KR20220076056A - A housing for cylindrical battery cell - Google Patents

Abstract

The present invention relates to a cylindrical battery cell housing, and more particularly, to a cylindrical battery cell housing having a cylindrical cell including an air-cooled cooling flow path that minimizes moisture inflow, in the cylindrical battery cell housing to suppress moisture inflow , a plurality of cylindrical battery cells 400; an upper housing part 100 and a lower housing part 200 having a plurality of through-holes continuously formed along the height direction and being vertically coupled to each other to accommodate the cylindrical battery cell 400; an upper cap part 300 for closing the upper part of the upper housing part 100; Including, but the outer diameter of the cylindrical battery cell 400 is smaller than the diameter of the first virtual circle connecting each center of any three of the plurality of through holes to the outer peripheral surface, and concentric with the first virtual circle and providing a cylindrical battery cell housing, characterized in that it is larger than a diameter of a second virtual circle having a minimum diameter among a plurality of virtual circles circumscribing the inner circumferential surface of the three through-holes, wherein moisture flowing into the semi-circular through-holes is a cylindrical battery cell There is an advantage in that the contact area with 400 can be discharged to the outside while being minimized.

Description

Cylindrical battery cell housing {A housing for cylindrical battery cell}

The present invention relates to a cylindrical battery cell housing, and more particularly, to a cylindrical battery cell housing having a cylindrical cell including an air-cooled cooling flow path that minimizes moisture inflow.

Cells used in battery packs for environmentally friendly vehicles currently being developed can be classified into pouch cells, prismatic cells, and cylindrical cells according to their shape.

Among these battery cells, the cylindrical cell is the most traditional type of battery cell that has been centered on laptops and mobile phones in the past.

Cylindrical cells have the advantage of being inexpensive and mass-produced compared to other battery cells, and many automakers are considering their application to vehicle batteries.

The importance of thermal management of the cell is further emphasized because the performance difference according to the temperature of the cell is clear.

On the other hand, the battery cooling method includes a water cooling type and an air cooling type.

An EV vehicle with a relatively large battery pack capacity requires a water cooling method as a cell cooling method, whereas an HEV vehicle with a relatively small capacity generally uses an air cooling method. At this time, a cooling flow rate is generated using a motor fan device such as a blower, and a cooling flow path is formed using a duct and a cell cartridge.

Since this air-cooling method is a method of cooling the vehicle by introducing air into the battery pack, the surface of the cell is inevitably exposed to the cooling passage in order to cool the cell. In this case, there is a possibility that moisture may directly flow into the battery pack through the duct, which is the path through which the air flows.

Therefore, it is necessary to maintain the cooling performance function and to minimize the moisture flowing into the module.

However, in the case of an air-cooling method to which a conventional cylindrical cell is applied, moisture may be directly introduced through the duct. If moisture enters and stays inside the module or a moisture path is formed with an external conducting part, there is a problem that the insulation performance may be deteriorated.

1 is prior art.

1 , in the conventional cylindrical cell housing, an upper case 11 and a lower case 12 are assembled with each other, and through-holes 21 and 22 for cooling are formed at the upper end of the upper case 11 .

FIG. 1(b) is a cross-section A-A in FIG. 1(a), through which moisture easily flows through the through holes 21 and 22, and accordingly, moisture onto the wide surface of the cylindrical battery cells 31 and 32 inside the cell housing. It can be seen that there was a problem that could be contacted.

JP 3782393 B1

An object of the present invention for overcoming the problems of the prior art as described above is to provide a cylinder having a cylindrical cell including an air-cooled cooling passage minimizing the inflow of moisture.

A cylindrical battery cell housing for suppressing moisture inflow, comprising: a plurality of cylindrical battery cells (400); an upper housing part 100 and a lower housing part 200 having a plurality of through-holes continuously formed along the height direction and being vertically coupled to each other to accommodate the cylindrical battery cell 400; an upper cap part 300 for closing the upper part of the upper housing part 100; Including, but the outer diameter of the cylindrical battery cell 400 is smaller than the diameter of the first virtual circle connecting the respective centers of the three adjacent through-holes among the plurality of through-holes to the outer circumferential surface, the first virtual circle and a cylindrical battery cell housing, characterized in that it is larger than a diameter of a second virtual circle having a minimum diameter among a plurality of virtual circles that are concentric with the inner peripheral surface of the three through-holes and circumscribe the inner circumferential surface of the three through-holes.

In addition, the end of the through-hole includes a cylindrical battery cell housing, characterized in that formed;

In addition, the upper cap portion 300 includes a cylindrical battery cell housing, characterized in that the opening is formed in which the protrusion is inserted.

In addition, the outer peripheral surfaces of the three cylindrical battery cells 400 adjacent to each other among the plurality of cylindrical battery cells 400 meet each other at a point dividing the outer peripheral surface of the cross section of the through hole into thirds. It includes a cylindrical battery cell housing. do.

In addition, the through hole includes a cylindrical battery cell housing, characterized in that it includes at least any one of a circular or semi-circular shape.

In addition, the cross-section of the protrusion includes a cylindrical battery cell housing, characterized in that it includes at least any one of a circular or semi-circular shape.

In addition, the opening includes a cylindrical battery cell housing, characterized in that it includes at least any one of a circular or semi-circular shape.

In addition, the lower housing 200 includes a cylindrical battery cell housing, characterized in that the discharge guide 230 is formed on the lower surface 201 of the housing.

In addition, it includes a cylindrical battery cell housing, characterized in that the support protrusion 240 is formed on the lower surface of the lower surface portion (201) of the lower housing (200).

In addition, the plurality of cylindrical battery cells 400 include a cylindrical battery cell housing, characterized in that a 3x2x3 arrangement.

According to the present invention as described above, there are the following effects.

