JP6657723B2 - Power storage device - Google Patents

Description

  The present invention relates to a power storage device including a plurality of unit cells.

  Conventionally, a power storage device including a plurality of unit cells arranged in a state of being arranged has been known. For example, in the case of the power storage device described in Patent Literature 1, a plurality of cells are arranged on a frame-shaped base portion. The plurality of cells are cooled by an airflow passing through the opening of the frame-shaped base.

JP 2012-204298 A

  By the way, in recent years, as a power storage device mounted on a moving body such as a vehicle, a power storage device having more cells, that is, a power storage device having a larger capacity is desired. However, in the case of a power storage device mounted on a moving object, rigidity is required. Therefore, when the power storage device includes more cells, the power storage device needs to have higher rigidity. However, when the rigidity of the power storage device is increased, the weight of the power storage device increases.

  Therefore, it is an object of the present invention to achieve higher rigidity of a power storage device including a plurality of unit cells while suppressing an increase in weight.

In order to solve the above technical problems, according to one embodiment of the present invention,
A base part,
And a plurality of cells arranged on the base portion,
The base part is
A battery holder in which a plurality of cells are arranged;
A first rib protruding from the battery holding portion to the anti-unit cell side,
An energy storage device is provided in which an opening is formed in a battery holding portion of a base portion.

  According to such a first aspect of the present invention, by providing the first rib, it is possible to realize a base portion which is lightweight, has high rigidity, and has an opening for cooling a unit cell. . As a result, the power storage device including the base portion can achieve higher rigidity while suppressing an increase in weight. Note that the first rib also functions as a radiation fin. That is, it serves to release the heat transferred to the unit cell base to the outside. Thereby, the unit cells can be cooled. Further, since the first rib protrudes from the battery holding portion of the base portion to the side opposite to the unit cell, the degree of freedom of arrangement of the plurality of unit cells on the battery holding portion is high. Therefore, the number or size of the unit cells that can be arranged on the battery holding unit increases. Therefore, the energy density of the power storage device increases.

According to a second aspect of the present invention,
The first rib is cut and raised,
The power storage device according to the first aspect, wherein the opening is a through hole formed by cutting and raising the power storage device.

  According to the second aspect of the present invention, the first rib and the opening can be formed at the same time. Further, the first rib functions as a guide for guiding the airflow into the opening.

According to a third aspect of the present invention,
The power storage device according to the first or second aspect is provided, wherein the base portion is provided along a peripheral edge of the battery holding portion and includes a frame-shaped second rib protruding toward the non-unit cell side.

  According to such a third aspect of the present invention, the rigidity of the base portion is further improved, whereby the rigidity of the power storage device is also improved.

According to a fourth aspect of the present invention,
A power storage device according to a third aspect is provided, in which the first rib and the second rib of the base portion have the same protruding height.

  According to the fourth aspect of the present invention, the weight of the plurality of cells arranged in the battery holding portion of the base portion can be supported by both the first rib and the second rib.

According to a fifth aspect of the present invention,
The power storage device according to the third or fourth aspect is provided, in which the first rib is located at the center of the portion of the battery holding portion surrounded by the second rib.

  According to the fifth aspect of the present invention, since the first rib is located at the center of the battery holding portion of the large flexible base portion, it is possible to suppress the occurrence of the large bending.

According to a sixth aspect of the present invention,
The power storage device according to any one of the first to fifth aspects, wherein the opening is formed in the battery holding portion of the base portion such that the opening faces each of the plurality of gaps between the plurality of unit cells. .

  According to the sixth aspect of the present invention, the opening for cooling the unit cell is provided at the pinpoint at the position of the base unit facing each of the plurality of gaps between the unit cells. Thereby, formation of the opening in the base portion can be suppressed to a minimum, and as a result, the rigidity of the base portion can be sufficiently ensured.

According to a seventh aspect of the present invention,
A power storage device according to a sixth aspect is provided, wherein the opening is formed so that the longitudinal direction thereof is parallel to the longitudinal direction of the unit cell.

  According to the seventh aspect of the present invention, when the longitudinal direction of the opening of the base portion is not parallel to the longitudinal direction of the unit cells, that is, the longitudinal direction of the gap between the unit cells, but is in a twisted positional relationship. Most of the airflow that has passed through the opening of the base portion flows into the gap between the unit cells. As a result, the cooling performance of the unit cell is improved.

