KR20170125629A - Energy storage module - Google Patents

Abstract

According to an aspect of the present invention, an energy storage module includes: a cell assembly which has two or more energy storage cells arranged in parallel in one direction and electrically connected in series, and has positive and negative terminals formed in the same direction; a first side surface case which has two or more case blocks connected in the parallel arrangement direction of the energy storage cells to surround a side surface of the cell assembly; a second side surface case which has the same structure with the first side surface case, is coupled to the first side surface case while facing the first side surface case, forms a storage space corresponding to the exterior shape of the energy storage cells, and surrounds the other side surface of the cell assembly; two or more side surface coupling members which connect the case blocks respectively included in the first and second side surface cases in the parallel arrangement direction of the energy storage cells to fix the same; and two covers covering the front and back surfaces in accordance with the coupling of the first and second side surface cases.

Description

[0001] ENERGY STORAGE MODULE [0002]

The present invention relates to an energy storage module, and more particularly to an energy storage module with increased space efficiency.

In general, an Ultra Capacitor is also called an "Super Capacitor" and is an energy storage device having an intermediate characteristic between an electrolytic capacitor and a secondary battery. The ultracapacitor has high efficiency and a semi-permanent lifetime characteristic and can be used in combination with the secondary battery, and can also be substituted for the secondary battery. In addition, the ultra capacitor has fast charging and discharging characteristics and can be used as an auxiliary power source for mobile communication information devices such as a cell phone, a notebook, and a PDA. Ultracapacitors are also used to replace batteries for applications where maintenance is not easy and long service life is required.

These ultracapacitors are generally assembled and used several times. An energy storage module in which several ultracapacitors are assembled is typically as shown in Fig. 1 is a view showing a configuration of an energy storage module according to the prior art. 1, an energy storage module according to the related art includes a case 20 accommodating an ultracapacitor array 10, an ultracapacitor array 10, and a cover 20 covering an upper and a lower opening of the case 20, (30, 40). In the ultracapacitor array 10, a plurality of ultracapacitors are formed by connecting the electrode terminals by the bus bar 11 and being coupled by a nut. One such energy storage module typically has a voltage of 48V.

Ultracapacitors are also used as main or auxiliary power sources for UPS (Uninterrupted Power Supply) which require high voltage. However, since one energy storage module as shown in FIG. 1 has a voltage of 48V as described above, a plurality of energy storage modules must be connected in series in order to be used at a high voltage such as a UPS. In order to electrically connect a plurality of energy storage modules in series, the positive and negative terminals projected to the outside of the top cover of two adjacent energy storage modules should be connected. However, since the energy storage module shown in FIG. 1 is arranged in parallel in various directions in the horizontal and vertical directions, in order to electrically connect a plurality of energy storage modules in series, a long connector must be used Connection between terminals is not easy. Alternatively, if the bus bar is used, two types of energy storage modules having different positions of the terminals must be manufactured, which increases the manufacturing cost. Therefore, when installed inside a space-restricted cabinet, the space efficiency is low. In addition, since the conventional energy storage module is arranged in parallel in various directions in the horizontal and vertical directions, when the energy storage modules are stacked in the cabinet, they are weak to vibration.

Korean Patent No. 10-1341474 (published on December 13, 2013)

Disclosure of the Invention The present invention has been proposed in order to solve the above problems and provides an energy storage module for electrically connecting a plurality of energy storage modules in series, There is a purpose.

Other objects and advantages of the present invention will become apparent from the following description, and it will be understood by those skilled in the art that the present invention is not limited thereto. It will also be readily apparent that the objects and advantages of the invention may be realized and attained by means of the instrumentalities and combinations particularly pointed out in the appended claims.

According to an aspect of the present invention, there is provided an energy storage module including at least two energy storage cells arranged in parallel in one direction, electrically connected in series, and having positive and negative terminals formed in the same direction assembly; At least two case blocks are connected in parallel to the energy storage cells to surround one side of the cell assembly; A second side case having the same structure as the first side case and opposed to the first side case to form a receiving space corresponding to an outer shape of the energy storage cell and to surround another side of the cell assembly; At least two side case engaging members connecting and fixing at least two or more case blocks included in each of the first and second side cases in parallel arrangement directions of the energy storage cells; And two covers covering the front and rear openings in accordance with the combination of the first and second side cases.