First, even when moisture comes into contact with the plate part 310 , since the upper end of the circular protrusion protrudes higher than the plate part 310 , the strength of direct moisture inflow into the circular through-hole can be suppressed as much as possible.

Second, since a plurality of circular through-holes in the plate part 310 are provided in the upper cap part 300 to vertically penetrate the plate part 310 , the heat generated from the cylindrical battery cell 400 is effectively radiated to the outside. Allows battery performance to be maximized.

Third, moisture flowing into the semi-circular through-hole has an advantage in that it can be discharged to the outside while the contact area with the cylindrical battery cell 400 is minimized.

1 is a prior art
2 is an overall perspective view according to a preferred embodiment of the present invention;
3 is a top view according to a preferred embodiment of the present invention;
4 is a side view according to a preferred embodiment of the present invention;

Since the present invention can have various changes and can have various embodiments, specific embodiments are illustrated in the drawings and will be described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

In describing each figure, like reference numerals are used for like elements.

Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component. The term “and/or” includes a combination of a plurality of related listed items or any of a plurality of related listed items.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. shouldn't

First, the terms used in the description are summarized.

"Front" refers to the direction in which the upper housing front part 110 and the lower housing front part 210 are facing in FIG. 2, and "rear" is the opposite direction.

The term “front end” refers to the end of the “front”, and “rear end” refers to the end of the “rear”.

The “ground” is assumed to be an imaginary flat surface on which the cylindrical battery cell housing according to a preferred embodiment of the present invention is placed in a fixed position.

Here, being placed in the correct position may mean that the lower surface of the lower housing part 200 is in contact with the ground in a state in which the cylindrical battery cell housing is finally assembled.

“Transverse direction” refers to a direction perpendicular to “front” and parallel to the ground, and “longitudinal direction” refers to a direction perpendicular to “lateral direction” and parallel to the ground.

The “bottom side” refers to the side facing the “ground” and the “top side” is the opposite side.

The term “lower” refers to a boundary toward the “upper surface” at a predetermined distance from the “lower surface”, and “upper” refers to an area toward the “lower surface” at a predetermined distance from the “upper surface”.

“Front” refers to the end face of “front”, and “rear” refers to the opposite side.

“Side” or “one side” refers to any side other than “top” and “bottom”, and “front” may be included in “side” or “one side”.

The term “vertical direction” refers to a direction perpendicular to the “ground”.

“Left” refers to the left side in the direction from “rear” to “front” in the longitudinal direction, and “right” refers to the opposite direction.

On the other hand, the term “coaxial line” of an object means that the lines connecting the center points of each other are in a positional relationship in which they are located on the same line.

2 is an overall perspective view according to a preferred embodiment of the present invention.

In the cylindrical battery cell housing according to a preferred embodiment of the present invention, a plurality of cylindrical battery cells 400 are accommodated in the upper housing part 100 and the lower housing part 200 that are coupled to each other, and the upper cap part 300 is the upper part. It is coupled to the upper portion of the housing part 100 to close the uppermost end.

On the other hand, the electrode part 500 is provided to be spaced apart from each other by a predetermined distance in the front upper portion of the upper housing part 100 , and the electrode part 500 may include the first electrode part 501 and the second electrode part 502 . can

In more detail, the electrode part 500 may be provided on the upper end of the upper housing front part 110 .

The upper housing part 100 and the lower housing part 200 are vertically coupled to each other while having a plurality of through-holes continuously formed along the height direction to accommodate the cylindrical battery cell 400 .

The through-hole may also be understood as an opening.

The upper cap part 300 closes the upper part of the upper housing part 100 .

On the other hand, the outer diameter of the cylindrical battery cell 400 is smaller than the diameter of the first virtual circle connecting the respective centers of any three through holes among the plurality of through holes to the outer circumferential surface, has concentricity with the first virtual circle, and has three through holes. It may be preferable that the diameter of the second virtual circle having the smallest diameter among the plurality of virtual circles circumscribed with the inner circumferential surface of the hole is larger than the diameter of the second virtual circle.

The upper housing part 100 has an outer surface formed by an upper housing front part 110 , an upper housing right surface part 120 , an upper housing left surface part 130 , and an upper housing rear part 140 .

In more detail, the upper housing part 100 is formed with the upper housing front part 110 flat toward the front.

The upper housing rear portion 140 may be formed as a flat surface in the same manner as the upper housing front portion 110 at the rear of the upper housing portion 100 .

The upper housing right surface part 120 forms a right surface of the upper housing part 100 , and includes a first upper housing right flat part 121 , a second upper housing right flat part 122 , and a third upper housing right flat part 123 . ), a fourth upper housing right flat portion 124 , a first upper housing right curved portion 125 , a second upper housing right curved portion 126 , and a third upper housing right curved portion 127 . .

The through-holes formed in the upper housing part 100 and the lower housing part 200 may be continuously formed along the height direction, respectively, and the inner peripheral surfaces of these through-holes are the first upper housing right curved part 125 and the second upper part. Housing right curved part 126 , third upper housing right curved part 127 , first upper housing left curved part 135 , second upper housing left curved part 136 , and third upper housing left curved part 137 . ), and so on.

More specifically, the first upper housing right curved portion 125 is vertically long and narrowly formed between the first upper housing right flat portion 121 and the second upper housing right flat portion 122 .

The second upper housing right curved portion 126 is vertically long and narrowly formed between the second upper housing right flat portion 122 and the third upper housing right flat portion 123 .

The third upper housing right curved portion 127 is vertically long and narrowly formed between the third upper housing right flat portion 123 and the fourth upper housing right flat portion 124 .

Each of the first upper housing right curved portion 125, the second upper housing right curved portion 126 and the third upper housing right curved portion 127 has a half circle (hereinafter referred to as “hc” series) in cross section) can have

The first upper housing right flat portion 121 , the second upper housing right flat portion 122 , the third upper housing right flat portion 123 , and the fourth upper housing right flat portion 124 may be formed as flat surfaces. have.

