JP2015122166A - Battery rack and cooling method of secondary battery disposed in the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To appropriately support a plurality of secondary battery modules and to appropriately cool the plurality of secondary battery modules.SOLUTION: A battery rack comprises: a plurality of upright support members fixed onto a wall surface 7 in a container; and individual rack plates 52-1 through 52-n mounted with a plurality of secondary battery modules 17-1 through 17-m. The individual rack plates 52-1 through 52-n are disposed apart from the wall surface 7 and are fixed to the plurality of upright support members. The battery rack 51 as described above can securely fix the individual rack plates 52-1 through 52-n onto the wall surface 7 so as not to block flow of the cooling air and can appropriately cool the plurality of secondary battery modules 17-1 through 17-m when cooling the plurality of secondary battery modules 17-1 through 17-m by feeding cooling air into a cooling space 53 formed among the individual rack plates 52-1 through 52-n and the wall surface 7.

Description

  The present invention relates to a battery rack and cooling of a secondary battery arranged in the battery rack, and more particularly to cooling of a battery rack storing a plurality of secondary battery modules and a secondary battery arranged in the battery rack.

  A secondary battery system including a plurality of secondary battery modules is known. The secondary battery system further includes a rack, a container, and an air conditioner. The rack has a plurality of shelves on which a plurality of secondary battery modules are placed, and is disposed inside the container. The air conditioner cools the plurality of secondary battery modules by cooling the inside of the container (see Patent Documents 1 to 4). Such a secondary battery system can be easily transported and installed by housing a plurality of secondary battery modules, a rack, and an air conditioner in one container.

International Publication No. 2012/015004 Japanese translation of PCT publication No. 2004-510313 JP 2005-243580 A JP 2012-164747 A

  Such a battery rack is desired to appropriately cool a plurality of secondary battery modules and appropriately support the plurality of secondary battery modules.

An object of the present invention is to provide a battery rack that appropriately supports a plurality of secondary battery modules and appropriately cools the plurality of secondary battery modules, and a method for cooling a secondary battery disposed in the battery rack. There is.
Another object of the present invention is to provide a battery rack that appropriately supports a plurality of secondary battery modules and uniformly cools the plurality of secondary battery modules, and a method for cooling a secondary battery disposed in the battery rack. It is to provide.
The secondary battery constituting the secondary battery module according to the present invention is not particularly limited, such as a lead secondary battery and a nickel hydride secondary battery, in addition to the lithium secondary battery, but has good charge / discharge followability, and the secondary battery. In view of the importance of managing deterioration of the secondary battery due to charge / discharge when the temperature of the battery is low, a lithium secondary battery is preferable.

  A battery rack according to the present invention includes a plurality of upright support members fixed inside a container and a plurality of rack plates on which a plurality of secondary battery modules are placed. Each rack plate of the plurality of rack plates is provided on the plurality of upright support members such that a cooling gap through which cooling air for cooling the secondary battery module passes is disposed between the rack plates and the wall surface inside the container. It is fixed.

  Such a battery rack has a cooling air flow when cooling a plurality of secondary battery modules by feeding cooling air into a cooling gap formed between a plurality of rack plates and a wall surface inside the container. A plurality of rack plates can be firmly fixed to the wall surface inside the container so as not to hinder. For this reason, such a battery rack can appropriately support the plurality of secondary battery modules, and can appropriately cool the plurality of secondary battery modules.

  A cooling air flow rate corresponding to each rack plate is made equal between each rack plate and the wall surface inside the container in a state where the plurality of secondary battery modules are placed on each rack plate. The cooling gap is formed.

  Such a battery rack can uniformly cool a plurality of secondary battery modules by uniformly supplying cooling air to each rack plate.

  The plurality of rack plates are arranged side by side in the vertical direction. A gap between an arbitrary rack plate of the plurality of rack plates and a wall surface inside the container is a lower rack plate disposed below the arbitrary rack plate of the plurality of rack plates. It is larger than the clearance gap between the wall surfaces inside the container.

