232 . The first busbar positioning portion 426 and the second busbar positioning portion 427 may limit the movement of the second busbar 232 in the X-axis direction and the Y-axis direction, respectively.

As shown in FIG. 4 , the second bus bar 232 is fastened to the second fuse holding portion 420 together with the fuse terminal 244 . The positional relationship between second bus bar 232 and fuse terminal 244 in second fuse holding portion 420 will be described with reference to FIG. A portion of the second bus bar 232 fastened to the second fuse holding portion 420 is also referred to as an end portion of the second bus bar 232 . The shape of the end portion of the second bus bar 232 is plate-like. The end of the second bus bar 232 has a first surface 232a corresponding to the widest surface and a second surface 232b corresponding to the inner surface of the hole passing through the first surface 232a. The shape of the second surface 232b may be cylindrical, but is not limited to this and may include other various shapes. The second fastening member 282 (see FIG. 4) passes through a hole whose inner surface is the second surface 232b of the second bus bar 232 .

The second bus bar 232 further has a third surface 232c, a fourth surface 232d and a fifth surface 232e that intersect the first surface 232a. The third surface 232 c , the fourth surface 232 d and the fifth surface 232 e are also referred to as side surfaces at the ends of the second bus bar 232 . The third surface 232c is located on the positive side of the Y axis and faces the inner surface 426a of the first busbar positioning portion 426. As shown in FIG. Assume that the clearance between the third surface 232c and the inner surface 426a is represented by C1. The fourth surface 232 d is located on the positive direction side of the X-axis and faces the fifth surface 242 e of the fuse body 242 . Assume that the clearance between the fourth surface 232d and the fifth surface 242e is represented by C2. The fifth surface 232 e is located on the negative direction side of the X axis and faces the inner surface 427 a of the second busbar positioning portion 427 .

The fuse terminal 244 overlaps the second bus bar 232 and is fastened to the second fuse holding portion 420 . The second surface 244b of the fuse terminal 244 faces the inner surface 426a of the first busbar positioning portion 426 on the positive Y-axis side. Assume that the clearance between the second surface 244b and the inner surface 426a is represented by C3.

The second bus bar 232 is fastened to the second fastening portion 424 so as to overlap the fuse terminal 244 outside when viewed from the second fuse holding portion 420 . When second fastening member 282 is a bolt, second bus bar 232 functions as a washer, which makes it difficult for torque due to fastening of the bolt to be transmitted to fuse terminal 244 . As a result, fuse 240 is less likely to fail when fastened to case 110 .

When the second bus bar 232 functions as a washer, the tightening of the bolt as the second fastening member 282 may cause the second bus bar 232 to rotate clockwise around the axis of the bolt. In this embodiment, the clearance C2 is larger than the clearance C1. That is, C2>C1 holds. When C2>C1 holds, the third surface 232c of the second busbar 232 contacts the inner surface 426a of the first busbar positioning portion 426 even if the second busbar 232 rotates clockwise. The contact of the third surface 232c with the inner surface 426a prevents the fourth surface 232d of the second bus bar 232 from contacting the fifth surface 242e of the fuse body 242 . If the second bus bar 232 rotates and contacts the fuse body 242, the fuse 240 may be damaged. By satisfying C2>C1, even if the second bus bar 232 rotates, the possibility of the fuse 240 being damaged is reduced.

Even if the second bus bar 232 functions as a washer, the fuse terminal 244 may rotate clockwise about the bolt axis. If the fuse terminal 244 rotates and contacts the inner surface 426a of the first busbar positioning portion 426, the fuse terminal 244 may be damaged. Here, even if the fuse terminal 244 rotates clockwise, the angle at which the fuse terminal 244 rotates is less than or equal to the angle at which the second bus bar 232 rotates. In this embodiment, the clearance C3 is larger than the clearance C1. That is, C3>C1 holds. When C3>C1 holds, even if the fuse terminal 244 rotates, the second surface 244b of the fuse terminal 244 does not contact the inner surface 426a. This reduces the possibility that the fuse terminal 244 will be damaged even if the fuse terminal 244 rotates.

A clearance between the second surface 244 b of the fuse terminal 244 and the inner surface 427 a may be larger than a clearance between the fifth surface 232 e of the second bus bar 232 and the inner surface 427 a of the second bus bar positioning portion 427 . In this case, even if the fuse terminal 244 rotates, the second surface 244b of the fuse terminal 244 does not contact the inner surface 426a. This reduces the possibility that the fuse terminal 244 will be damaged even if the fuse terminal 244 rotates.

At least one of the clearance between the third surface 242c of the fuse body 242 and the fuse Y positioning rib and the clearance between the fourth surface 242d of the fuse body 242 and the fuse X positioning rib is smaller than the clearance C3. may be In this way, the position of fuse 240 is determined by the position of fuse body 242 . If the position of fuse 240 is determined by the position of fuse terminal 244 , fuse terminal 244 may be damaged by contacting first busbar positioning portion 426 or second busbar positioning portion 427 . Also, in this case, stress may be applied to the fuse body 242 through the fuse terminals 244 . The stress on fuse body 242 can damage the fuse elements within fuse body 242 . In this embodiment, the location of fuse 240 is determined by the location of fuse body 242, thereby reducing the likelihood of damage to fuse terminals 244 and the likelihood of damage to the fuse element.