On the other hand, the upper housing left surface portion 130 forms a left surface of the upper housing portion 100 , and includes a first upper housing left flat portion 131 , a second upper housing left flat portion 132 , and a third upper housing left flat portion. a portion 133 , a fourth upper housing left flat portion 134 , a first upper housing left curved portion 135 , a second upper housing left curved portion 136 , and a third upper housing left curved portion 137 . can do.

More preferably, the first upper housing left planar part 131 may have a symmetrical shape with the first upper housing right flat part 121 with respect to the lateral centerline of the upper housing part 100 , and the second upper housing left planar part 131 may have a symmetrical shape. The portion 132 may be symmetrical to the second upper housing right flat portion 122 with respect to the lateral centerline of the upper housing portion 100 , and the third upper housing left flat portion 133 may be symmetrical to the upper housing portion 100 . ) may have a symmetrical shape with the third upper housing right flat part 123 based on the lateral centerline of the ), and the fourth upper housing left plane part 134 may be a fourth upper housing part with respect to the lateral centerline of the upper housing part 100 . It may be symmetrical to the upper housing right flat portion 124 , and the first upper housing left curved portion 135 is symmetrical to the first upper housing right curved portion 125 with respect to the lateral center line of the upper housing portion 100 . The second upper housing left curved portion 136 may be symmetrical to the second upper housing right curved portion 126 with respect to the lateral centerline of the upper housing portion 100 , and the third upper housing left curved surface The portion 137 may have a symmetrical shape with the third upper housing right curved portion 127 with respect to the lateral center line of the upper housing portion 100 .

Meanwhile, the lower housing part 200 is connected to the lower part of the upper housing part 100 .

In more detail, the lower housing part 200 may include a lower housing front part 210 , a lower housing right side part 220 , a discharge guide part 230 , and a support protrusion part 240 .

The lower housing front part 210 is formed as a flat surface facing forward under the upper housing front part 110 .

The lower housing right side portion 220 forms a right side surface of the lower housing portion 200 , and includes a first lower housing right flat portion 221 , a second lower housing right flat portion 222 , and a third lower housing right flat portion 223 . ), a fourth lower housing right flat portion 224 , a first lower housing right curved portion 225 , a second lower housing right curved portion 226 , and a third lower housing right curved portion 227 . .

More specifically, the first lower housing right curved portion 225 is vertically long and narrowly formed between the first lower housing right flat portion 221 and the second lower housing right flat portion 222 .

The second lower housing right curved portion 226 is vertically long and narrowly formed between the second lower housing right flat portion 222 and the third lower housing right flat portion 223 .

The third lower housing right curved portion 227 is vertically long and narrowly formed between the third lower housing right flat portion 223 and the fourth lower housing right flat portion 224 .

Each of the first lower housing right curved portion 225 , the second lower housing right curved portion 226 , and the third lower housing right curved portion 227 may have a semicircular cross-section.

The first lower housing right curved portion 225 may be formed coaxially with the first upper housing right curved portion 125 , and the second lower housing right curved portion 226 may include the second upper housing right curved portion 126 . ) and the third lower housing right curved portion 227 may be formed coaxially with the third upper housing right curved portion 127 .

The first lower housing right flat portion 221 , the second lower housing right flat portion 222 , the third lower housing right flat portion 223 , and the fourth lower housing right flat portion 224 may be formed as flat surfaces. have.

The discharge guide part 230 forms the lowermost end of the lower housing front part 210 , and may include a first discharge guide part 231 , a second discharge guide part 232 , and a third discharge guide part 233 . .

In other words, in the first discharge guide part 231 , the first lower housing right curved part 225 extends downward, and the second discharge guide part 232 has the second lower housing right curved part 226 . The third discharge guide portion 233 extends downward, and the third lower housing right curved portion 227 extends downward.

The first discharge guide part 231 guides the moisture introduced through the first upper housing right curved part 125 to pass through the first lower housing right curved part 225 and finally discharged to the outside.

The second discharge guide part 232 guides the moisture introduced through the second upper housing right curved part 126 to pass through the second lower housing right curved part 226 and finally discharged to the outside.

The third discharge guide part 233 guides the moisture introduced through the third upper housing right curved part 127 to pass through the third lower housing right curved part 227 and finally discharged to the outside.

Meanwhile, the support protrusion 240 may be provided on the lower surface 201 of the lower housing to support the cylindrical battery cell housing on the ground.

The support protrusion 240 may include a first support protrusion 241 and a second support protrusion 242 spaced apart from each other by a predetermined distance in the longitudinal direction.

The upper cap part 300 may be provided with a plate part 310 , a contact part 320 , a fastening part 330 and ch, and a semi-circular through-hole.

The plate part 310 may have a flat surface, and a plurality of circular through-holes and a plurality of semi-circular through-holes may be formed in the plate part 310 .

A circular through-hole refers to a circular hole (hereinafter; referred to as “ch” series) formed as an opening without incision on the edge, and a semi-circular through-hole is a half hole formed with an opening with a cutout on the edge. denoted by the "hh" series).

The upper cap part 300 will be described in more detail with reference to FIG. 3 .

3 is a top view according to a preferred embodiment of the present invention.

Since a plurality of circular through-holes in the plate part 310 are provided in the upper cap part 300 to vertically penetrate the plate part 310 , heat generated from the cylindrical battery cell 400 is effectively radiated to the outside, thereby improving battery performance. Let this be maximized.

Here, the circular protrusion refers to a circular upper protrusion (hereinafter referred to as a “cu” series) that forms the top of the upper housing part 100 and is formed as an opening without an incision on the edge.

When the upper cap part 300 is coupled to the upper end of the upper housing part 100 , the outer peripheral surface of the side of the circular protrusion is inserted into the circular through hole, and the upper end of the circular protrusion protrudes higher than the plate part 310 to have a height difference. do.