  Such a battery rack is formed such that the lower rack plate has a narrower gap with the wall surface inside the container, so that cooling that flows through the cooling gap between each rack plate and the wall surface inside the container is performed. When the static pressure of air is higher on the lower side, the cooling air can be made to flow uniformly to each rack plate, and the plurality of secondary battery modules can be uniformly and appropriately cooled.

  Each rack plate of the plurality of rack plates has a plurality of rack plate claws. The plurality of rack plate claws are respectively fitted to the plurality of secondary battery modules mounted on the rack plates among the plurality of secondary battery modules.

  Such a battery rack is configured such that when a plurality of rack plate claws are arranged at equal intervals on the rack plate, the plurality of secondary battery modules are fitted with the plurality of rack plate claws, respectively. Battery modules can be easily arranged at equal intervals. In such a battery rack, by arranging a plurality of secondary battery modules at equal intervals, the plurality of secondary battery modules can be uniformly brought into contact with the cooling air, and the plurality of secondary battery modules can be appropriately connected. Can be cooled.

  The battery rack according to the present invention further includes a plurality of fixing jigs corresponding to the plurality of rack plates. An arbitrary fixing jig of the plurality of fixing jigs is attached to the belt-like member that is detachably fixed to a rack plate corresponding to the arbitrary fixing jig of the plurality of rack plates. A plurality of fixing jig claw plates to be fixed; The plurality of fixing jig claw plates are respectively fitted to a plurality of secondary battery modules mounted on the rack plate among the plurality of secondary battery modules.

  In such a battery rack, when a plurality of fixing jig claw plates are arranged at equal intervals on the belt-shaped member, a plurality of fixing jig claw plates are respectively fitted to a plurality of secondary battery modules, A plurality of secondary battery modules can be easily arranged at equal intervals. In such a battery rack, by arranging a plurality of secondary battery modules at equal intervals, the plurality of secondary battery modules can be uniformly brought into contact with the cooling air, and the plurality of secondary battery modules can be appropriately connected. Can be cooled.

  The plurality of rack plates are grouped into a plurality of units. The plurality of unit rack plates belonging to an arbitrary unit among the plurality of rack plates are an uppermost unit rack plate disposed on the uppermost side and a lower unit rack disposed on the lower side of the uppermost unit rack plate. Includes board. At this time, the plurality of secondary battery modules include the plurality of units so that the number of secondary battery modules mounted on the uppermost unit rack plate among the plurality of secondary battery modules is minimized. It is placed on a rack plate.

  A plurality of secondary battery modules are formed with a predetermined number of units, and are used for each unit. Such a battery rack can facilitate management of a plurality of secondary battery modules by arranging a plurality of secondary battery modules separately for each unit. For this reason, such a battery rack can further lower the center of gravity while maintaining the cooling effect of the plurality of secondary battery modules, and can appropriately support the plurality of secondary battery modules.

  The battery rack according to the present invention further includes a plurality of battery monitoring circuits corresponding to the plurality of units. The battery monitoring circuit corresponding to the arbitrary unit of the plurality of battery monitoring circuits includes the plurality of secondary battery modules mounted on the plurality of unit rack plates of the plurality of secondary battery modules. Controlled and placed on the lowermost unit rack plate disposed on the lowermost side of the plurality of unit rack plates.

  Such a battery rack can lower the center of gravity. Therefore, such a battery rack can appropriately support the plurality of secondary battery modules while maintaining the cooling effect of the plurality of secondary battery modules.

  The secondary battery installation method according to the present invention is a method of placing the plurality of secondary battery modules on the battery rack according to the present invention. The secondary battery installation method according to the present invention includes: grouping the plurality of rack plates into a plurality of units; and a secondary battery mounted on the uppermost unit rack plate of the plurality of secondary battery modules. Placing the plurality of secondary battery modules on the plurality of rack plates so that the number of modules is minimized.

  According to such an installation method, the center of gravity of the battery rack can be lowered, and a plurality of secondary battery modules can be appropriately supported.

  The secondary battery cooling method according to the present invention is a method of cooling the plurality of secondary battery modules using the battery rack according to the present invention. The method for cooling a secondary battery according to the present invention includes mounting the plurality of secondary battery modules on the plurality of rack plates and feeding the cooling air into the cooling gap.