According to an eighth aspect of the present invention,
A cover portion that covers the plurality of cells arranged in the battery holding portion of the base portion,
A power storage device according to a sixth or seventh aspect, wherein the cover portion includes a plurality of openings facing the plurality of openings of the base portion.

  According to the eighth aspect of the present invention, it is possible to generate an airflow from the opening of the base to the opening of the cover in the gap between the unit cells. Each of the cells can be cooled by this airflow.

According to a ninth aspect of the present invention,
The power storage device according to an eighth aspect is provided, wherein the opening area of the opening of the cover portion is smaller than the opening area of the opening of the base portion.

  According to the ninth aspect of the present invention, a part of the airflow that has passed through the opening of the base portion flows around the cell without immediately going outside through the opening of the cover portion. As a result, the unit cell is further cooled.

  ADVANTAGE OF THE INVENTION According to this invention, by providing a 1st rib, it is lightweight and can have high rigidity, and can implement | achieve the base part provided with the opening for cooling a cell. As a result, the power storage device including the base portion can achieve higher rigidity while suppressing an increase in weight.

1 is a perspective view of a power storage device according to one embodiment of the present invention. FIG. 1 is a perspective view showing the back side of a power storage device. Exploded perspective view of a power storage device Exploded view of battery module Plan view showing electrical connection of multiple cells Perspective view of a unit cell with first and second caps attached. FIG. 6A is a further perspective view of the unit cell with the first and second caps attached, as viewed from a different direction from FIG. 6A. Perspective view of a second cap FIG. 6A is a perspective view of the second cap viewed from a different direction from FIG. 6A. Perspective view of base portion of power storage device FIG. 7A is a perspective view of a base portion of the power storage device viewed from a direction different from that of FIG. 7A. Cross section of power storage device Layout diagram of multiple openings in the base Sectional view of adjacent second caps Sectional view of different form of second cap

  Hereinafter, a power storage device according to one embodiment of the present invention will be described with reference to the drawings.

  1A and 2 are perspective views of a power storage device according to one embodiment of the present invention. FIG. 3 is an exploded view of the power storage device. In order to facilitate understanding of the present invention, an XYZ coordinate system including an X axis, a Y axis, and a Z axis that are orthogonal to each other is defined. The X-axis direction indicates the width direction of the power storage device, the Y-axis direction indicates the depth direction, and the Z-axis direction indicates the height direction. In this specification, “upper” and “lower” indicate “upper” and “lower” in the drawings, and an “upper” element always exists above a “lower” element. It is not limited to using the power storage device according to the present invention in the state.

As shown in FIGS. 1 to 3, the power storage device 10 has a substantially rectangular parallelepiped shape, and has a battery module 12 therein. A plurality of power storage devices 10 are mounted side by side on a lower part of a railway vehicle, for example, to store regenerative energy as electricity.

  As shown in FIG. 3, the battery module 12 includes a plurality of cells 14. In the case of the present embodiment, the battery module 12 is configured by arranging 12 unit cells 14 in two rows in the depth direction (Y-axis direction).

  FIG. 4 is an exploded view of the battery module 12. As shown in FIG. 4, each of the cells 14 has a substantially rectangular parallelepiped shape, and a positive terminal 14 a and a negative terminal 14 b as external terminals are connected to one end face (upper end face) in the height direction (Z-axis direction). 14c. In the width direction (X-axis direction), the depth direction (Y-axis direction), and the height direction (Z-axis direction), the size in the width direction is the largest, and the size in the depth direction is the smallest.

  As shown in FIGS. 4 and 5, in the battery module 12, a plurality of cells 14 are electrically connected in series to form a series circuit. Specifically, each of the positive electrode terminal 14a and the negative electrode terminal 14b of the plurality of unit cells 14 is connected to the adjacent positive electrode terminal 14a and negative electrode terminal 14b of another unit cell 14 via a metal plate 16 made of a copper material or the like. It is electrically connected. In the series circuit of the battery module 12, the negative terminal 14b of one cell 14 (14A) and the positive terminal 14a of the other cell 14 (14B) located at the respective ends are connected to a device external to the power storage device 10 (for example, An extraction terminal 18 for electrical connection with the power storage device 10) is attached.

