JP2020145161A - Battery pack - Google Patents

Abstract

To prevent swelling of a cell row.SOLUTION: In a battery pack 10 proposed here, each of a plurality of cells has a pair of flat surface portions facing each other. The cells are arranged such that the flat surface portions face each other in the adjacent cells. A holding member 26 includes a portion protruding outside a portion on which the adjacent cells are overlapped, a cavity as a holding portion that holds a spring, and a shaft insertion hole formed in the protruding portion. A tension plate 32 is bridged over end plates 28 and 30 and joined to the end plates 28 and 30 in a pulled state. A shaft 34 is inserted into the shaft insertion holes of the plurality of holding members 26.SELECTED DRAWING: Figure 1

Description

The disclosure here relates to an assembled battery.

In Japanese Patent Application Laid-Open No. 2009-026703, regarding an assembled battery in which cells (cell batteries) are laminated, an elastic member is arranged in the stacking direction of the cells, an end plate is arranged at the laminated end, and the battery is restrained by the restraining member. It is disclosed.

JP-A-2009-026703

By the way, with respect to an assembled battery in which cells are laminated, the present inventor arranges elastic members between the laminated cells, arranges end plates at both ends of the stack, and ends plates at both ends in the cell stacking direction. We are considering attaching a tension plate to the battery to restrain it. In this case, in the stacking direction of the cells, the stacked cells may be tilted due to the elastic reaction force of the elastic members stacked between the cells, and the row of cells may undulate as a whole.

The assembled battery proposed here has a pair of plane portions facing each other, and a plurality of cells arranged so that the plane portions face each other in adjacent cells, and in a direction in which the plurality of cells are arranged. , A spring arranged between at least two adjacent cells among adjacent cells and a holding portion arranged between adjacent cells in which the springs are arranged to hold the spring and the adjacent cells are overlapped with each other. A plurality of holding members having a portion protruding to the outside of the portion to be formed and a shaft insertion hole formed in the protruding portion, and a pair of ends stacked on the flat surfaces of the cells at both ends of the plurality of cells. It includes a plate, a tension plate that is stretched and joined to a pair of end plates, and a shaft that is inserted into the shaft insertion holes of a plurality of holding members.

According to such an assembled battery, the linearity of the holding member is maintained by the shaft inserted into the shaft insertion holes of the plurality of holding members, so that the row of cells is prevented from undulating.

FIG. 1 is a perspective view showing the assembled battery 10 proposed here. FIG. 2 is a perspective view of the cell 22 incorporated in the assembled battery 10. FIG. 3 is a perspective view showing a state in which the frame 22d is attached to the cell 22. FIG. 4 is a partial cross-sectional view schematically showing the structure of the assembled battery 10 in an unfolded state. FIG. 5 is a perspective view schematically showing a procedure for stacking cells 22 in order. FIG. 6 is a perspective view schematically showing a procedure for stacking cells 22 in order. FIG. 7 is a perspective view schematically showing a process in which the tension plate 32 is attached. FIG. 8 is a schematic view schematically showing how the block 12 is tilted. FIG. 9 is a schematic view schematically showing a state in which the shaft 34 is inserted. FIG. 10 is a side view schematically showing the assembled battery 10A according to another embodiment.

Hereinafter, an embodiment of the assembled battery disclosed here will be described. The embodiments described herein are, of course, not intended to specifically limit the present invention. The present invention is not limited to the embodiments described herein, unless otherwise specified.

<Assembled battery 10>
FIG. 1 is a perspective view showing the assembled battery 10 proposed here. FIG. 2 is a perspective view of the cell 22 incorporated in the assembled battery 10. FIG. 3 is a perspective view showing a state in which the frame 22d is attached to the cell 22. FIG. 4 is a partial cross-sectional view schematically showing the structure of the assembled battery 10 in an unfolded state. Note that FIG. 1 shows the state of the assembled battery 10 before the bus bar is attached.

As shown in FIGS. 1 to 4, the assembled battery 10 includes a plurality of cells 22 (see FIGS. 2 and 3), a spring 24 (see FIG. 4), a holding member 26, and a pair of end plates. It includes 28 and 30, a tension plate 32 (see FIG. 1), and a shaft 34.

<Cell 22>
As shown in FIG. 2, each of the plurality of cells 22 incorporated in the assembled battery 10 has flat surface portions 22a facing each other. The plurality of cells 22 are arranged so that the plane portions 22a of the adjacent cells 22 face each other. In this embodiment, the cell 22 is a so-called laminated cell in which a laminated film is used for the exterior that houses the electrode body. The cell 22 is not limited to a laminated cell unless otherwise specified.