  According to such a cooling method, the cooling air fed into the cooling gap formed between the plurality of rack plates and the wall surface inside the container is not hindered by the plurality of rack plates, and the plurality of secondary air The battery module can be appropriately cooled.

  A secondary battery system according to the present invention includes a battery rack according to the present invention, the plurality of secondary battery modules, a container in which a wall surface inside the container is formed, the plurality of rack plates, and a wall surface inside the container. And an air conditioner that sends cooling air into a cooling gap formed between the two.

  Such a secondary battery system can appropriately cool a plurality of secondary battery modules by including the battery rack according to the present invention.

  The battery rack installation method according to the present invention is used when configuring a battery rack. The battery rack includes a plurality of upright support members fixed to a wall surface inside the container, and a plurality of rack plates on which a plurality of secondary battery modules are placed. Each rack plate of the plurality of rack plates is provided on the plurality of upright support members such that a cooling gap through which cooling air for cooling the secondary battery module passes is disposed between the rack plates and the wall surface inside the container. It is fixed. At this time, a cooling gap through which cooling air passes is formed between each rack plate and the wall surface inside the container. The battery rack installation method according to the present invention includes changing a gap between each rack plate and a wall surface inside the container based on a flow rate of cooling air corresponding to each rack plate.

  In such a battery rack installation method, the cooling air is uniformly supplied to the plurality of secondary battery modules mounted on each rack plate while maintaining appropriate support of the plurality of secondary battery modules. The battery rack can be appropriately configured, and the plurality of secondary battery modules can be appropriately cooled.

  In the battery rack and the battery rack installation method according to the present invention, a plurality of rack plates can be firmly fixed to the wall surface inside the container so as not to hinder the flow of cooling air, and the plurality of secondary battery modules can be appropriately attached. It can support and can cool a plurality of secondary battery modules appropriately.

It is a figure which shows a lithium secondary battery system. It is sectional drawing which shows the AA cross section of FIG. It is a front view which shows the rack for batteries. It is a side view which shows the rack for batteries. It is a top view which shows the rack for batteries. It is a perspective view which shows a secondary battery module. It is a perspective view which shows a rack board. It is a perspective view which shows a fixing jig. It is a perspective view which shows the state by which the secondary battery module was fixed to the rack board using the fixing jig. It is a sectional side view which shows the other battery rack.

  An embodiment of a battery rack will be described below with reference to the drawings. In this embodiment, a lithium secondary battery will be described as a secondary battery, but is not particularly limited. The battery rack 1 is used in a lithium secondary battery system 2 as shown in FIG. The lithium secondary battery system 2 includes a container 3. The container 3 is formed in a box shape and forms a storage space 5 therein. The container 3 is formed with a floor surface 6 and a wall surface 7 facing the storage space 5. The floor surface 6 is flat and is formed along a horizontal plane. The wall surface 7 is flat and is formed along a plane parallel to the vertical direction. The battery rack 1 is disposed in the storage space 5 inside the container 3, is placed on the floor surface 6, and is disposed along the wall surface 7.

  The battery rack 1 further includes an air conditioner 8 as shown in FIG. The air conditioner 8 is disposed outside the container 3. The air conditioner 8 includes a duct 10. The duct 10 is disposed inside the container 3 and above the storage space 5. The duct 10 is formed with an air inlet 11 and an outlet 12. The air inlet 11 is disposed approximately at the center of the storage space 5. The outlet 12 is arranged on the upper side of the battery rack 1. The air conditioner 8 sucks air in the storage space 5 from the air inlet 11 and injects cooling air from the outlet 12.

  FIG. 3 shows the battery rack 1. The battery rack 1 includes a plurality of upright support members 14 and a plurality of rack plates 15-1 to 15-n. The plurality of rack plates 15-1 to 15-n are each formed in a substantially rectangular plate, and a flat mounting surface 16 is formed. The plurality of rack plates 15-1 to 15-n are arranged in the vertical direction, and are arranged so that the placement surface 16 is along the horizontal plane. The plurality of rack plates 15-1 to 15-n are fixed to the plurality of upright support members 14.