  As shown in FIGS. 3 to 7, the positive terminal 14 a and the negative terminal 14 b of each unit cell 14 are covered and protected by the first cap 20. Specifically, the first caps 20 are made of a resin material, and are provided two for each of the unit cells 14. One first cap 20 is attached to the corner of the unit cell 14 on the positive electrode terminal 14a side so as to cover the corner. The other first cap 20 is attached to the corner of the unit cell 14 on the side of the negative electrode terminal 14b so as to cover the corner. Note that the two first caps 20 attached to the respective cells 14 are separate bodies, but may be integrated.

  As shown in FIGS. 3 to 7, each cell 14 has one end (upper end) in the height direction (Z-axis direction) where the positive electrode terminal 14 a and the negative electrode terminal 14 b are provided. A second cap 22 is attached to the other end (lower end) of the cell 14 on the opposite side.

  The second cap 22 is made of a resin material like the first cap 20. However, unlike the first cap 20, the second cap 22 covers the lower end of the cell 14 over the entire width direction (X-axis direction) and the depth direction (Y-axis direction). Further details of the second cap 22 will be described later.

  As shown in FIGS. 1 to 3, the power storage device 10 includes a base 24 that holds a plurality of cells 14 (battery modules 12), and a cover 26 that covers the cells 14 held by the base 24. And In the case of the present embodiment, the plurality of cells 14 (battery modules 12) are sandwiched (held) between the base 24 and the cover 26. The base portion 24 and the cover portion 26 are supported by the side portions 28, 30 by fixing both ends in the width direction (X-axis direction) to the side portions 28, 30.

  The cover portion 26 is a member formed by, for example, sheet metal pressing a thin metal plate, and holds the first cap 20 attached to each of the unit cells 14. Specifically, each of the first caps 20 is provided with a columnar engaging portion 20a protruding in the height direction (Z-axis direction). On the other hand, a plurality of engagement holes 26a through which the engagement portions 20a of the plurality of first caps 20 can be inserted are formed in the cover 26.

  The base portion 24 is a member formed by, for example, sheet metal pressing a thin metal plate, and holds the second cap 22 attached to each of the unit cells 14. Specifically, as shown in FIGS. 2 and 6 to 9, and particularly as shown in FIG. 9, the lower ends (the positive electrode terminal 14 a and the negative electrode terminal) of the unit cell 14 in the height direction (Z-axis direction). At the bottom 22a of the second cap 22 facing the upper end (the end opposite to the upper end where the 14b is provided), two columnar engaging portions 22b protruding in the height direction are provided. . On the other hand, as shown in FIGS. 2 and 10 to 11, the base portion 24 allows the engaging portions 22 b of the plurality of second caps 22 to pass through the battery holding portion 24 a holding the plurality of unit cells 14. And a plurality of engaging holes 24b.

  The engaging portion 20a of each of the first caps 20 is inserted into the engaging hole 26a of the cover portion 26, and the engaging portion 22b of each of the second caps 22 is inserted into the engaging hole 24b of the base portion 24. . As a result, the unit cell 14 with the first cap 20 and the second cap 22 attached is sandwiched between the cover 26 and the base 24.

  Note that the base portion 24 that holds the plurality of unit cells 14 via the second cap 22 functions as a base of the power storage device 10 and greatly contributes to the rigidity of the entire power storage device 10. Therefore, the base portion 24 is configured to suppress the deformation.

  Specifically, as shown in FIGS. 3, 10, and 11, the base portion 24 extends from the periphery of the battery holding portion 24 a that holds the plurality of unit cells 14 to the anti-unit cell side (the unit cell 14 does not exist). The second rib 24c has a frame-like second rib 24c protruding to the side (side) and a first rib 24d protruding from the battery holding portion 24a surrounded by the second rib 24c to the non-unit cell side. For example, the second rib 24c is formed by bending and raising the periphery of a thin metal plate. Further, for example, the first rib 24d is formed by cutting and raising.

  The frame-shaped second ribs 24c and the first ribs 24d provided inside the second ribs 24c suppress the bending deformation of the base portion 24 due to the weight of the plurality of cells 14 on the battery holding portion 24a, and also reduce the base. The weight of the portion 24 can be reduced (compared to a case where the ribs 24c and 24d are not provided).

  When the base portion 24 is configured without providing the first rib 24d and the second rib 24c, the base portion 24 needs to be made of a metal plate having a thickness that does not deform due to the weight of the plurality of cells 14. . However, in that case, the weight of base portion 24 increases, and as a result, the weight of power storage device 10 increases. The power storage device 10 whose weight has increased is not suitable for being mounted on a moving body such as a vehicle.