In this embodiment, a flat surface portion 22a is provided in the center of the cell 22. An electrode body is housed in the center of the cell 22 provided with the flat surface portion 22a. A flat, substantially rectangular accommodation space is formed in the flat surface portion 22a. The electrode body housed in the flat surface portion 22a has a positive electrode active material layer and a negative electrode active material layer overlapped with each other. The flat surface portion 22a is orthogonal to the direction in which the positive electrode active material layer and the negative electrode active material layer are overlapped.

In this embodiment, the exterior of the cell 22 is a laminated film, which is joined by the peripheral edge portion 22b of the cell 22. Of these, on one short side of the substantially rectangular cell 22, the first electrode terminal 22b1 protrudes from the peripheral edge portion 22b. On the short side opposite to the cell 22, the second electrode terminal 22b2 protrudes from the peripheral edge portion 22b. The first electrode terminal 22b1 is a positive electrode terminal, and the second electrode terminal 22b2 is a negative electrode terminal. In this embodiment, the first electrode terminal 22b1 and the second electrode terminal 22b2 of the cell 22 are cut, and the cell 22 having a different terminal pattern is prepared.

<Frame 22d>
In this embodiment, after the first electrode terminal 22b1 and the second electrode terminal 22b2 of the cell 22 are cut, the plurality of cells 22 are each fitted with a plate-shaped frame 22d as shown in FIG. .. The frame 22d has an opening 22d1 corresponding to the flat surface portion 22a of the cell 22. The frame 22d is attached to the cell 22 by mounting the opening 22d1 on the flat surface portion 22a of the cell 22 containing the electrode body. The frame 22d protrudes from the cell 22, and guide holes 22d2 are formed at the corners of the frame 22d. As shown in FIG. 3, the cells 22 are arranged so that the plane portions 22a of the adjacent cells 22 face each other with the frame 22d attached. The first electrode terminal 22b1 and the second electrode terminal 22b2 of the cell 22 each have a required length so as to protrude from the frame 22d.

5 and 6 are perspective views schematically showing a procedure for stacking cells 22 in order. The cell 22 is superposed on the holding member 26 that holds the spring 24, as shown in FIGS. 5 and 6. Then, as shown in FIG. 4, the holding member 26 holding the spring 24 is stacked on the cell 22 stacked on the holding member 26, and a predetermined number of cells 22 are further stacked. Be done. In the assembled battery 10, the cells 22 are stacked with the holding member 26 holding the spring 24 interposed therebetween. As shown in FIG. 4, the stacked cells 22 can be separated by a holding member 26 that holds the spring 24.

Note that FIG. 4 is a development view of the assembled battery 10, and the structure of the assembled battery 10 is particularly schematically shown. Here, the holding member 26 and the cell 22 stacked on the holding member 26 are regarded as one block 12 having a unit. And it is shown so that there is a gap between the blocks 12. There is actually no such gap. Further, in FIG. 4, three blocks 12 are shown between the lower first end plate 28 and the upper second end plate 30. Further, in FIG. 4, the number of blocks 12 between the lower first end plate 28 and the upper second end plate 30 is not limited to three. In the assembled battery 10, more blocks 12 can be stacked.

<Spring 24>
The spring 24 is an elastic member. In this embodiment, a circular disc spring is used as the spring 24. The spring 24 is held by the holding member 26, respectively. Of these, the spring 24 held by the intermediate holding member 263 is arranged between at least one adjacent cell 22 in the direction in which the plurality of cells 22 are arranged, as shown in FIG. .. In this embodiment, spacers 27a and 27b are interposed between the spring 24 and the cell 22 as described later.

<Holding member 26>
The holding member 26 is a member that holds the spring 24. In this embodiment, the holding member 26 is a substantially rectangular plate-shaped member. The holding member 26 has a cavity 26a in which the spring 24 is mounted as a holding portion for holding the spring 24. The holding member 26 has a cavity 26a formed so that three springs 24 are held along the longitudinal direction of the cell 22. Further, the holding member 26 has a required size so as to protrude to the outside of the portion where the adjacent cells are overlapped.