  The lithium secondary battery system 2 further includes a plurality of secondary battery modules 17-1 to 17-m. The plurality of secondary battery modules 17-1 to 17-m are mounted on the mounting surfaces 16 of the plurality of rack plates 15-1 to 15-n.

  As shown in FIG. 4, the plurality of upright support members 14 are each formed in a ladder shape by joining a plurality of rod-shaped members to each other. The plurality of upright support members 14 are placed on the floor surface 6 of the container 3 so as to stand upright along a straight line parallel to the vertical direction. The plurality of upright support members 14 are further arranged such that a plane along which the plurality of upright support members 14 are perpendicular to the wall surface 7. The upright support members 14 arranged on the wall surface 7 side among the plurality of upright support members 14 are in contact with the wall surface 7 and are fixed to the wall surface 7 via fastening members (not shown).

  As shown in FIG. 5, the plurality of rack plates 15-1 to 15-n are arranged so as to be separated from the wall surface 7 by a predetermined distance. The battery rack 1 is arranged such that the plurality of rack plates 15-1 to 15-n are separated from the wall surface 7, whereby a cooling gap is provided between the plurality of rack plates 15-1 to 15-n and the wall surface 7. 18 is formed. At this time, the air outlet 12 of the duct 10 is directed to the cooling gap 18 so that the cooling air discharged from the air outlet 12 is supplied to the cooling gap 18.

  FIG. 6 shows an arbitrary secondary battery module 17-j (j = 1, 2, 3,..., M) among the plurality of secondary battery modules 17-1 to 17-m. The secondary battery module 17-j includes a housing portion 21, two front side fixing parts 22, two front side triangular plates 23, two back side fixing parts 24, and two back side triangular plates 25. The casing portion 21 is formed in a rectangular parallelepiped shape and includes a plurality of lithium secondary batteries inside.

  Each of the two front side fixing portions 22 is formed in a plate shape. The two front-side fixing portions 22 are arranged so as to protrude to the front side of the housing portion 21 along the lower surface of the housing portion 21, and are joined to the lower surface of the housing portion 21. ing. The two front triangular plates 23 are each formed in a plate shape. The two near-side triangular plates 23 are disposed so as to protrude to the near side of the casing portion 21 along the side surface of the casing portion 21 and the side surface on the opposite side, respectively. It is joined to one of the fixing portions 22.

  The two back side fixing parts 24 are each formed in a plate shape. The two back-side fixing portions 24 are arranged so as to protrude to the back side of the housing portion 21 along the bottom surface of the housing portion 21, and are joined to the bottom surface of the housing portion 21. ing. The two back side triangular plates 25 are each formed in a plate shape. The two back side triangular plates 25 are arranged so as to protrude to the back side of the housing part 21 along the side surface of the housing part 21 and the side surface on the opposite side thereof, and the side surface of the housing part 21 and the two back sides It is joined to one of the fixing portions 24.

  FIG. 7 shows an arbitrary rack plate 15-i (i = 1, 2, 3,..., N) among the plurality of rack plates 15-1 to 15-n. The rack plate 15-i is formed with a front side surface portion 31, a back side surface portion 32, and a plurality of rack plate claws 33 by processing a rectangular metal plate. The front side surface portion 31 is formed on the front side edge far from the wall surface 7 of the rack plate 15-i, and is formed so as to protrude downward. The back side surface portion 32 is formed on the back edge of the rack plate 15-i on the side close to the wall surface 7, and is formed so as to protrude downward. Each of the plurality of rack plate claws 33 is formed on the back side edge of the rack plate 15-i, and projects from the back side edge to the near side so as to face the placement surface 16 of the rack plate 15-i. Is formed. The plurality of rack plate claws 33 are formed so as to be arranged at equal intervals, and each has a width equal to the interval between the two back side triangular plates 25.