  On the other hand, by providing the first rib 24d and the second rib 24c, the base portion 24 is made of a lightweight thin metal plate, and has sufficient rigidity (flexural rigidity and bending rigidity) with respect to the weight of the plurality of cells 14. Can be secured. Further, as shown in FIG. 2, the rigidity of the base portion 24 in which a plurality of through holes (an engagement hole 24b and a ventilation opening (opening) 24e described later) is formed can be improved. Accordingly, a highly rigid and lightweight power storage device 10 suitable for mounting on a moving body such as a vehicle can be realized.

  Note that, as shown in FIG. 11, the first rib 24d is preferably provided at the center of the portion of the base portion 24 surrounded by the large and easily deflectable second rib 24c. When the base 24 is long in one direction, the first rib 24d preferably extends in the longitudinal direction of the base 24. In the case of the present embodiment, the first rib 24d extends in the width direction (X-axis direction).

  When the power storage device 10 is used by being placed on a flat surface, the frame-shaped second rib 24c and the first rib 24d provided inside the second rib 24c have a protruding height from the battery holding portion 24a. Preferably they are equal. Thus, the weight of the plurality of cells 14 on the battery holding portion 24a of the base portion 24 can be supported not only by the second rib 24c but also by the first rib 24d. As a result, the deformation of the base portion 24 can be further suppressed.

  Furthermore, the first ribs 24d and the second ribs 24c not only suppress deformation of the base portion 234, but also function as radiation fins. That is, it serves to release the heat transferred from the cell 14 to the base 24 to the outside. Thereby, the base portion 24 functions as a heat sink having excellent heat dissipation, and can cool the unit cells 14.

  In addition, since the first rib 24d protrudes from the battery holding portion 24a of the base portion 24 toward the anti-unit cell side (the side where the unit cell 14 does not exist), the first rib 24d is formed on the battery holding unit 24a of the plurality of unit cells 14. High degree of freedom in arrangement (compared to the case where the first rib 24d protrudes toward the unit cell). Therefore, the number or size of the unit cells 14 that can be arranged on the battery holding unit 24a increases. Therefore, the energy density of power storage device 10 increases.

  Further, the second cap 22 is configured to prevent the unit cell 14 from falling down when the unit cell 14 with the first and second caps 20 and 22 attached is attached to the base unit 24.

  More specifically, the engaging portion 22b of the second cap 22 is sufficient so that the engaging portion 22b of the second cap 22 does not come out of the engaging hole 24b of the base portion 24 even when the cell 14 is inclined. Height (the size in the height direction (Z-axis direction)). Thereby, when the unit cell 14 with the second cap 22 attached is mounted on the base unit 24, even if the unit cell 14 contacts the unit cell 14 already mounted on the base unit 24, The unit cell 14 already mounted does not fall. As a result, the assemblability of the power storage device 10 is improved.

  Furthermore, as shown in FIG. 1, a monitoring module 32 that monitors the state of the power storage device 10 is attached to the side part 30. The monitoring module 32 is configured to monitor the temperature and voltage of the cell 14 via a sensor (not shown) attached to one of the cells 14 of the battery module 12, for example.

  In addition, as shown in FIG. 3, the side portions 28 and 30 support the base portion 24 and the cover portion 26, and also support a plurality of heat insulating plates 34.

Specifically, the heat insulating plate 34 is supported at both ends in the width direction (X-axis direction) by the side portions 28 and 30 and is disposed in a gap between the unit cells 14 adjacent in the depth direction (Y-axis direction). .
The heat insulating plate 34 suppresses a temperature rise of the unit cells 14 caused by heat radiation from the adjacent unit cells 14.

  As shown in FIG. 1 and FIG. 3, a plurality of slot-shaped ventilation holes (openings) that are long in the width direction (X-axis direction) through which an air current for cooling the cells 14 passes are related to the temperature of the cells 14. ) 26b is formed on the cover portion 26.

  Similarly, as shown in FIGS. 2 and 3, a plurality of slot-shaped ventilation holes 24 e that are long in the width direction (X-axis direction) are also formed in the base portion 24.

  FIG. 12 is a schematic cross-sectional view of power storage device 10. As shown in FIG. 12, the ventilation port 26b of the cover 26 is formed in the cover 26 so as to face a gap between the adjacent cells 14 in the depth direction (Y-axis direction).