Wherein the case blocks include: a plurality of convex portions having an arc shape identical to an outer shape of the energy storage cell; And two case block connecting portions formed at both ends of the plurality of convex portions, wherein each of the at least two side case connecting members includes a case block connecting portion of two case blocks connected in parallel to the energy storing cells, Can be combined and fixed.

The two case block connection portions and the side case coupling members connected in parallel arrangement directions of the energy storage cells and the side case coupling members may be bolted together.

Through holes are formed in a row at regular intervals in each of the two case block connecting portions connected in parallel to the energy storage cells, and the side case coupling member is provided with two rows of non-through holes at positions corresponding to the non- A through hole may be formed.

A first guide groove may be formed in a surface of the case block connecting portion which is coupled to the side surface case engaging member and is opposite to the terminal of the energy storage cell and a first sealing member may be inserted into the first guide groove .

The position of the bolting engagement may be between the convex portion and the first guide groove.

The case block connecting portions formed at both ends of the first side case and the case block connecting portions formed at both ends of the second side case may be bolted to each other.

Wherein at least one surface of the case block connecting portion formed at both ends of the first side case and opposite to the case block connecting portion formed at both ends of the second side case has a second guide And a second sealing member may be inserted into the second guide groove.

And the second guide groove may be positioned between the position of the bolting engagement and the convex portion.

And a third sealing member between the first and second side cases and the two covers.

The third sealing member may be disposed along the front and rear surfaces in a shape corresponding to the shapes of the front and rear surfaces of the first and second side cases.

The case blocks may be L-shaped.

The energy storage module of the present invention facilitates electrical series connection between a plurality of energy storage modules, in which the energy storage cells are arranged in parallel in one direction and electrically connected in series and the positive and negative terminals are formed in the same direction .

In the energy storage module of the present invention, since the energy storage cells are arranged in parallel in one direction and electrically connected in series, and the positive and negative terminals are formed in the same direction, a large number of energy storage cells can be installed inside the space- Thereby enhancing the space efficiency.

The energy storage module of the present invention facilitates capacity expansion of the energy storage module by using a method of connecting and fixing a plurality of case blocks with a side case coupling member in forming a side case by connecting a plurality of case blocks.

1 is a view showing a configuration of an energy storage module according to the prior art.
2 is an exploded perspective view of an energy storage module according to an embodiment of the present invention.
3 is an assembled perspective view of the energy storage module of FIG.
4 is a diagram illustrating a connection between energy storage cells according to another embodiment of the present invention.
5 is a cross-sectional view taken along a line II-II 'in FIG.
6 is a cross-sectional view of a case block according to an embodiment of the present invention.
7 is a perspective view of a case block according to an embodiment of the present invention.
8 is a view showing a case block according to another embodiment of the present invention.
9 is a perspective view of a cabinet according to an embodiment of the present invention.
10 is a view illustrating a plurality of energy storage modules stacked according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims are to be construed in accordance with the technical idea of the present invention based on the principle that the concept of a term can be properly defined in order to describe its own invention in the best way It must be interpreted as meaning and concept. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 2 is an exploded perspective view of an energy storage module according to an embodiment of the present invention, FIG. 3 is an assembled perspective view of the energy storage module of FIG. 2, And Fig. 5 is a cross-sectional view taken along a line II-II 'in Fig.

2 to 5, the energy storage module 200 according to the present embodiment includes a cell assembly 210 in which at least two energy storage cells 211 are electrically connected in series, four case blocks A case coupling member 230 for coupling and fixing the case block 220, and covers 240 and 250. [

In the cell assembly 210, at least two energy storage cells 211 are electrically connected in series. The energy storage cell 211 may be an ultracapacitor. In describing the present embodiment, the energy storage cell is described as an ultracapacitor. Ultra capacitors have fast charging / discharging characteristics and thus can be used not only as auxiliary power sources for mobile communication information devices such as mobile phones, notebook computers and PDAs, but also for electric vehicles and hybrid cars, solar battery power supplies and uninterruptible power supplies Power Supply: UPS) or auxiliary power supply. The ultracapacitor 211 may be in the form of a cylinder. However, the energy storage cell may be a cell capable of storing electric energy such as a secondary battery and a battery.