  The battery rack 1 further includes a plurality of fixing jigs corresponding to the plurality of rack plates 15-1 to 15-n. FIG. 8 shows a fixing jig corresponding to the rack plate 15-i among the plurality of fixing jigs. The fixing jig 41 includes a belt-like portion 42 and a plurality of fixing jig claw plates 43. The strip-shaped portion 42 is formed in a strip shape. The plurality of fixing jig claw plates 43 are each formed in a rectangular shape, and are formed so that the width is substantially equal to the interval between the two front triangular plates 23. The plurality of fixing jig claw plates 43 are arranged at equal intervals at intervals equal to the intervals between the plurality of rack plate claws 33, and are joined to the band-shaped portion 42.

  As shown in FIG. 9, the secondary battery module 17-j is configured so that one of the plurality of rack plate claws 33 of the rack plate 15-i is sandwiched between the two back triangular plates 25 and sandwiched between them. The two rear side fixing portions 24 are arranged so as to be sandwiched between the single rack plate claw and the mounting surface 16. The fixing jig 41 is arranged so that one of the plurality of fixing jig claw plates 43 is sandwiched between the two front triangular plates 23 of the secondary battery module 17-j, and the sandwiched fixing jig claw plates The belt-like portion 42 is joined to the rack plate 15-i via a bolt and nut so that the two front-side fixing portions 22 are sandwiched between 43 and the mounting surface 16.

  The plurality of secondary battery modules 17-1 to 17-m are firmly fixed to the container 3 and can be appropriately supported by being fixed by such a battery rack 1. The plurality of secondary battery modules 17-1 to 17-m are further fitted into the plurality of rack plate claws 33 of the rack plate 15-i or the plurality of fixing jig tabs of the fixing jig 41. By being fitted to the plate 43, it can be appropriately arranged at equal intervals.

  The rack plate 15-i is formed by forming a plurality of notches on one side of a rectangular flat plate, and bending a plurality of portions sandwiched between the plurality of notches, respectively. The rack plate claw 33 is formed. According to such a manufacturing method, the rack plate 15-i can be easily manufactured. The plurality of rack plate claws 33 may be formed by another manufacturing method different from such a manufacturing method. For example, the rack plate 15-i can be formed with a plurality of rack plate claws 33 by joining a plurality of plate-like members to the placement surface 16. In this manner, even in the rack plate on which the plurality of rack plate claws 33 are formed, the plurality of secondary battery modules 17-1 to 17-m can be appropriately arranged in the same manner.

  When the plurality of secondary battery modules 17-1 to 17-m can be appropriately disposed on the plurality of rack plates 15-1 to 15-n, the battery rack 1 includes a plurality of rack plate claws 33 and Either or both of the plurality of fixing jigs can be omitted. Similarly, the battery rack from which the plurality of rack plate claws 33 or the plurality of fixing jigs are omitted is fixed in contact with the wall surface 7 to thereby form a plurality of secondary battery modules 17-1 to 17-m. Can be appropriately supported, and the plurality of secondary battery modules 17-1 to 17-m can be appropriately cooled.

  The air conditioner 8 supplies cooling air having a predetermined temperature from the outlet 12 of the duct 10 to the cooling gap 18 at a predetermined flow rate. When the cooling air is supplied to the cooling gap 18, the cooling air branches and flows above the plurality of rack plates 15-1 to 15-n to cool the plurality of secondary battery modules 17-1 to 17-m. .

  The embodiment of the battery rack installation method is a method of configuring the battery rack 1 described above. In the battery rack installation method, first, an intermediate product of a battery rack assembled from a plurality of upright support members 14 and a plurality of rack plates 15-1 to 15-n is prepared, and the plurality of upright support members 14 are containers. 3 is fixed in contact with the wall surface 7.

  In the plurality of secondary battery modules 17-1 to 17-m, after the plurality of upright support members 14 are fixed to the wall surface 7 of the container 3, one of the plurality of rack plate claws 33 of the rack plate 15-i has two. It arrange | positions so that the two back side fixing | fixed parts 24 may be pinched | interposed between the one rack board nail | claw and the mounting surface 16 pinched | interposed between the back side triangular plates 25. The fixing jig 41 is arranged so that one of the plurality of fixing jig claw plates 43 is sandwiched between the two front triangular plates 23 of the secondary battery module 17-j, and the sandwiched fixing jig claw plates The belt-like portion 42 is joined to the rack plate 15-i via a bolt and nut so that the two front side fixing portions 22 are sandwiched between the mounting plate 16 and the mounting surface 16.