  On the other hand, the ventilation opening 24e of the base portion 24 is formed at a position of the base portion 24 facing a gap between the second caps 22 mounted on the unit cells 14 adjacent in the depth direction (Y-axis direction). I have. Therefore, the ventilation port 26b of the cover 26 and the ventilation port 24e of the base 24 face each other in the height direction (Z-axis direction).

  The ventilation hole 26b of the cover portion 26 and the ventilation hole 24e of the base portion 24 provide a gap between the unit cells 14 adjacent in the depth direction (Y-axis direction) from the ventilation hole 24e of the base portion 24 to the cover portion 26. It is possible to generate an airflow F (generation) toward the ventilation opening 26b.

  For example, when the power storage device 10 is attached to the lower part of a railway vehicle, traveling wind flows in through the ventilation holes 24 e of the base portion 24, passes through the gap between the cells 14, and passes through the ventilation holes 26 b of the cover portion 26. Spill out through. In this case, guide means (not shown) such as a duct for guiding the traveling wind to the ventilation port 24 e of the base portion 24 is provided in the power storage device 10.

  By the ventilation holes 26b of the cover portion 26 and the ventilation holes 24e of the base portion 24, each of the cells 14 in the power storage device 10 can be cooled by the airflow F. In addition, by forming a ventilation hole 24e in the base portion 24 at a pinpoint at a position facing a plurality of gaps between the plurality of unit cells 14, that is, a plurality of gaps between the plurality of second caps 22, A decrease in rigidity of the base portion 24 can be suppressed. That is, the opening formed in the base portion 24 is minimized, whereby a decrease in the rigidity of the base portion 24 is suppressed (sufficient rigidity is secured).

  In addition, a part of the ventilation opening 24e of the base portion 24 is constituted by a through hole formed when the first rib 24d is formed by cutting and raising. Thereby, in the base part 24, the ventilation opening 24e and the first rib 24d can be simultaneously formed. Further, the first rib 24d functions as a guide for guiding the airflow F into the corresponding ventilation port 24e. As a result, a large amount of airflow F flows into the gap between the cells 14 facing the ventilation holes 24e, and the cells 14 are efficiently cooled.

  Further, as shown in FIG. 13 in which the power storage device 10 (that is, the base portion 24) is viewed from the back side, the plurality of ventilation holes 24e formed in the base portion 24 are arranged in the longitudinal direction of the base portion 24 (that is, in the width direction (X axis Directions)) are formed on the base portion 24 so as not to face each other. In other words, the positions of the plurality of ventilation openings 24e in the depth direction (Y-axis direction) are different.

  More specifically, as shown in FIG. 3, the plurality of cells 14 are arranged in two rows in the depth direction (Y-axis direction). Therefore, the ventilation holes 24e of the base portion 24 for generating the airflow F in the gap between the unit cells 14 are also arranged in two rows in the depth direction.

  At this time, when the ventilation holes 24e in one row (the left column in the drawing) and the ventilation holes 24e in the other row (the right column in the drawing) are arranged in the width direction (X-axis direction), the base portion 24 therebetween. The stress may concentrate on the portion, and the base portion 24 may be deformed or broken at that portion.

  In order to alleviate such stress concentration, as shown in FIG. 13, a plurality of ventilation holes 24e in one row and a plurality of ventilation holes 24e in the other row are not opposed in the width direction (X-axis direction). The ventilation port 24 e is formed in the base 24. Specifically, as shown in FIG. 13, the center of the ventilation opening 24 e in the depth direction (Y-axis direction) is shifted with respect to the gap between the adjacent second caps 22, and the ventilation of one row is The opening 24e and the ventilation opening 24e in the other row are shifted in opposite directions.

  Further, as shown in FIG. 2, the ventilation port 24 e of the base portion 24 is formed in the base portion 24 so that its longitudinal direction (X-axis direction) is parallel to the longitudinal direction (X-axis direction) of the cell 14. ing. That is, the longitudinal direction of the gap between the unit cells 14 adjacent in the depth direction (Y-axis direction) is parallel to the longitudinal direction of the ventilation port 24e. As a result, most of the airflow F passing through the ventilation port 24e flows into the gap between the cells 14 adjacent in the depth direction, and the cells 14 are efficiently cooled (the longitudinal direction of the ventilation port 24e is the depth direction). (In comparison with the case where the gap between the unit cells 14 facing each other in the direction is twisted with respect to the longitudinal direction).