2 to 4, the energy storage cells 211 constituting the cell assembly 210 are arranged in parallel in an even number of rows in one direction and electrically connected in series. For example, six rows in this embodiment. In each column, a plurality of energy storage cells 211 are arranged in series and electrically connected in series. In this embodiment, three energy storage cells 211 are connected in series. Therefore, the cell assembly 210 has a 3 x 6 array structure. For example, a nut 262 and a bus bar 261, between the ultracapacitors disposed in parallel at the outermost adjacent two columns. 4, the positive terminal of the first ultra capacitor and the negative terminal of the second ultracapacitor are connected to the bus bar 430 and the nuts 450, respectively, in a state where the ultracapacitors 211 are disposed in parallel in one direction. ) May be used to form the cell assembly 210 by electrically connecting in series. Therefore, the cathode terminal 210a and the cathode terminal 210b of the cell assembly 210 are finally protruded in the same direction.

Referring to FIGS. 2 and 3, four case blocks 220 of the same type are combined to cover the side surface of the energy storage cell 211. That is, the two case blocks 220 connected in parallel to the energy storage cells 211 form a first side case that encloses one side of the cell assembly 210. The other two case blocks 220 connected in parallel to the energy storage cells 211 form a second side case surrounding the other side of the cell assembly 210. Therefore, the first side case and the second side case have the same structure. At this time, the two case blocks 220 constituting the first side case are connected and fixed by one side case engaging member 230 to cover one side of the cell assembly 210. The two case blocks 220 constituting the second side case are connected and fixed by the other side case coupling member 230 to cover the other side of the cell assembly 210.

The case block 220 can be manufactured by a general-purpose extruder using an aluminum panel. That is, when the aluminum panel is inserted into the side surface of a general-purpose extruder, the extruder pressurizes the aluminum panel and the case block 220 according to the embodiment of the present invention is manufactured according to the shape of the mold in the extruder. In the embodiment of the present invention, the cell assembly 210 has a structure in which the ultracapacitors 211 are arranged in 3 × 6, and the length of the side case accommodating the ultracapacitors 211 is about 418 mm. However, when a case of 300 mm or more is manufactured by pressurizing an aluminum panel by a general-purpose extruder, the pressure can not be transmitted to both ends of the aluminum panel, and thus both ends of the case are defective. For this reason, in the embodiment of the present invention, the two case blocks 220 are separately manufactured without manufacturing the side case integrally, and then connected and fixed by the side case coupling member 230 as described above, . Since the ultracapacitor is also used as a main power source or an auxiliary power source such as a UPS (Uninterrupted Power Supply) requiring high voltage, the cell assembly 210 may have an additional 3 x 8 array structure other than the 3 x 6 array structure according to the embodiment of the present invention, , 3 x 10, and so on. In the embodiment of the present invention, the case block 220 made of a general-purpose extruder is connected to the side case coupling member 230 to manufacture the side case, so that it is possible to easily cope with such a high rated capacity.

Specifically, the two case blocks 220 and the side case coupling member 230 connected in parallel to the energy storage cells 211 are bolted together. The first side case and the second side case are opposed to each other and both ends are in direct contact with each other. The case block 220 formed at both ends of the first side case and the case block 220 formed at both ends of the second side case opposite to the case block 220 are bolted together.

The covers 240 and 250 cover the open front and back sides according to the combination of the first side case and the second side case. That is, the four case blocks 220 cover only the side surfaces of the cell assembly 210, and therefore cover the terminal directions of the cell assemblies 210 housed in the case block 220, that is, the front and rear surfaces, with the covers 240 and 250 . As described above, in the cell assembly 210, the plurality of energy storage cells 211 are connected in series while being arranged in even-numbered columns, so that the final cathode terminal 210a and the cathode terminal 210b of the cell assembly 210 are connected in the same direction Respectively. The first lid 240 covers the front surface of the cell assembly 210, that is, the cathode terminal 210a and the cathode terminal 210b. The first lid 240 covers the cathode terminal 210a and the cathode terminal 210b, And the second lid 250, which covers the opposite rear surface, is not provided with a hole. The positive electrode terminal 210a and the negative electrode terminal 210b of the cell assembly 210 protrude through the holes 242 of the first cover 240 and are fixed by the nuts 270. As will be described later, when the energy storage module 200 is installed in the cabinet, the four corners of the first cover 240 can be fastened to the cabinet, The size of the first lid 240 is preferably larger than that of the second lid 250. Holes 243 and 253 for bolting are formed in the first and second lids 240 and 250 at positions corresponding to the tabs 613a of the case block 220.