  At this time, the plurality of secondary battery modules 17-1 to 17-m are positioned using the plurality of rack plate claws 33 of the rack plate 15-i and the plurality of fixing jig claw plates 43 of the fixing jig 41. Therefore, it can arrange | position at equal intervals easily.

  The air conditioner 8 supplies cooling air to the cooling gap 18 after the plurality of secondary battery modules 17-1 to 17-m are fixed to the plurality of rack plates 15-1 to 15-n. While the air conditioner 8 is blowing cooling air into the cooling gap 18, the flow rate simulation and temperature measurement corresponding to each rack plate 15-1 to 15-n among the plurality of racks are performed.

  The distance between each rack plate and the wall surface 7 of the container 3 is determined based on the flow rate simulation and temperature measurement corresponding to each rack plate 15-1 to 15-n. For example, the flow rate of the cooling air corresponding to each rack plate 15-1 to 15-n is changed by narrowing the space between the rack plate 15-1 to 15-n and the wall surface 7 as it goes downward. Can be adjusted. In addition, like the example raised here, the space | interval of each rack board 15-1 to 15-n and the wall surface 7 is not limited to narrowing, so that it goes to the lower part.

  The plurality of rack plates 15-1 to 15-n are removed from the plurality of upright support members 14, and are arranged so that the gap with the wall surface 7 is equal to the determined interval. 14 is fixed.

  The battery rack 1 corresponds to a rack plate among the plurality of rack plates 15-1 to 15-n when the gap between the plurality of rack plates 15-1 to 15-n and the wall surface 7 is relatively large. The flow rate becomes smaller than the flow rate corresponding to the rack plate below the rack plate. The battery rack 1 corresponds to a rack plate among the plurality of rack plates 15-1 to 15-n when the gap between the plurality of rack plates 15-1 to 15-n and the wall surface 7 is relatively small. The flow rate becomes larger than the flow rate corresponding to the rack plate below the rack plate. The battery rack 1 configured by such a battery rack installation method is used to supply cooling air to the plurality of secondary battery modules 17-1 to 17-m mounted on the plurality of rack plates 15-1 to 15-n. The secondary battery modules 17-1 to 17-m can be appropriately and uniformly cooled. Since the plurality of secondary battery modules 17-1 to 17-m can be uniformly cooled, the temperature rise can be suppressed and deterioration can be suppressed. Therefore, the characteristics of each secondary battery module can be maintained relatively the same. , Charging and discharging can be performed with the same capacity.

  The flow rate of each cooling air corresponding to each rack plate 15-1 to 15-n among the plurality of rack plates is measured using an actual machine, and the interval between each rack plate and the wall surface 7 of the container 3 can be determined. it can. Similarly, when the flow rate of the cooling air is measured, the battery rack 1 that appropriately and uniformly cools the plurality of secondary battery modules 17-1 to 17-m can be manufactured.

  The plurality of secondary battery modules 17-1 to 17-m are used by being grouped into a plurality of units 45-1 to 45-2 as shown in FIG. ing. The plurality of rack plates 15-1 to 15-n are also grouped into a plurality of units 45-1 to 45-2. An arbitrary unit among the plurality of units 45-1 to 45-2 includes a plurality of unit rack plates 46-1 to 46-4 grouped from the plurality of rack plates 15-1 to 15-n. . The plurality of rack plates 15-1 to 15-n are arranged so that each of the plurality of units 45-1 to 45-2 is grouped, that is, the plurality of unit rack plates 46-1 to 46-4 are arranged. The unit rack plate belonging to another unit is not arranged between the uppermost unit rack plate 46-1 disposed on the uppermost side and the lowermost unit rack plate 46-4 disposed on the lowermost side. Are arranged side by side. In each of the unit rack plates 46-1 to 46-4, only a plurality of secondary battery modules belonging to one unit among the plurality of secondary battery modules 17-1 to 17-m are placed.

  The battery rack 1 can facilitate the management and handling of the plurality of secondary battery modules by arranging the plurality of secondary battery modules belonging to one unit as a group.