  In order to realize a compact power storage device 10, it is preferable that the plurality of unit cells 14 be arranged as densely as possible. However, when the plurality of unit cells 14 are densely arranged, the gap between the second caps 22 attached thereto is narrowed. As a result, the flow rate of the airflow F passing through the gap between the cells 14 decreases, and the cooling performance of the cells 14 decreases.

  As a countermeasure, as shown in FIG. 8, a first concave portion 22c and a second concave portion 22d are formed in each of the second caps 22.

  Note that the “recess” of the second cap 22 referred to in this specification refers to a portion that is recessed from the outer surface of the second cap 22 and includes a penetrating portion from the outer surface to the inner surface.

  As shown in FIG. 8, the first and second concave portions 22c and 22d are formed on side walls 22e and 22f facing each other in the depth direction (Y-axis direction). The first concave portion 22c has a cut shape, and the second concave portion 22d has a through hole shape.

  Specifically, as shown in FIG. 14, which is a cross-sectional view of the second cap 22 adjacent in the depth direction (Y-axis direction), the first concave portion 22c is formed from the open end 22g of the second cap 22. The side wall 22e is formed by cutting the side wall 22e from the opening end 22g so as to extend substantially to the center in the height direction (Z-axis direction). That is, the first concave portion 22c communicates with a gap between the adjacent unit cells 14.

  On the other hand, the second recess 22d is formed through the side wall 22f so as to extend from the bottom 22a of the second cap 22 to a substantially central portion in the height direction (Z-axis direction). In other words, as shown in FIG. 8, the second recess 22d cuts from the open end 22g to the bottom 22a of the second cap 22, and connects two corners between the cut and the open end 22g in the width direction. It is a through-hole formed by being connected by a bridging portion 22j extending in the (X-axis direction). That is, the second recess 22 d communicates with the bottom 22 a of the cap 22.

  Therefore, a part of the first concave part 22c and a part of the second concave part 22d face each other in the depth direction (Y-axis direction) at a substantially central position in the height direction (Z-axis direction) of the second cap 22. are doing.

  As shown in FIGS. 12 and 14, when a plurality of second caps 22 having such first and second recesses 22c and 22d are arranged in the depth direction (Y-axis direction), the adjacent second caps 22 are formed. One first concave portion 22c of the cap 22 partially opposes the other second concave portion 22d. In the case of the present embodiment, specifically, at the substantially center position in the height direction (Z-axis direction) of the second cap 22, the first concave portion 22c of one second cap 22 and the second Opposes the second concave portion 22d of the cap 22.

  As shown in FIG. 14, the first concave portion 22c of one second cap 22 and the second concave portion 22d of the other second cap 22 face each other, so that A flow path of an airflow F (broken line) extending in the height direction (Z-axis direction) is formed. That is, a flow path of the airflow F communicating with the gap between the adjacent unit cells 14 and communicating with the bottom 22 a of the second cap 22 is formed. The airflow F passes through the inside of the second recess 22d of the other second cap 22 and then passes through the inside of the first recess 22c of the one second cap 22.

  As described above, the first concave portion 22c and the second concave portion 22d face each other to form a flow path of the airflow F between the second caps 22, so that the flow rate of the airflow F flowing through the gap between the single cells 14 is obtained. (Compared to the case where these recesses are not present). Therefore, even if the cells 14 are densely arranged and the gap between the second caps 22 is narrowed, a sufficient amount of airflow F allows the gap between the cells 14 to be formed by the first concave portion 22c and the second concave portion 22d. Can flow. As a result, the power storage device 10 having a compact size can be realized by closely arranging a plurality of the cells 14 while suppressing the cooling performance of each of the cells 14.

  It should be noted that a concave portion communicating with the gap between the unit cells 14 and the bottom portion 22a of the second cap 22 may be formed on only one of the side wall portions 22e and 22f of the second cap 22 as a flow path through which the airflow F flows. Conceivable. However, there is a possibility that the rigidity of the side wall of the second cap 22 in which such a recess is formed is reduced. As a result, when the power storage device 10 is mounted on a vehicle, the second cap 22 may be damaged by vibration of the running vehicle. In order to suppress the decrease in the rigidity, it is conceivable that the side wall portion on which the concave portion is formed is made thick. However, the size of the second cap 22 is increased, and as a result, the cells 14 are densely arranged. It becomes difficult.