Therefore, even when moisture comes into contact with the plate part 310 , since the upper end of the circular protrusion protrudes higher than the plate part 310 , the strength of direct moisture inflow into the circular through-hole can be suppressed as much as possible.

Nevertheless, moisture introduced into the circular through-hole may be discharged to the outside while the contact area with the cylindrical battery cell 400 is minimized.

The semi-circular protrusion also refers to a semi-circular protrusion (hereinafter referred to as a “hu” series) formed as an opening having an incision at the edge while forming the upper end of the upper housing part 100 .

When the upper cap part 300 is coupled to the upper end of the upper housing part 100, the outer peripheral surface of the side of the semi-circular protrusion is inserted into the semi-circular through-hole, and the upper end of the semi-circular protrusion protrudes higher than the plate part 310 to have a height difference. do.

Therefore, even when moisture comes into contact with the plate part 310 , since the upper end of the semi-circular protrusion protrudes higher than the plate part 310 , the strength of direct moisture inflow into the semi-circular through-hole can be suppressed as much as possible.

Nevertheless, moisture introduced into the semi-circular through-hole may be discharged to the outside while the contact area with the cylindrical battery cell 400 is minimized.

The circular through-hole is provided at a position that is spaced apart from the edge of the upper cap part 300 by a predetermined distance and has a different distance from the first electrode part 501 .

Meanwhile, the semi-circular through-hole is provided at the edge of the upper cap part 300 .

The semi-circular through-holes include a first semi-circular through-hole (hh1), a second semi-circular through-hole (hh2), a third semi-circular through-hole (hh3), a fourth semi-circular through-hole (hh4), a fifth semi-circular through-hole (hh5), and a second semi-circular through-hole (hh5). It may include a sixth semi-circular through-hole hh6 , a seventh semi-circular through-hole hh7 , an eighth semi-circular through-hole hh8 , a ninth semi-circular through-hole hh9 , and a tenth semi-circular through-hole hh10 .

In more detail, Hh is a first semi-circular through-hole (hh1), a second semi-circular through-hole (hh2), and a third semi-circular through-hole (hh3) on one side, respectively, from the lateral side of the upper cap part 300, and the other side A fourth semi-circular through-hole (hh4), a fifth semi-circular through-hole (hh5), and a sixth semi-circular through-hole (hh6) are provided in the ninth semi-circular through-hole (hh9) and a tenth through-hole (hh9) at the front of the upper cap part 300 . A semi-circular through-hole hh10 is provided, and a seventh semi-circular through-hole hh7 and an eighth semi-circular through-hole hh8 are provided at the rear of the upper cap part 300 .

The seventh semi-circular through-hole (hh7) and the eighth semi-circular through-hole (hh8) are located at each point obtained by dividing the shortest longitudinal distance of the upper cap part 300 into three equal parts, the ninth semi-circular through-hole (hh9) and the tenth semi-circular through hole (hh9) The through-hole hh10 is also located at each point obtained by dividing the shortest longitudinal distance of the upper cap part 300 into three equal parts.

The circular through-holes formed in the upper cap part 300 are a first circular through-hole (ch1), a second circular through-hole (ch2), a third circular through-hole (ch3), a fourth circular through-hole (ch4), and a fifth circular through-hole (ch4). Through-hole (ch5), sixth circular through-hole (ch6), seventh circular through-hole (ch7), eighth circular through-hole (ch8), ninth circular through-hole (ch9), tenth circular through-hole (ch10) , an eleventh circular through-hole ch11 , a twelfth circular through-hole ch12 , a thirteenth circular through-hole ch13 , and a fourteenth circular through-hole ch14 .

The center of the first cylindrical battery cell 410 may be located at a point indicated by an arrow.

The fifth circular through-hole ch5 and the fourth circular through-hole ch4 are positioned on the same line in the longitudinal direction.

The eighth semi-circular through-hole (hh8), the thirteenth circular through-hole (ch13), the second circular through-hole (ch2) at the same distance from each center point of the first circular through-hole (ch1) and the second semi-circular through-hole (hh2) The diameter of the first imaginary circle centered on the point may be smaller than a distance of 1/2 of the longitudinal length of the upper cap part 300 .

The eighth semi-circular through-hole (hh8), the thirteenth circular through-hole (ch13), the second circular through-hole (ch2) at the same distance from each center point of the first circular through-hole (ch1) and the second semi-circular through-hole (hh2) The center of the first cylindrical battery cell 410 is located directly at the point.

That is, the outermost outer peripheral surface of the cross-section of the first cylindrical battery cell 410 may be a circular rim of the battery cell, and the diameter of the circular rim of the battery cell is the eighth semi-circular through hole hh8 and the thirteenth circular through hole ( ch13) and the second circular through-hole ch2 It may be preferable to have a diameter smaller than the diameter of the first virtual circle connecting the respective center points of the first circular through-hole ch1 and the second semi-circular through-hole hh2.

In other words, the outer peripheral surface of the first cylindrical battery cell 410 has an eighth semi-circular through-hole (hh8), a thirteenth circular through-hole (ch13), a second circular through-hole (ch2), a first circular through-hole (ch1), The second semi-circular through-hole hh2 may be penetrated with the same radius.

That is, the cylindrical battery cell 400 may be described as being in surface contact with ch.

Although not directly shown in FIG. 3, the first cylindrical battery cell 410 includes an eighth semi-circular through-hole (hh8), a thirteenth circular through-hole (ch13), a second circular through-hole (ch2), and a first circular through-hole ( ch1) and a portion thereof may be seen through the second semi-circular through-hole hh2.

In other words, the first cylindrical battery cell 410 includes an eighth semi-circular through-hole (hh8), a thirteenth circular through-hole (ch13), a second circular through-hole (ch2), a first circular through-hole (ch1), and a second 2 It blocks some space of the semi-circular through-hole hh2, and the film has an effect that moisture inflow from the outside can be suppressed as much as the space.