  In addition, the plurality of secondary battery modules belonging to one unit have a plurality of units so that the number of secondary battery modules placed on the uppermost unit rack plate 46-1 disposed on the uppermost side is minimized. It is mounted on the rack plates 46-1 to 46-4. The battery rack 1 has a plurality of secondary battery modules placed in this manner, so that the center of gravity can be lowered and the battery rack 1 is not easily toppled and can appropriately support the plurality of secondary battery modules.

  Each of the plurality of units 45-1 to 45-2 further includes a current sensor 48 and a battery monitoring circuit 47 (BMU, Battery Management Unit). The current sensor 48 measures currents flowing through the plurality of secondary battery modules belonging to one unit. The current sensor 48 is formed in the same shape as the secondary battery module 17-j, and is placed on any of the plurality of unit rack plates 46-1 to 46-4. The battery monitoring circuit 47 monitors the state of the plurality of secondary battery modules belonging to one unit, and stops charging / discharging of the secondary battery module having an abnormality among the plurality of secondary battery modules. The battery monitoring circuit 47 is placed at the end of the lowermost lowermost unit rack plate 46-4 where the secondary battery module is not placed. That is, the battery monitoring circuit 47 is orthogonally projected onto a certain horizontal plane. The plurality of secondary battery modules are placed on the lowermost unit rack plate 46-4 so as not to overlap with a figure orthogonally projected onto the horizontal plane.

  The battery rack 1 has a battery monitoring circuit 47 mounted on the lowermost unit rack plate 46-4 on the lowermost side, so that the center of gravity can be lowered and the battery rack 1 is not easily collapsed. Can be supported.

  FIG. 10 shows another embodiment of the battery rack. In the battery rack 51, the plurality of rack plates 15-1 to 15-n of the battery rack 1 in the above-described embodiment are replaced with the other plurality of rack plates 52-1 to 52-n. The plurality of rack plates 52-1 to 52-n are formed such that the distance between the upper rack plate and the wall surface 7 increases. That is, the distance between one rack plate 52-s and the wall surface 7 among the plurality of rack plates 52-1 to 52-n is the same as the rack plate 52-t and the wall surface arranged below the rack plate 52-s. It is larger than the interval with 7. In the battery rack 51, a cooling gap 53 is formed between the plurality of rack plates 52-1 to 52-n and the wall surface 7.

  The battery rack 51 can be configured by joining a plurality of additional plates having different lengths to the edges on the wall surface 7 side of the plurality of rack plates 15-1 to 15-n of the battery rack 1. .

  When the gap between the plurality of rack plates 52-1 to 52-n and the wall surface 7 is relatively narrow, the cooling gap 53 has a higher static pressure toward the upper part when cooling air is supplied from the upper part. The battery rack 51 can supply substantially the same amount of cooling air to the upper portions of the plurality of rack plates 52-1 to 52-n even when the static pressure is higher as the upper portion of the cooling gap 53, and the plurality of secondary The battery modules 17-1 to 17-m can be uniformly cooled. In particular, the battery rack 51 is a case where the gap between the plurality of rack plates 52-1 to 52-n and the wall surface 7 can be set large, and the flow rate of the cooling air supplied to the cooling gap 53 varies. When it is large, the robustness can be improved and the effect of uniformly cooling the plurality of secondary battery modules 17-1 to 17-m can be improved.

  The plurality of upright support members 14 can be replaced with a structure formed from another shape different from the ladder shape. The plurality of upright support members 14 can be formed in a plate shape. The battery rack in which the plurality of upright support members 14 are formed in a plate shape is also in contact with the wall surface 7 and fixed in the same manner as the battery racks 1 and 51 described above. 17-1 to 17-m can be appropriately supported, and the plurality of secondary battery modules 17-1 to 17-m can be appropriately cooled.