In this embodiment, as the holding member 26, three types of holding members 26, a first holding member 261 and a second holding member 262, and an intermediate holding member 263, are used. The first holding member 261 is arranged between the cell 22 and the first end plate 28 arranged on the lower side. As shown in FIG. 4, the intermediate holding member 263 is arranged between the adjacent cells 22 of the assembled battery 10 with the spring 24 arranged. The second holding member 262 is arranged between the cell 22 and the second end plate 30 arranged on the upper side.

<End plates 28, 30>
The end plates 28 and 30 are plates arranged at both ends of the assembled battery 10. The end plates 28 and 30 are one of the restraining members that restrain each cell 22 of the assembled battery 10, respectively. Here, the lower end plate 28 is provided with a protrusion 28a for positioning the spring 24. The protrusion 28a may be provided on the end plate 28 so as to project into the cavity 26a of the first holding member 261 that is overlapped with the lower end plate 28. Similarly, the upper end plate 30 is also provided with protrusions 30a for positioning the spring 24. The protrusion 30a may be provided on the end plate 30 so as to project into the cavity 26a of the second holding member 262 that is overlapped with the upper end plate 30.

<Spacers 27a, 27b>
The spacers 27a and 27b are arranged between the intermediate holding member 263 and the cell 22, respectively. In this embodiment, a plate-shaped spacer 27a that supports the spring 24 is attached to the lower side of the intermediate holding member 263. The spacer 27a is provided with a protrusion 27a1 for positioning the spring 24. The protrusion 27a1 may be provided on the spacer 27a so as to project into the cavity 26a of the intermediate holding member 263.

A plate-shaped spacer 27b is arranged on the spring 24 held by the first holding member 261 and the intermediate holding member 263. Further, a plate-shaped spacer 27b is also arranged under the spring 24 held by the second holding member 262. Spacers of a required thickness are selectively adopted for the spacers 27a and 27b. The elastic reaction force of the compressed spring 24 acts on the block 12 of the stacked cells 22 via the spacers 27a and 27b.

<Guide shaft 27c>
The first holding member 261 and the intermediate holding member 263 have mounting holes 26b for mounting the guide shaft 27c. The mounting hole 26b is formed in a portion protruding outside the portion where adjacent cells are overlapped. The mounting holes 26b are formed on the upper surfaces of the holding members 261 and 263. The mounting hole 26b is formed so that the guide shaft 27c to be mounted is aligned with the guide hole 22d2 formed at the corner of the frame 22d mounted on the cell 22. The mounting hole 26b is formed so that the lower end of the guide shaft 27c fits snugly, and the lower end of the guide shaft 27c is press-fitted. The guide shaft 27c mounted in the mounting hole 26b is maintained in a state of standing on the first holding member 261 and the intermediate holding member 263.

A recess 26c into which the upper end of the guide shaft 27c is fitted is provided on the lower surfaces of the second holding member 262 and the intermediate holding member 263. The recess 26c has an inner diameter slightly larger than the outer diameter of the upper end of the guide shaft 27c in consideration of assembling property. Therefore, even if the guide shaft 27c mounted in the mounting hole 26b is slightly tilted, the second holding member 262 and the intermediate holding member 263 can be stacked.

Hereinafter, a procedure for stacking the cells 22 in order will be described.

As shown in FIG. 5, first, the lower end plate 28 is arranged horizontally, and the first holding member 261 is mounted on the lower end plate 28. The lower end plate 28 is provided with a protrusion 28b (see FIG. 4) for positioning the first holding member 261. Further, the end plate 28 has a protrusion 28a protruding into the cavity 26a of the first holding member 261. The spring 24 is attached to the protrusion 28a, and after the spring 24 is attached, the spacer 27b is attached to the first holding member 261. The first holding member 261 is formed with a step 26d on which the spacer 27b is mounted.

Next, as shown in FIG. 5, the guide shaft 27c is mounted and erected in the mounting hole 26b of the holding member 261. As shown in FIG. 6, the cell 22 attaches the guide hole 22d2 of the frame 22d to the guide shaft 27c attached to the holding member 26 in a state where the frame 22d is attached. As a result, the frame 22d is positioned along the guide shaft 27c. A frame 22d is attached to the cell 22. Therefore, the cells 22 are arranged while being positioned by the guide shaft 27c and the frame 22d. Therefore, the flat surface portions 22a of the adjacent cells 22 are overlapped in the stacking direction in which the cells 22 are arranged. Cooling plates 22e can be appropriately stacked between the cells 22. Further, after a predetermined number of cells 22 and the cooling plate 22e are stacked, the heat insulating plate 22f is stacked. The cooling plate 22e and the heat insulating plate 22f may have guide holes 22e1, 22f1 mounted on the guide shaft 27c. In this way, a predetermined number of cells 22 are superposed on the first holding member 261.