In addition, an eighth semi-circular protrusion hu8 is inserted into the eighth semi-circular through-hole hh8, a thirteenth circular protrusion cu13 is inserted into the thirteenth circular through-hole ch13, and a second circular through-hole ( A second circular protrusion cu2 is inserted into ch2, a first circular protrusion cu1 is inserted into the first circular through-hole ch1, and a second semi-circular protrusion ( Because hu2) is inserted, due to the same height difference as described above, moisture is directly transferred to the eighth semi-circular through-hole (hh8), the thirteenth circular through-hole (ch13), the second circular through-hole (ch2), and the first circular through-hole (ch1), the inflow into the second semi-circular through-hole (hh2) can be primarily suppressed.

The first circular through-hole ch1 and the second circular through-hole ch2 are located on the same line in the longitudinal direction, and the fourth circular through-hole ch4 and the fifth circular through-hole ch5 are also on the same line in the longitudinal direction. is located, and the third circular through hole ch3 is spaced a predetermined distance away from the second circular through hole ch2 and the fourth circular through hole ch4 toward the first semi-circular protrusion hu1 at a point 1/2 of the distance do.

A center of the third circular through-hole ch3 may be located on the same axis as a center of the first semi-circular through-hole hh1.

The center of the first semi-circular through-hole hh1 may be externally positioned at 1/2 the lateral length of the upper cap part 300 .

The center of the third circular through-hole ch3 is located to be biased toward the first semi-circular through-hole hh1 rather than a 1/2 point of the longitudinal length of the upper cap part 300 .

Accordingly, the first circular through hole ch1, the second circular through hole ch2, the third circular through hole ch3, the fourth circular through hole ch4, the fifth circular through hole ch5, and the first semicircular through hole A diameter of the first virtual circle centered at a point at the same distance from each center point of the hole hh1 may be smaller than a distance of 1/2 the length of the upper cap part 300 in the longitudinal direction.

First circular through-hole (ch1), second circular through-hole (ch2), third circular through-hole (ch3), fourth circular through-hole (ch4), fifth circular through-hole (ch5), and first semi-circular through-hole ( The center of the second cylindrical battery cell 420 is located at a point at the same distance from each center point of hh1).

That is, the outermost outer peripheral surface of the cross-section of the second cylindrical battery cell 420 may be an annular ring shape (hereinafter, “circular rim of the battery cell”). The diameter of the circular rim of the battery cell is the diameter of the first circular through hole (ch1), the second circular through hole (ch2), the third circular through hole (ch3), the fourth circular through hole (ch4), the fifth circular through hole (ch5), and each center point of the first semi-circular through hole (hh1) It may be preferable to be smaller than the diameter of the first virtual circle connecting the .

In other words, the outer peripheral surface of the second cylindrical battery cell 420 has a first circular through hole (ch1), a second circular through hole (ch2), a third circular through hole (ch3), a fourth circular through hole (ch4), The fifth circular through-hole ch5 and the first semi-circular through-hole hh1 may be invaded with the same radius, which can be understood with reference to FIG. 4 .

That is, the cylindrical battery cell 400 may be described as being in surface contact with ch.

Although not directly shown in FIG. 3, the second cylindrical battery cell 420 has a first circular through hole ch1, a second circular through hole ch2, a third circular through hole ch3, and a fourth circular through hole ( A part thereof may be seen through ch4), the fifth circular through hole ch5, and the first semi-circular through hole hh1.

In other words, the second cylindrical battery cell 420 includes a first circular through hole ch1, a second circular through hole ch2, a third circular through hole ch3, a fourth circular through hole ch4, and a fourth circular through hole ch4. Part of the space of the 5 circular through-hole ch5 and the first semi-circular through-hole hh1 is blocked, and the film has an effect that moisture inflow from the outside can be suppressed as much as the space.

In addition, a first circular protrusion cu1 is inserted into the first circular through-hole ch1, a second circular protrusion cu2 is inserted into the second circular through-hole ch2, and a third circular through-hole ( A third circular protrusion cu3 is inserted into ch3, a fourth circular protrusion cu4 is inserted into the fourth circular through hole ch4, and a fifth circular protrusion cu4 is inserted into the fifth circular through hole ch5 ( cu5) is inserted, and the first semi-circular protrusion hu1 is inserted into the first semi-circular through-hole hh1. Inflow into the 2 circular through-hole (ch2), the third circular through-hole (ch3), the fourth circular through-hole (ch4), the fifth circular through-hole (ch5), and the first semi-circular through-hole (hh1) is primarily suppressed it can be

Meanwhile, similarly, the third cylindrical battery cell 430 may have its center positioned at a point indicated by an arrow.

The fifth semi-circular through-hole hh5 and the fourth circular through-hole ch4 are positioned on the same line in the longitudinal direction.

At the same distance from each center point of the tenth semi-circular through-hole (hh10), the eleventh circular through-hole (ch11), the fourth circular through-hole (ch4), the fifth circular through-hole (ch5), and the third semi-circular through-hole (hh3) The diameter of the first imaginary circle centered on the point may be smaller than a distance of 1/2 of the longitudinal length of the upper cap part 300 .

At the same distance from each center point of the tenth semi-circular through-hole (hh10), the eleventh circular through-hole (ch11), the fourth circular through-hole (ch4), the fifth circular through-hole (ch5), and the third semi-circular through-hole (hh3) The center of the third cylindrical battery cell 430 is located directly at the point.

That is, the outermost outer peripheral surface of the cross-section of the third cylindrical battery cell 430 may be a circular rim of the battery cell, and the diameter of the circular rim of the battery cell is the tenth semi-circular through hole (hh10), the eleventh circular through hole ( ch11), the fourth circular through-hole (ch4), the fifth circular through-hole (ch5), and the third semi-circular through-hole (hh3) may be preferably smaller than the diameter of the first virtual circle connecting the center points.