  Further, it is conceivable that the flow path of the airflow F communicating the gap between the unit cells 14 and the bottom of the second cap 22 is formed by a through hole instead of a concave portion. However, the rigidity of the side wall of the second cap 22 having such a through hole may be reduced. In order to suppress the decrease in the rigidity, it is conceivable to configure the side wall portion where the through hole is formed to be thick. However, as a result, the second cap 22 is enlarged, and as a result, the unit cells 14 are densely packed. It becomes difficult to arrange. In the case of a through hole, the processing cost of the second cap 22 is higher than that of the recess.

  In addition, since the first and second recesses 22c and 22d are formed as through holes, the cell 14 covered with the second cap 22 is provided in the flow path of the airflow F formed by the recesses 22c and 22d. Part of the part is exposed. As a result, the portion of the cell 14 covered by the second cap 22 is cooled.

  Therefore, as in the present embodiment, the recesses 22c and 22d formed in the adjacent second caps 22 are opposed to each other, so that the rigidity of the second cap 22 is maintained and the gap between the second caps 22 is maintained. The flow path of the airflow F can be formed at the same time.

  As described above, in order to form the flow path of the airflow F between the second caps 22, it is necessary that the first concave portion 22 c and the second concave portion 22 d face each other in the depth direction (Y-axis direction). It is necessary to attach the plurality of second caps 22 to the base portion 24 in the posture.

  In order to attach the plurality of second caps 22 to the base portion 24 in a normal posture without erroneous orientation in the depth direction (Y-axis direction), as shown in FIG. The bottom 22a is provided with a protrusion 22h that protrudes in the height direction (Z-axis direction).

  Specifically, as shown in FIG. 3, when the second cap 22 is attached to the base portion 24, the two engaging portions 22b of the second cap 22 are inserted into the two engaging holes 24b of the base portion 24. It is inserted. Since the two engagement holes 24b are arranged in the width direction (X-axis direction), the second cap 22 may be attached to the base portion 24 in the depth direction (Y-axis direction).

  In order to prevent the wrong orientation in the depth direction (Y-axis direction), the projection 22h provided on the bottom portion 22a of the second cap 22 has the base portion 24 with the second cap 22 in the correct depth direction. Can be passed through the ventilation opening 24e. On the other hand, when the second cap 22 is oriented in the wrong depth direction, the protruding portion 22h hits the battery holding portion 24a of the base portion 24, whereby the engaging portion 22b of the second cap 22 is engaged with the base portion 24. The hole 24b cannot be engaged.

  By providing such a protruding portion 22h on the second cap 22, the plurality of second caps 22 can be attached to the base portion 24 with the first concave portion 22c and the second concave portion 22d surely facing each other. Can be. As a result, the flow path of the airflow F is reliably formed between the second cap 22 by the opposing first concave portion 22c and second concave portion 22d.

  The means for engaging the second cap 22 with the base portion 24 in a state where the direction of the depth direction (Y-axis direction) is correct is not limited to the protrusion 22h formed on the second cap 22. For example, the shape of the engagement portion 22b of the second cap 22 and the engagement hole 24b of the base portion 24 is changed such that the depth direction (Y-axis direction) of the second cap 22 is equal to the first recess 22c and the second recess 22c. The shape may be a shape that can be engaged only when the concave portion 22d is in the correct direction facing the concave portion, for example, a triangular shape.

  Further, as shown in FIG. 3, the opening area of the ventilation port 26 b of the cover 26, which is the outlet of the airflow F that passes through the gap between the cells 14 and cools the cells 14, is changed by the inlet of the airflow F. It may be smaller than the opening area of the ventilation port 24e of a certain base portion 24.

  The opening area of the ventilation port 26b of the cover 26 is a size that the user cannot touch the external terminals (the positive electrode terminal 14a and the negative electrode terminal 14b) of the unit cell 14 through the ventilation port 26b, that is, a size that the user's finger cannot pass. Has been determined. The opening area of the ventilation port 24e of the base portion 24 is larger than the opening area of the ventilation port 26b of the cover portion 26.