Next, the cell 22 stacked on the first holding member 261 is pressed. Then, the dimension (height) of the stacked cells 22 is measured. Then, as shown in FIG. 4, a spacer 27a having a required thickness is attached. The thickness of the spacer 27a is adjusted with respect to the thickness of the block 12 composed of the first holding member 261 and the cell 22 stacked on the first holding member 261. Further, the intermediate holding member 263 is overlapped, and the spring 24 is mounted in the cavity 26a of the intermediate holding member 263. Here, the spring 24 is attached to the protrusion 27a1 of the spacer 27a. Further, the spacer 27b is arranged on the intermediate holding member 263. The thickness of the block 12 composed of the first holding member 261 and the cell 22 stacked on the first holding member 261 is adjusted by adjusting the thickness after measuring the dimension (height) of the spacer 27b. You may adjust it.

Next, the guide shaft 27c is mounted in the mounting hole 26b of the intermediate holding member 263. Then, a block 12 in which a predetermined number of cells 22 are further stacked is formed on the spacer 27b stacked on the intermediate holding member 263. In the block 12, cooling plates and spacers can be appropriately stacked between the cells 22. A predetermined number of blocks 12 in which the cells 22 are stacked on the intermediate holding member 263 that holds the spring 24 in this way are stacked. Every time the cell 22 is superposed on the holding member 26, it may be pressed, the dimension (height) is measured, and the thickness of the spacer 27a or the spacer 27b may be adjusted. As a result, the height of the entire assembled battery 10 is adjusted.

After a predetermined number of blocks 12 on which the cells 22 are stacked are stacked, the upper second holding member 262, the spring 24, and the end plate 30 are stacked via the spacer 27b. The upper end plate 30 is provided with a protrusion 30b for positioning the second holding member 262.

FIG. 7 is a perspective view schematically showing a process in which the tension plate 32 is attached. As shown in FIG. 7, the upper and lower end plates 28 and 30 are pressed in the vertical direction. At this time, the spring 24 held by the holding member 26 and the stacked cells 22 are pressure-compressed as a whole between the upper and lower end plates 28 and 30. Then, the tension plate 32 is bridged over the end faces of the end plates 28 and 30 at both the upper and lower ends in the pressure-compressed state. Then, the tension plates 32 are joined to the end faces of the end plates 28 and 30 at both the upper and lower ends. The tension plate 32 is welded to the end faces along the pair of long sides of the substantially rectangular end plates 28 and 30 in a state of being bridged to each other.

If, in this state, the force of pressurizing and compressing the upper and lower end plates 28 and 30 is unloaded, the tension plate 32 is generated by the elastic reaction force of the spring 24 and the cell 22 held by the holding member 26. Tension is applied to. The tension plate 32 receives the elastic reaction force of the spring 24 held by the holding member 26 in this way, and is in a state of being pulled by the pair of end plates 28 and 30 at both ends. On the other hand, the blocks 12 in which the cells 22 are arranged in the thickness direction are each subjected to the required compressive load. Further, the block 12 in which the cells 22 are arranged in the thickness direction is maintained as one by the guide shaft 27c. The elastic reaction force of the spring 24 held by the holding member 26 acts between the blocks 12.

However, according to the knowledge of the present inventor, if the force of pressurizing and compressing the upper and lower end plates 28 and 30 is unloaded in this state, the block 12 loses its balance due to the elastic reaction force of the spring 24. In some cases. As a result, the block 12 is tilted between the end plates 28 and 30. When the block 12 is tilted, the restraining pressure acting on the cell 22 differs for each block 12, and the performance tends to vary from cell to cell 22. In particular, when the expansion and contraction of the cell 22 is large and it is necessary to apply a high restraining pressure to the cell 22, the spring 24 needs to apply a high elastic reaction force. In such a case, a high elastic reaction force acts on the block 12 by the spring 24. Therefore, when the force of pressurizing and compressing the end plates 28 and 30 at both upper and lower ends is unloaded, the block 12 tends to lose its balance and tilt.