1: Battery rack 2: Lithium secondary battery system 3: Container 7: Wall surface 8: Air conditioner 10: Duct 14: Plural upright support members 15-1 to 15-n: Plural racks (each rack) plate 17- 1 to 17-m: a plurality of secondary battery modules 18: a cooling gap 33: a plurality of rack plate claws 41: a fixing jig 43: a plurality of fixing jig claw plates 51: a battery rack 52-1 to 52-n : Multiple racks (each rack) 53: Clearance for cooling

Claims (11)

A plurality of upright support members fixed inside the container;
A plurality of rack plates on which a plurality of secondary battery modules are placed;
Each rack plate of the plurality of rack plates has the plurality of uprights so that a cooling gap through which cooling air for cooling the plurality of secondary battery modules passes is disposed between the wall surfaces inside the container. A battery rack fixed to the support member.   2. The cooling gap is formed such that the cooling air flow rate corresponding to each rack plate is equal in a state where the secondary battery module is placed on each rack plate. Battery rack. The plurality of rack plates are arranged in the vertical direction,
Among the plurality of rack plates, a gap between an arbitrary rack plate and a wall surface inside the container is between a lower rack plate disposed below the arbitrary rack plate and a wall surface inside the container. The battery rack according to claim 1, wherein the battery rack is larger than the gap. Each rack plate of the plurality of rack plates is formed with a plurality of rack plate claws,
The plurality of rack plate claws are fitted into the plurality of secondary battery modules mounted on the rack plates of the plurality of secondary battery modules, respectively. The battery rack described in one item. A plurality of fixing jigs corresponding to the plurality of rack plates;
An arbitrary fixing jig among the plurality of fixing jigs is
A band-shaped member fixed to a rack plate corresponding to the arbitrary fixing jig among the plurality of rack plates;
A plurality of fixing jig claw plates fixed to the belt-shaped member;
The plurality of fixing jig claw plates are respectively fitted to a plurality of secondary battery modules mounted on the rack plate among the plurality of secondary battery modules. A battery rack as described in any one of the above. The plurality of rack plates are grouped into a plurality of units,
A plurality of unit rack plates belonging to an arbitrary unit among the plurality of rack plates are:
An uppermost unit rack plate disposed on the uppermost side;
A lower unit rack plate disposed below the uppermost unit rack plate,
The plurality of secondary battery modules are mounted on the plurality of unit rack plates so that the number of secondary battery modules mounted on the uppermost unit rack plate among the plurality of secondary battery modules is minimized. The battery rack according to any one of claims 1 to 5, wherein the battery rack is placed. A plurality of battery monitoring circuits corresponding to the plurality of units;
The battery monitoring circuit corresponding to the arbitrary unit of the plurality of battery monitoring circuits includes the plurality of secondary battery modules mounted on the plurality of unit rack plates of the plurality of secondary battery modules. The battery rack according to claim 6, wherein the battery rack is controlled and placed on a lowermost unit rack plate disposed on a lowermost side among the plurality of unit rack plates. A method for installing a secondary battery in which the plurality of secondary battery modules are mounted on the battery rack according to any one of claims 6 to 7.
Grouping the plurality of rack plates into a plurality of units;
The plurality of secondary battery modules are mounted on the plurality of rack plates so that the number of secondary battery modules mounted on the uppermost unit rack plate among the plurality of secondary battery modules is minimized. A secondary battery installation method comprising: A cooling method for cooling the plurality of secondary battery modules using the battery rack according to any one of claims 1 to 7,
Placing the plurality of secondary battery modules on the plurality of rack plates;
A cooling method for a secondary battery comprising: feeding the cooling air into the cooling gap. A battery rack according to any one of claims 1 to 7,
The plurality of secondary battery modules;
A container in which a wall surface inside the container is formed;
A secondary battery system comprising: an air conditioner that sends cooling air into a cooling gap formed between the plurality of rack plates and a wall surface inside the container. A plurality of upright support members fixed inside the container;
A plurality of rack plates on which a plurality of secondary battery modules are placed;
Among the plurality of racks, each rack plate is arranged between the plurality of uprights such that a cooling gap through which cooling air for cooling the plurality of secondary battery modules passes is disposed between the rack plates. A battery rack installation method comprising a battery rack fixed to a support member,
A cooling gap through which cooling air passes is formed between each rack plate and the wall surface inside the container,
A battery rack installation method comprising: changing a gap between each rack plate and a wall surface inside the container based on a flow rate corresponding to each rack plate.

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