In other words, the outer peripheral surface of the third cylindrical battery cell 430 has a tenth semi-circular through-hole (hh10), an eleventh circular through-hole (ch11), a fourth circular through-hole (ch4), a fifth circular through-hole (ch5), The third semi-circular through-hole hh3 may be invaded with the same radius.

That is, the cylindrical battery cell 400 may be described as being in surface contact with ch.

Although not directly shown in FIG. 3 , the third cylindrical battery cell 430 has a tenth semi-circular through hole (hh10), an 11th circular through hole (ch11), a fourth circular through hole (ch4), and a fifth circular through hole ( ch5), a part thereof may be seen through the third semicircular through-hole hh3.

In other words, the third cylindrical battery cell 430 includes a tenth semi-circular through-hole (hh10), an eleventh circular through-hole (ch11), a fourth circular through-hole (ch4), a fifth circular through-hole (ch5), and a second 3 It blocks a part of the semicircular through-hole hh3, and the film has an effect that moisture inflow from the outside can be suppressed as much as the space.

In addition, a tenth semi-circular protrusion hu10 is inserted into the tenth semi-circular through-hole hh10, an eleventh circular protrusion cu11 is inserted into the eleventh circular through-hole ch11, and a fourth circular through-hole ( Because the third circular protrusion cu3 is inserted into ch4, and the fifth circular protrusion cu5 is inserted into the fifth circular through hole ch5, due to the same height difference as described above, moisture is directly absorbed into the tenth Inflow into the semi-circular through-hole (hh10), the eleventh circular through-hole (ch11), the fourth circular through-hole (ch4), the fifth circular through-hole (ch5), and the third semi-circular through-hole (hh3) is to be primarily suppressed. it can be

Meanwhile, similarly, the fourth cylindrical battery cell 440 may have its center positioned at a point indicated by an arrow.

The fourteenth circular through-hole ch14 and the thirteenth circular through-hole ch13 are located on the same line in the longitudinal direction, and the third circular through-hole ch3 and the eighth circular through-hole ch8 are also on the same line in the longitudinal direction. is located in

The second circular through-hole ch2 and the ninth circular through-hole ch9 are disposed on the same line as an imaginary line connecting the first circular through-hole ch1 and the tenth circular through-hole ch10 to each other, respectively.

14th circular through-hole (ch14), 13th circular through-hole (ch13), 2nd circular through-hole (ch2), 3rd circular through-hole (ch3), 8th circular through-hole (ch8), and ninth circular through-hole ( The diameter of the first virtual circle centered at a point at the same distance from each center point of ch9) may be smaller than a distance of 1/2 the length of the upper cap part 300 in the longitudinal direction.

14th circular through-hole (ch14), 13th circular through-hole (ch13), 2nd circular through-hole (ch2), 3rd circular through-hole (ch3), 8th circular through-hole (ch8), and ninth circular through-hole ( The center of the fourth cylindrical battery cell 440 is located at a point at the same distance from each center point of ch9).

That is, the outermost outer peripheral surface of the cross section of the fourth cylindrical battery cell 440 may be a circular rim of the battery cell, and the diameter of the circular rim of the battery cell is a 14th circular through hole (ch14), a 13th circular through hole ( ch13), the second circular through-hole (ch2), the third circular through-hole (ch3), the eighth circular through-hole (ch8), and the ninth circular through-hole (ch9) with the diameter of the first virtual circle connecting the center points Smaller ones may be desirable.

In other words, the outer peripheral surface of the fourth cylindrical battery cell 440 has a 14th circular through hole (ch14), a thirteenth circular through hole (ch13), a second circular through hole (ch2), a third circular through hole (ch3), The eighth circular through-hole ch8 and the ninth circular through-hole ch9 may be invaded with the same radius.

That is, the cylindrical battery cell 400 may be described as being in surface contact with ch.

Although not directly shown in FIG. 3 , the fourth cylindrical battery cell 440 has a 14th circular through hole (ch14), a 13th circular through hole (ch13), a second circular through hole (ch2), and a third circular through hole ( ch3), a portion thereof may be seen through the eighth circular through hole ch8 and the ninth circular through hole ch9.

In other words, the fourth cylindrical battery cell 440 includes a fourteenth circular through hole ch14, a thirteenth circular through hole ch13, a second circular through hole ch2, a third circular through hole ch3, and a third circular through hole ch3. Some spaces of the eighth circular through-hole ch8 and the ninth circular through-hole ch9 are blocked, and the film has an effect that moisture inflow from the outside can be suppressed as much as the space.

In addition, a fourteenth circular protrusion cu14 is inserted into the fourteenth circular through-hole ch14, a fourteenth circular protrusion cu14 is inserted into the thirteenth circular through-hole ch13, and a second circular through-hole ( A second circular projection cu2 is inserted into ch2, a third circular projection cu3 is inserted into the third circular through hole ch3, and a tenth circular projection ( cu10) is inserted, and the sixth circular protrusion cu6 is inserted into the ninth circular through hole ch9, so due to the height difference as described above, moisture is directly transferred to the 14th circular through hole ch14, the second 13 The circular through-hole (ch13), the second circular through-hole (ch2), the third circular through-hole (ch3), the eighth circular through-hole (ch8), and the ninth circular through-hole (ch9) are primarily inhibited from flowing in it can be

On the other hand, similarly, the fifth cylindrical battery cell 450 may have its center positioned at the point indicated by the arrow.

The twelfth circular through hole ch12 and the eleventh circular through hole ch11 are located on the same line in the longitudinal direction, and the third circular through hole ch3 and the eighth circular through hole ch8 are also on the same line in the longitudinal direction. is located in

The fourth circular through-hole ch4 and the seventh circular through-hole ch7 are arranged on the same line as an imaginary line connecting the fifth and sixth circular through-holes ch5 and ch6 to each other, respectively.