On the other hand, as shown in FIG. 5, a heat dissipation pad 510 is installed on the inner side surface of each case block 220. The heat dissipation pad 510 is positioned between the ultracapacitor 211 of the cell assembly 210 and the case block 220 when the cell assembly 210 is inserted into the internal space formed by the case blocks 220. The heat radiating pad 510 may be attached to the inner surface of the case block 220 in a direction in which the electrode of the ultracapacitor 211 is formed. The heat-radiating pad 510 may include a heat-conducting filler for heat transfer, for example, metal powder or ceramic powder. Examples of the metal powder may be any one or a mixture of two or more of aluminum, silver, copper, nickel and tungsten. Further, examples of the ceramic powder may be silicone, graphite, and carborn black. The material of the heat radiation pad 510 is not limited to the material of the embodiment of the present invention.

FIG. 6 is a cross-sectional view of a case block according to an embodiment of the present invention, and FIG. 7 is a perspective view of a case block according to an embodiment of the present invention.

6 and 7, the case block 220 may have an L shape and may have a receiving portion 618 corresponding to the external shape of the ultracapacitor 211. When the ultracapacitor 211 has a cylindrical shape, the inner surface of the case block 220, which is in contact with the outer surface of the ultracapacitor 211, may have a cylindrical rounded shape. The four case blocks 220 having the L shape are combined to finally form a cylindrical inner space.

6, the case block 220 includes a plurality of convex portions 611 and convex portions 611 having the same arc shape as the external shape of the ultracapacitor 211 A concave portion 612 formed between the convex portion 611 and the convex portion connecting portion 613 and a case block connecting portion 614 and 615 connecting the case block 220 to each other.

The plurality of protrusions 611 have the same arc shape as the outer shape of the ultracapacitor 211 to form the accommodating portion 618 for accommodating the ultracapacitor 211 and the heat radiating pad 510 Respectively. The heat radiating pad 510 discharges the heat generated in the ultracapacitor 211 to the convex portion 611 and also performs an insulating function between the ultracapacitor 211 and the convex portion 611. These convex portions 611 are connected by the convex portion connecting portion 613 and the convex portion connecting portion 613 is formed with a tab 613a for fixing the covers 240 and 25. The tab 613a is a structure for a bolting process, and a thread is formed on the inner circumferential surface thereof, and a bolt for fixing the case block 220 and the covers 240 and 250 is inserted.

The concave portion 612 is formed between the convex portion 611 and the convex portion 613. The concave portion 612 is formed by folding a part of the convex portion 611 outward to secure an insulation distance between the ultracapacitor 211 and the case block 220. A plurality of heat sinks 617 are vertically installed in the concave portion 612 at regular intervals to discharge heat generated in the ultracapacitor 211 to the outside. The heat sinks 617 are vertically installed at regular intervals in order to increase heat radiation efficiency through the air flow between the heat sinks 617. A plurality of heat dissipating plates 617 are provided to widen the heat dissipating area. At this time, the height of the heat radiating plate 617 is formed to be equal to the height of the convex portion connecting portion 613.

The convex portions of the plurality of convex portions 611 are provided with case block connecting portions 614 and 615. The case block connectors 614 and 615 connect the cable block 220. 7, at least one through hole 614b is longitudinally formed in the case block connecting portion 614, and at least one non-through hole 614b is formed in the case block connecting portion 615 in the longitudinal direction. 615b are formed in a row. The non-through holes 615b may be formed with threads on the inner peripheral surface.

The case block connecting portions 614 of the two case blocks 220 which are coupled to each other face each other and the two case block connecting portions 614 which are abutted to each other are fixed with bolts and nuts through the through holes 614b. When the two case blocks 220 are connected to each other in the parallel arrangement direction of the energy storage cells 211 to form the side case, the two case block connecting portions 615 are not directly bolted together, ).

As shown in FIG. 2, two rows of through holes 231 parallel to the electrode direction, that is, the longitudinal direction, of the energy storage cell 211 are formed in the side case coupling member 230. The positions of the two rows of through holes 231 in the side case connecting member 230 correspond to the positions of the non-through holes 615b of the case block connecting portion 615. [ The through holes 231 in one row of the two rows of the side case coupling members 230 are connected to the first case block connection portions 615 when the two case block connection portions 615 are connected in the parallel arrangement direction of the energy storage cells 211. [ Hole 615b of the second case block connecting portion 615 and the through hole 231 of the remaining column corresponds to the non-through hole 615b of the second case block connecting portion 615. [ The bolts are inserted into the two rows of through holes 231 of the side case coupling member 230 and the non-through holes 615b of the two case block coupling portions 615 in a state where the two case block coupling portions 615 are connected The two case block connecting portions 615 are fixed.