A space 430 is formed between the second surface 242b of the fuse body 242 and the top surface 112 of the case 110, as shown in FIGS. Space 430 corresponds to the area surrounded by second surface 242b, upper surface 112, first wall 418b, and second wall 428b. Since the fuse body 242 is in contact with the space 430 , Joule heat generated by the current flowing through the fuse body 242 is easily released to the space 430 . That is, the fuse body 242 is easily air-cooled. If the fuse body 242 were not in contact with the space 430 , heat would easily accumulate in the fuse body 242 . Due to the heat build-up in the fuse body 242, the temperature of the fuse body 242 may be higher than the temperature corresponding to the current flow. In this case, the fuse 240 cuts off current less than the predetermined current. According to this embodiment, heat is emitted from the fuse body 242 to the space 430, so that the temperature of the fuse body 242 becomes a temperature corresponding to the flowing current. In this case, the fuse 240 can cut off a predetermined current.

The space 430 communicates with the outside through an opening 440 (see FIG. 5) located between the first fuse holding portion 410 and the second fuse holding portion 420 . The first fuse holding portion 410 has an open end 411 at the end of the first wall portion 418a in the negative direction of the X axis. The second fuse holding portion 420 has an open end 421 at the end of the second wall portion 428a in the positive direction of the X axis. An opening 440 through which the space 430 communicates with the outside is formed by the open end 411 , the open end 421 and the upper surface 112 . Since the space 430 communicates with the outside through the opening 440, heat is less likely to accumulate in the space 430. - 特許庁In this case, the fuse body 242 is more easily air-cooled.

Although one embodiment according to the present disclosure has been described with reference to drawings and examples, it should be noted that various variations or modifications can be easily made by those skilled in the art based on the present disclosure. Therefore, it should be noted that these variations or modifications are included within the scope of this disclosure. For example, functions included in each means can be rearranged so as not to be logically inconsistent, and a plurality of means can be combined into one or divided.

Descriptions such as “first” and “second” in the present disclosure are identifiers for distinguishing the configurations. Configurations that are differentiated in descriptions such as "first" and "second" in this disclosure may interchange the numbers in that configuration. For example, a first busbar can exchange identifiers "first" and "second" with a second busbar. The exchange of identifiers is done simultaneously. The configurations are still distinct after the exchange of identifiers. Identifiers may be deleted. Configurations from which identifiers have been deleted are distinguished by codes. The description of identifiers such as “first” and “second” in this disclosure should not be used as a basis for interpreting the order of the configuration or the existence of lower numbered identifiers.

In the present disclosure, the X-axis, Y-axis and Z-axis are provided for convenience of explanation and may be interchanged with each other. Configurations according to the present disclosure have been described using a Cartesian coordinate system formed by X, Y and Z axes. The positional relationship of each configuration according to the present disclosure is not limited to an orthogonal relationship.

100 assembled battery 110 case 112 upper surface 120 holder 150 battery cell 151 cap surface 152 positive electrode 153 negative electrode 164 total positive electrode bus bar 165 total negative electrode bus bar 220 (221, 222) relays (first and second relays)
230 (231 to 234) positive bus bar (first to fourth bus bar)
232a to 232e 1st to 5th surfaces of the end of the second bus bar 235 Negative bus bar 240 Fuse 242 Fuse main body (242a to 242e 1st to 5th surfaces)
244 fuse terminals (244a to 244c first to third surfaces)
250 positive terminal 270 negative terminal 281, 282 first and second fastening members 410, 420 first and second fuse holding portions 411, 421 open ends 412, 422 first and second fuse Y positioning ribs 413, 423 first, Second fuse X positioning ribs 414, 424 First and second fastening parts 415, 425 First and second support parts 418 (418a-418b), 428 (428a-428d) First and second wall parts 419, 429 1, second connecting portion 426, 427 first and second busbar positioning portion 426a, 427a inner surface 430 space 440 opening

Claims (8)

a fuse having a fuse body and a fuse terminal connected to the fuse body;
a bus bar connected to the fuse terminal;
a case having a fuse holding portion that holds the bus bar and the fuse,
The case has a busbar positioning portion that determines the position of the busbar,
The fuse terminal is fastened to the case via the bus bar,
The assembled battery, wherein a clearance between the busbar and the fuse body is larger than a clearance between the busbar and the busbar positioning portion. 2. The assembled battery according to claim 1, wherein a clearance between said fuse terminal and said busbar positioning portion is larger than a clearance between said busbar and said busbar positioning portion. the case further has a fuse positioning portion that determines the position of the fuse body;
3. The assembled battery according to claim 1, wherein a clearance between said fuse terminal and said busbar positioning portion is larger than a clearance between said fuse body and said fuse positioning portion. 4. The assembled battery according to claim 3, wherein said fuse positioning portion has a rib that contacts a side surface of said fuse body. the side surface of the fuse body includes a first side surface and a second side surface that intersect with each other;
5. The assembled battery according to claim 4, wherein said rib includes a first rib that contacts said first side surface and a second rib that contacts said second side surface. The assembled battery according to claim 5, wherein the rib includes at least two of at least one of the first rib and the second rib. the fuse terminals include a first fuse terminal and a second fuse terminal;
The fuse holding portion includes a first fuse holding portion holding the first fuse terminal and a second fuse holding portion holding the second fuse terminal,
The assembled battery according to any one of claims 1 to 6, wherein the case has a space surrounded by the first fuse holding portion, the second fuse holding portion, and the fuse body. The assembled battery according to any one of claims 1 to 7, wherein the bus bar is positioned outside the fuse terminal when viewed from the fuse holding portion.

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