  As a result, a large amount of airflow F flows between the base portion 24 and the cover portion 26 through the ventilation port 24 e of the base portion 24. In addition, since the ventilation port 26b of the cover 26 as the outlet is smaller than the ventilation port 24e of the base 24 as the entrance, a part of the airflow F passing through the ventilation port 24e of the base 24 is immediately removed. The air flows around the unit cell 14 without going outside through the ventilation opening 26b of the cell 26. For example, an airflow flows through a gap between the unit cells 14 adjacent in the width direction (X-axis direction). As a result, the plurality of unit cells 14 are cooled more than when the opening area of the ventilation opening 26b of the cover 26 is larger than or equal to the opening area of the ventilation opening 24e of the base 24.

  According to the present embodiment, by providing the first rib 24d and the second rib 24c, the base is lightweight and has high rigidity, and has an opening (air vent 24e) for cooling the unit cell 14. The unit 24 can be realized. As a result, the power storage device 10 including the base portion 24 can achieve higher rigidity while suppressing an increase in weight.

  As described above, the present invention has been described with reference to the above embodiments, but the present invention is not limited to the above embodiments.

  For example, in the case of the above-described embodiment, the frame-shaped second rib 24c and the first rib 24d are formed inside the base portion 24, but the present invention is not limited to this. If sufficient rigidity can be secured, the frame-shaped second rib 24c may be omitted. In the above-described embodiment, the first rib 24d is cut and raised, but is not limited to this. The first rib protrudes from the battery holding portion of the base portion on which the plurality of unit cells are arranged to the non-unit cell side, and if it can improve the rigidity of the base portion against flexure deformation, its shape and number Does not matter.

  In the above-described embodiment, for example, a plurality of second caps 22 are used to cover lower ends of the plurality of unit cells 14. However, it is not limited to this.

  FIG. 15 is a cross-sectional view of a different form of the second cap.

  Only one second cap 222 shown in FIG. 15 is provided for the power storage device, and covers the lower ends of the plurality of unit cells 14. That is, the second cap 222 has a tray shape and includes a plurality of storage holes 222j for storing and covering the lower ends of the plurality of unit cells 14.

  As shown in FIG. 15, the second cap 222 has a partition wall 222k (a portion sandwiched between the lower ends of the adjacent cells 14) defining a plurality of storage holes 222j. Is formed. In each of the flow paths 222m, the airflow F flows, and one end thereof communicates with a gap between the adjacent unit cells 14 (that is, the space above the partition wall portion 222k), and the other end thereof forms a bottom portion of the second cap 222. 222a. The channel 222m is formed in the partition wall 222k so as to alternately pass through the adjacent accommodation holes 222j. Accordingly, the airflow F flowing through the flow path 222m alternately enters the adjacent accommodation holes 222j, that is, alternately contacts the adjacent unit cells 14. As a result, the lower end of the unit cell 14 covered with the accommodation hole 222j of the second cap 222 is cooled by the airflow F. The channel 222m formed in the partition wall 222k may communicate with the gap between the adjacent unit cells 14 without communicating with the accommodation hole 222j.

  The present invention is applicable to a power storage device including a plurality of unit cells.

DESCRIPTION OF SYMBOLS 10 Electric storage apparatus 14 Single cell 24 Base part 24a Battery holding part 24e Opening (vent)

Claims (8)

A base part,
And a plurality of cells aligned on the base portion,
The base part is
A battery holder in which the plurality of cells are arranged;
A first rib protruding from the battery holding portion to the anti-unit cell side,
An opening is formed in the battery holding portion of the base portion ,
The first rib is cut and raised,
It said opening Ru through hole der formed by raised its cutting power storage device. The power storage device according to claim 1 , wherein the base portion includes a frame-shaped second rib provided along a peripheral edge of the battery holding portion and protruding toward a non-unit cell side. The power storage device according to claim 2 , wherein the first rib and the second rib of the base portion have the same protruding height. It said first rib is positioned at the center portion of said battery holding portion surrounded by the second rib, the power storage device according to claim 2 or 3. The power storage device according to any one of claims 1 to 4 , wherein the opening is formed in the battery holding portion of the base portion so as to face each of the plurality of gaps between the plurality of unit cells. . The power storage device according to claim 5 , wherein the opening is formed such that a longitudinal direction thereof is parallel to a longitudinal direction of the unit cell. A cover portion that covers the plurality of cells arranged in the battery holding portion of the base portion;
A plurality of openings in which the cover portion is opposed to the plurality of openings of the base portion, the electricity storage device according to claim 5 or 6. The power storage device according to claim 7 , wherein an opening area of the opening of the cover portion is smaller than an opening area of the opening of the base portion.

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