Meanwhile, when the case blocks 220 are coupled, foreign matter (e.g., moisture) may be introduced from the outside into the connecting portion of the case blocks 220. 6 and 7, guide grooves 614a and 615a are formed in the case block connecting portions 614 and 615 in the longitudinal direction, and sealing grooves 614a and 615a are formed in the guide grooves 614a and 615a, Member is inserted. The case block connecting portion 614 is formed with a guide groove 614a on the surface facing the other case block connecting portion 614 and the case block connecting portion 615 has a guide groove 615a are formed.

Foreign matter may be introduced through the through hole 614b so that the guide groove 614a in the case block connecting portion 614 is preferably formed between the through hole 614b and the convex portion 611 . Conversely, in the case block connecting portion 615, it is preferable that the case block connecting portion 615 is formed on the side opposite to the non-through hole 615b and the convex portion 611, that is, on the opposite side. It is preferable that the sealing member inserted into the guide grooves 614a and 615a has elasticity and its thickness is larger than the depth of the guide grooves 614a and 615a. So that the airtightness can be maintained and the inflow of foreign matter can be prevented more effectively.

Although not shown in the drawing, a sealing member may be provided on the mating surfaces of the lids 240 and 250 and the case block 220. [ The sealing member is preferably formed in a shape corresponding to the shapes of the front and rear surfaces of the case block 220 and is disposed along the front and rear surfaces of the case block 220. When the sealing member is a rectangular shape having a size corresponding to that of the lids 240 and 250, lifting of the lids 240 and 250 and the case block 220 at the edges of the sealing member occurs during bolting.

As described above, the energy storage module 200 according to the present embodiment includes a plurality of energy storage cells 211 arranged in parallel in one direction and electrically connected in series to finally connect the positive electrode terminals 210a and the anode terminal 210b are arranged in the same line and protrude in the same direction. Therefore, when a plurality of energy storage modules 200 are stacked in a cabinet and connected in series, space efficiency can be improved while facilitating connection between terminals. This will be described in detail with reference to Figs. 9 and 10 below.

The above-described embodiment describes that the cell assembly 210 is accommodated by coupling four case blocks 220 having the same structure of 'L' shape. However, the present invention is not limited thereto, and a straight case block may be provided between the two 'L' -shaped case blocks 220 connected in the parallel arrangement direction of the energy storage cells 211 in the first and second side cases At least one can be connected. 8 is a view showing a case block according to another embodiment of the present invention, and is a straight case block. 8, the straight type case block includes a plurality of convex portions 611 having the same arc shape as the external shape of the ultracapacitor 211, convex portions 611 connecting the convex portions 611, A connecting portion 613 and a concave portion 612 formed between the convex portion 611 and the convex portion connecting portion 613. This structure is similar to that of the case block 200 of FIG. 6 and FIG. 7 ). However, both ends of the straight type case block shown in FIG. 8 include case block connecting portions 615 having the same structure.

Therefore, in the first and second side cases, an L-shaped case block is disposed at both ends in the parallel arrangement direction of the energy storage cells 211, and a case block of a straight shape as shown in Fig. A large number of energy storage cells 211 can be accommodated by connecting and fixing one or more of them with the side case engaging member 230. [

9 is a perspective view of a cabinet according to an embodiment of the present invention. 9, the cabinet 900 according to the present embodiment includes four frames 911 erected to hold a skeleton in a rectangular parallelepiped shape, two side panels 914 coupled along the sides of the frame 911 And a rear panel 915. An upper panel 912 and a lower panel 913 coupled to the upper and lower portions of the frame 911 and a door 916 for opening and closing the front surface of the cabinet 900 are provided. They may all be metallic materials. The upper panel 912 may be provided with at least one open portion so that at least one cooling fan can be installed if necessary. The upper panel 912, the lower panel 913, A plurality of wiring holes may be provided.

In the four frames 911, a plurality of fastening holes 911a are formed in a row in the vertical direction at regular intervals in the direction in which the door 916 is installed. Although it is described in the present embodiment that the four frames 911 are formed with the fastening holes 911a, the fastening holes 911a may be formed only on the two front frames on the door 916 side. 9, in the open state of the door 916, a plurality of energy storage modules 200 are inserted into the cabinet 900. As shown in Fig. At this time, the fastening holes 241 formed at the four corners of the front cover 240 of each energy storage module 200 and the fastening holes 911a formed in the frame 911 are provided to correspond to each other. The energy storage module 200 is installed inside the cabinet 900 by inserting the bolts 921 into the fastening holes 241 and 911a and fixing them with the nuts. At this time, when a plurality of energy storage modules 200 are inserted and stacked in the cabinet 900, the positions of the terminals of the energy storage modules 200 adjacent to each other are opposite to each other.