FIG. 8 is a schematic view schematically showing how the block 12 is tilted. Note that FIG. 8 schematically shows how each block 12 tilts when the force of pressurizing and compressing the end plates 28 and 30 is unloaded. In reality, there is no number of blocks 12 or gaps between the blocks 12. As shown in FIG. 8, when the block 12 is tilted between the end plates 28 and 30, the row of the stacked cells 22 becomes undulating as a whole.

In the assembled battery 10 proposed here, as described above, the plurality of holding members 26 protrude outside the portion where the adjacent cells are overlapped, and each of the protruding portions has a shaft insertion hole 26f. There is. In this embodiment, a hollow shaft is used for the guide shaft 27c shown in FIG. Further, a shaft insertion hole 26f is formed at the bottom of the mounting hole 26b to which the guide shaft 27c is mounted. Further, in the intermediate holding member 263, the shaft insertion hole 26f penetrates the recess 26c that receives the upper end of the guide shaft 27c. Further, the second holding member 262 attached to the upper end plate 30 is formed with a shaft insertion hole 26f so as to penetrate the bottom of the recess 26c that receives the upper end of the guide shaft 27c. The upper end plate 30 has a notch 30f at a position corresponding to a portion where the shaft insertion hole 26f is formed. Therefore, the shaft insertion hole 26f is exposed when viewed from above the upper end plate 30.

FIG. 9 is a schematic view schematically showing a state in which the shaft 34 is inserted. In FIG. 9, a state in which the shaft 34 is inserted into the shaft insertion holes 26f of the plurality of hollow guide shafts 27c and the holding member 26 is schematically shown. For example, as shown in FIG. 7, the upper and lower end plates 28 and 30 are pressed in the vertical direction, and the spring 24 and the stacked cells 22 held by the holding member 26 are compressed as a whole. The components of the assembled battery 10 are assembled up to the state of being assembled. In this state, the tension plate 32 is welded to the end plates 28 and 30. After that, the shaft 34 is inserted into the hollow guide shaft 27c and the shaft insertion hole 26f of the holding member 26 from above the upper end plate 30.

Here, between the end plates 28 and 30, the shaft 34 is inserted into a hollow guide shaft 27c attached to each block 12 as shown in FIG. Further, the shaft 34 has a required length between the end plates 28 and 30 so as to be inserted into a hollow guide shaft 27c attached to each block 12. The shaft 34 may be inserted into the shaft insertion hole 26f before the tension plate 32 is welded to the end plates 28 and 30.

By inserting the shaft 34 in this way, the linearity between the blocks 12 in which the cells 22 are arranged in the thickness direction is maintained. Therefore, even if the tension plates 32 are welded to the upper and lower end plates 28 and 30 and the force of pressure-compressing the upper and lower end plates 28 and 30 is unloaded, as shown in FIG. In addition, the linearity between the blocks 12 is maintained between the end plates 28 and 30. Therefore, when the force of pressurizing and compressing the end plates 28 and 30 is unloaded, tilting of each block 12 is suppressed.

In this embodiment, the tension plate 32 is not attached to the side surface of the end plates 28, 30 on the short side side. The bus bar is attached after the tension plates 32 are joined as described above and the force of pressurizing and compressing the upper and lower end plates 28 and 30 is released. Here, on the side surface to which the tension plate 32 is not attached, the first electrode terminal 22b1 and the second electrode terminal 22b2 of the cell 22 of the assembled battery 10 are exposed. The bus bar is attached to the side surface on the short side, and connects the first electrode terminal 22b1 and the second electrode terminal 22b2 of the cell 22 with a predetermined wiring.

In this embodiment, the guide shaft 27c is a hollow shaft, and the shaft 34 is inserted through the shaft insertion hole 26f of the hollow guide shaft 27c and the holding member 26. The assembled battery 10 proposed here is not limited to such a form.

FIG. 10 is a side view schematically showing the assembled battery 10A according to another embodiment. In FIG. 10, the side surfaces of the end plates 28 and 30 as seen from the short side are drawn. In FIG. 10, it is schematically drawn in the same manner as in FIG. In the form shown in FIG. 10, the guide shaft 27c is a solid shaft. In the form shown in FIG. 10, a shaft insertion hole is formed in a corner portion of a portion protruding outside the portion where adjacent cells are overlapped, which is opposite to the side on which the mounting hole 26b to which the guide shaft 27c is mounted is formed. 26f is formed. Although not shown, shaft insertion holes 26f are formed at two positions separated along the long side of the rectangular holding member 26. A shaft insertion hole 30g is formed in the upper end plate 30 so as to match the position where the shaft insertion hole 26f is formed.