12th circular through hole (ch12), 11th circular through hole (ch11), 4th circular through hole (ch4), 3rd circular through hole (ch3), 8th circular through hole (ch8), and 7th circular through hole ( The diameter of the first imaginary circle centered at a point at the same distance from each central point of ch7) may be smaller than a distance of 1/2 the length of the upper cap part 300 in the longitudinal direction.

12th circular through hole (ch12), 11th circular through hole (ch11), 4th circular through hole (ch4), 3rd circular through hole (ch3), 8th circular through hole (ch8), and 7th circular through hole ( The center of the fifth cylindrical battery cell 450 is located at a point at the same distance from each center point of ch7).

That is, the outermost outer peripheral surface of the cross-section of the fifth cylindrical battery cell 450 may be a circular rim of the battery cell, and the diameter of the circular rim of the battery cell is the twelfth circular through hole ch12 and the eleventh circular through hole ( ch11), the fourth circular through hole (ch4), the third circular through hole (ch3), the eighth circular through hole (ch8), and the diameter of the first virtual circle connecting the respective center points of the seventh circular through hole (ch7) Smaller ones may be desirable.

In other words, the outer peripheral surface of the fifth cylindrical battery cell 450 has a twelfth circular through hole (ch12), an eleventh circular through hole (ch11), a fourth circular through hole (ch4), a third circular through hole (ch3), The eighth circular through-hole ch8 and the seventh circular through-hole ch7 may be invaded with the same radius.

That is, the cylindrical battery cell 400 may be described as being in surface contact with ch.

Although not directly shown in FIG. 3 , the fifth cylindrical battery cell 450 has a twelfth circular through hole ch12, an eleventh circular through hole ch11, a fourth circular through hole ch4, and a third circular through hole ( ch3), a portion thereof may be seen through the eighth circular through-hole ch8 and the seventh circular through-hole ch7.

In other words, the fifth cylindrical battery cell 450 includes a twelfth circular through hole ch12, an eleventh circular through hole ch11, a fourth circular through hole ch4, a third circular through hole ch3, and a third circular through hole ch3. Some spaces of the eighth circular through-hole ch8 and the seventh circular through-hole ch7 are blocked, and the film has an effect that moisture inflow from the outside can be suppressed as much as the space.

In addition, a twelfth circular protrusion cu12 is inserted into the twelfth circular through-hole ch12, an eleventh circular protrusion cu11 is inserted into the eleventh circular through-hole ch11, and a fourth circular through-hole ( A third circular protrusion cu3 is inserted into ch4, a third circular protrusion cu3 is inserted into the third circular through-hole ch3, and a tenth circular protrusion ( cu10) is inserted, and the ninth circular protrusion cu9 is inserted into the seventh circular through hole ch7, so due to the height difference as described above, moisture is directly transferred to the twelfth circular through hole ch12, the second 11 Primary suppression of inflow into the circular through-hole (ch11), the fourth circular through-hole (ch4), the third circular through-hole (ch3), the eighth circular through-hole (ch8), and the seventh circular through-hole (ch7) it could be

An imaginary line connecting the center of the fifth cylindrical battery cell 450 and the center of the fourth cylindrical battery cell 440 is an imaginary line in the transverse direction that perpendicularly intersects the midpoint of the longitudinal length of the upper cap part 300 . It may be located on the same line as the line.

Meanwhile, similarly, the center of the sixth cylindrical battery cell 460 may be located at a point indicated by an arrow.

The ninth circular through-hole ch9 and the tenth circular through-hole ch10 are positioned on the same line in the longitudinal direction.

At the same distance from each center point of the seventh semi-circular through-hole (hh7), the 14th circular through-hole (ch14), the ninth circular through-hole (ch9), the tenth circular through-hole (ch10), and the fifth semi-circular through-hole (hh5) The diameter of the first imaginary circle centered on the point may be smaller than a distance of 1/2 of the longitudinal length of the upper cap part 300 .

At the same distance from each center point of the seventh semi-circular through-hole (hh7), the 14th circular through-hole (ch14), the ninth circular through-hole (ch9), the tenth circular through-hole (ch10), and the fifth semi-circular through-hole (hh5) The center of the sixth cylindrical battery cell 460 is located right at the point.

That is, the outermost outer peripheral surface of the cross section of the sixth cylindrical battery cell 460 may be a circular rim of the battery cell, and the diameter of the circular rim of the battery cell is the seventh semi-circular through hole hh7 and the 14th circular through hole ( ch14) and the ninth circular through-hole ch9 may be smaller than the diameter of the first virtual circle connecting the central points of the tenth circular through-hole ch10 and the fifth semi-circular through-hole hh5.

In other words, the outer peripheral surface of the sixth cylindrical battery cell 460 has a seventh semi-circular through-hole (hh7), a 14th circular through-hole (ch14), a ninth circular through-hole (ch9), a tenth circular through-hole (ch10), The fifth semi-circular through-hole hh5 may be invaded with the same radius.

That is, the cylindrical battery cell 400 may be described as being in surface contact with ch.

Although not directly shown in FIG. 3 , the sixth cylindrical battery cell 460 has a seventh semi-circular through-hole (hh7), a 14th circular through-hole (ch14), a ninth circular through-hole (ch9), and a tenth circular through-hole ( ch10) and a portion thereof may be seen through the fifth semi-circular through-hole hh5.

In other words, the sixth cylindrical battery cell 460 has an eighth semi-circular through-hole hh8, a thirteenth circular through-hole ch13, a second circular through-hole ch2, a first circular through-hole ch1, and a 2 It blocks some space of the semi-circular through-hole hh2, and the film has an effect that moisture inflow from the outside can be suppressed as much as the space.