10 is a view illustrating a plurality of energy storage modules 200 stacked in a vertical direction in a cabinet 900 according to an embodiment of the present invention. As shown in FIG. 10, the terminal arrangement positions of the adjacent energy storage modules 200 are opposite to each other. For example, the uppermost energy storage module 200 has a positive terminal 210a on the right side and a negative terminal 210b on the left. On the other hand, in the second energy storage module 200, the cathode terminal 210a is located on the left side and the cathode terminal 210b is located on the right side. Each time the energy storage module 200 is inserted into the cabinet 900, the energy storage module 200 may be inserted upside down. When the plurality of energy storage modules 200 are stacked in the vertical direction, the anode terminal 210a and the cathode terminal 210b of the adjacent energy storage module 200 are disposed adjacent to each other in the vertical direction, When the bus bars 1010 are connected in series, the bus bars 1010 in the form of a straight line can be connected in the vertical direction. Therefore, electrical series connection is easier than connection through a harness or the like. By using the bus bar 1010, an acceptable current is higher than that of a harness or the like, and it is easy to tighten. Also, since a large number of energy storage modules 200 can be installed in the cabinet 800 having a limited space, space efficiency can be improved and high voltage can be coped with.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood that various modifications and changes may be made without departing from the scope of the appended claims.

200: Energy storage module
210: cell assembly
211: Energy storage cell
220: Case block
230: side case coupling member
240, 250: cover
241: fastening hole

Claims (12)

A cell assembly in which at least two energy storage cells are arranged in parallel in one direction and are electrically connected in series and having positive and negative terminals in the same direction;
At least two case blocks are connected in parallel to the energy storage cells to surround one side of the cell assembly;
A second side case having the same structure as the first side case and opposed to the first side case to form a receiving space corresponding to an outer shape of the energy storage cell and to surround another side of the cell assembly;
At least two side case engaging members connecting and fixing at least two or more case blocks included in each of the first and second side cases in parallel arrangement directions of the energy storage cells; And
And two covers covering the front and rear openings in accordance with the combination of the first and second side cases. The method according to claim 1,
The case blocks,
A plurality of convex portions having the same arc shape as the outer shape of the energy storage cell; And two case block connecting portions formed at both ends of the plurality of convex portions,
Wherein each of the at least two side case engaging members comprises:
Wherein the energy storage cell is fixedly coupled to a case block connection portion of two case blocks connected in parallel to the energy storage cells. 3. The method of claim 2,
Wherein the two case block connecting portions and the side case coupling members connected to each other in the parallel arrangement direction of the energy storage cells are bolted to each other. The method of claim 3,
In each of the two case block connecting portions connected in parallel arrangement directions of the energy storage cells, non-through holes are formed in a row at regular intervals,
Wherein the side case coupling member is formed with two through holes at positions corresponding to the positions of the non-through holes. The method of claim 3,
A first guide groove is formed in a surface of the case block connecting portion which is coupled to the side case coupling member and is opposite to the case block coupling portion in a direction in which the terminal of the energy storage cell is formed,
And a first sealing member is inserted into the first guide groove. 6. The method of claim 5,
Wherein the position of the bolting engagement is between the convex portion and the first guide groove. 3. The method of claim 2,
Wherein the case block connecting portion formed at both ends of the first side case and the case block connecting portion formed at both ends of the second side case are coupled to each other by bolting. 8. The method of claim 7,
Wherein at least one surface of the case block connecting portion formed at both ends of the first side case and opposite to the case block connecting portion formed at both ends of the second side case has a second guide And a second sealing member is inserted into the second guide groove. 9. The method of claim 8,
And the second guide groove is located between the position of the bolting engagement and the convex portion. The method according to claim 1,
And a third sealing member between the first and second side cases and the two covers. 11. The method of claim 10,
Wherein the third sealing member is disposed along the front and rear surfaces in a shape corresponding to a shape of a front surface and a rear surface of the first and second side cases. 12. The method according to any one of claims 1 to 11,
Wherein the case blocks are L-shaped.

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