Then, as shown in FIG. 10, the end plates 28 and 30 at both upper and lower ends are pressed in the vertical direction, and the stacked cells 22 are pressurized and compressed as a whole, and the shaft insertion hole of the holding member 26 is inserted. The shaft 34 is inserted through 26f. The shaft 34 may be inserted after the tension plate 32 is welded to the end plates 28 and 30. In this way, the straightness of the shaft insertion hole 26f of the holding member 26 is maintained by the single shaft 34 inserted into the shaft insertion hole 26f of the holding member 26. Further, the shaft insertion holes 26f are formed at two positions apart from each other of the holding member 26, and the shaft 34 is inserted so that the holding member 26 can be prevented from rotating or tilting. As described above, the shaft 34 does not have to be inserted through the hollow guide shaft 27c. Further, when the shaft 34 is not inserted through the guide shaft 27c in this way, the guide shaft 27c does not have to be a hollow shaft.

As described above, the assembled batteries 10 and 10A include a plurality of cells 22, a spring 24, a holding member 26, a pair of end plates 28 and 30, a tension plate 32, and a shaft 34, respectively.

The plurality of cells 22 have a pair of flat surface portions 22a facing each other. The cells 22 are arranged so that the plane portions 22a face each other in the adjacent cells 22. The spring 24 is arranged between at least two or more adjacent cells among the adjacent cells in the direction in which the plurality of cells 22 are arranged. The holding member 26 is arranged between adjacent cells 22 in which the spring 24 is arranged. The holding member 26 has a portion protruding outside the portion on which the adjacent cells 22 are overlapped, a cavity 26a as a holding portion for holding the spring 24, and a shaft insertion hole 26f formed in the protruding portion. There is. The end plates 28 and 30 are stacked on the flat surfaces of the cells 22 at both ends of the plurality of cells 22, respectively. The tension plate 32 is bridged and joined to the end plates 28 and 30 in a pulled state. The shaft 34 is inserted into the shaft insertion holes 26f of the plurality of holding members 26.

In the assembled batteries 10 and 10A proposed here, the shaft 34 is inserted into the shaft insertion holes 26f of the plurality of holding members 26. By such a shaft 34, the linearity of the plurality of holding members 26 is maintained between the end plates 28 and 30. Therefore, the rows of the holding member 26 and the cell 22 are prevented from undulating between the end plates 28 and 30. In this way, the rows of the holding member 26 and the cell 22 are prevented from undulating, so that a required compressive load is applied to each of the cells 22. Therefore, the difference in the restraining pressure acting on the cell 22 is small, and the variation in performance for each cell 22 is small.

The assembled batteries disclosed here have been described in various ways. Unless otherwise specified, the embodiments of the assembled battery mentioned here do not limit the present invention. Further, the assembled battery disclosed herein can be variously modified, and each component and each process referred to here may be appropriately omitted or combined as appropriate, unless a particular problem occurs.

10, 10A battery pack 12 block 22 cell 22a flat surface 22b peripheral edge 22b1 first electrode terminal 22b2 second electrode terminal 22d frame 22d1 opening 22d2 guide hole 22e cooling plate 22e1 guide hole 22f heat insulating plate 22f1 guide hole 24 spring 26 holding member 26a Cavity (holding part)
26b Mounting hole 26c Recess 26d Step 26f Shaft insertion hole 27a Spacer 27a1 Protrusion 27b Spacer 27c Guide shaft 28 1st end plate 28a Protrusion 28b Protrusion 30 2nd end plate 30a Protrusion 30b Protrusion 30f Notch 30g Shaft insertion hole 32 Tension plate 34 Shaft 261 First holding member 262 Second holding member 263 Intermediate holding member

Claims (1)

A plurality of cells having a pair of plane portions facing each other and arranged so that the plane portions face each other in adjacent cells.
A spring arranged between at least two or more adjacent cells among the adjacent cells in the direction in which the plurality of cells are arranged,
A holding portion that is arranged between adjacent cells in which the spring is arranged, a portion that holds the spring, a portion that protrudes outside the portion on which the adjacent cells are overlapped, and a shaft insertion formed in the protruding portion. A plurality of holding members having holes and
A pair of end plates stacked on the flat surfaces of the cells at both ends of the plurality of cells,
A tension plate that is stretched and joined to the pair of end plates.
A shaft inserted into the shaft insertion hole of the plurality of holding members is provided.
Batteries assembled.

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