In addition, a seventh semi-circular protrusion hu7 is inserted into the seventh semi-circular through-hole hh7, a fourteenth circular protrusion cu14 is inserted into the fourteenth circular through-hole ch14, and a ninth circular through-hole ( A sixth circular protrusion cu6 is inserted into ch9, a seventh circular protrusion cu7 is inserted into the tenth circular through-hole ch10, and a fifth semi-circular protrusion ( Because hu5) is inserted, due to the same height difference as described above, moisture directly enters the seventh semi-circular through-hole (hh7), the 14th circular through-hole (ch14), the ninth circular through-hole (ch9), and the tenth circular through-hole (ch10), the inflow into the fifth semi-circular through-hole (hh5) can be primarily suppressed.

On the other hand, similarly, the seventh cylindrical battery cell 470 may be centered at the point indicated by the arrow.

In other words, the center of the seventh cylindrical battery cell 470 and the center of the second cylindrical battery cell 420 are at 1/2 the longitudinal length of the upper cap part 300 .

The tenth circular through-hole ch10 and the ninth circular through-hole ch9 are located on the same line in the longitudinal direction, and the seventh circular through-hole ch7 and the sixth circular through-hole ch6 are also on the same line in the longitudinal direction. is located, and the eighth circular through-hole ch8 is spaced a predetermined distance away from the fourth semi-circular protrusion hu4 at a point 1/2 of the distance between the ninth circular through-hole ch9 and the seventh circular through-hole ch7 do.

The center of the eighth circular through-hole ch8 may be located on the same axis as the center of the fourth semi-circular through-hole hh4.

The center of the fourth semi-circular through-hole hh4 may be externally located at a point 1/2 of the lateral length of the upper cap part 300 .

The center of the eighth circular through-hole ch8 is located to be biased toward the fourth semi-circular through-hole hh4 rather than a 1/2 point of the longitudinal length of the upper cap part 300 .

Accordingly, the tenth circular through hole (ch10), the ninth circular through hole (ch9), the eighth circular through hole (ch8), the seventh circular through hole (ch7), the sixth circular through hole (ch6), and the fourth semicircular through hole (ch6) A diameter of the first imaginary circle centered at a point at the same distance from each center point of the hole hh4 may be less than a distance of 1/2 of the longitudinal length of the upper cap part 300 .

A tenth circular through hole (ch10), a ninth circular through hole (ch9), an eighth circular through hole (ch8), a seventh circular through hole (ch7), a sixth circular through hole (ch6), and a fourth semi-circular through hole ( The center of the seventh cylindrical battery cell 470 is located at a point at the same distance from each center point of hh4).

That is, the outermost outer peripheral surface of the cross-section of the seventh cylindrical battery cell 470 may be a circular rim of the battery cell, and the diameter of the circular rim of the battery cell is the tenth circular through hole ch10 and the ninth circular through hole ( ch9), the eighth circular through-hole (ch8), the seventh circular through-hole (ch7), the sixth circular through-hole (ch6), and the fourth semi-circular through-hole (hh4) with the diameter of the first virtual circle connecting the center points Smaller ones may be desirable.

In other words, the outer peripheral surface of the seventh cylindrical battery cell 470 has a tenth circular through hole (ch10), a ninth circular through hole (ch9), an eighth circular through hole (ch8), a seventh circular through hole (ch7), The sixth circular through-hole ch6 and the fourth semi-circular through-hole hh4 may be invaded with the same radius.

That is, the cylindrical battery cell 400 may be described as being in surface contact with ch.

Although not directly shown in FIG. 3 , the seventh cylindrical battery cell 470 has a tenth circular through hole ch10, a ninth circular through hole ch9, an eighth circular through hole ch8, and a seventh circular through hole ( ch7), the sixth circular through-hole ch6, and the fourth semi-circular through-hole hh4 may be partially visible.

In other words, the seventh cylindrical battery cell 470 has a tenth circular through hole ch10, a ninth circular through hole ch9, an eighth circular through hole ch8, a seventh circular through hole ch7, and a seventh circular through hole ch7. Some spaces of the 6 circular through-holes ch6 and the fourth semi-circular through-holes hh4 are blocked, and the membrane has an effect that moisture inflow from the outside can be suppressed as much as the space.

In addition, a seventh circular protrusion cu7 is inserted into the tenth circular through hole ch10, a sixth circular protrusion cu6 is inserted into the ninth circular through hole ch9, and an eighth circular through hole ( A tenth circular protrusion cu10 is inserted into ch8, a ninth circular protrusion cu9 is inserted into the seventh circular protrusion ch7, and an eighth circular protrusion cu9 is inserted into the sixth circular through-hole ch6. cu8) is inserted, and the fourth semi-circular protrusion hu4 is inserted into the fourth semi-circular through-hole hh4. Inflow into the 9 circular through-hole (ch9), the 8th circular through-hole (ch8), the 7th circular through-hole (ch7), the 6th circular through-hole (ch6), and the fourth semi-circular through-hole (hh4) is primarily suppressed it could be

On the other hand, similarly, the eighth cylindrical battery cell 480 may be centered at the point indicated by the arrow.

The sixth circular through-hole ch6 and the seventh circular through-hole ch7 are positioned on the same line in the longitudinal direction.

At the same distance from each center point of the 6th semicircular through-hole (hh6), the 6th circular through-hole (ch6), the 7th circular through-hole (ch7), the 12th circular through-hole (ch12), and the ninth semi-circular through-hole (hh9) The diameter of the first imaginary circle centered on the point may be smaller than a distance of 1/2 of the longitudinal length of the upper cap part 300 .

At the same distance from each center point of the 6th semicircular through-hole (hh6), the 6th circular through-hole (ch6), the 7th circular through-hole (ch7), the 12th circular through-hole (ch12), and the ninth semi-circular through-hole (hh9) The center of the eighth cylindrical battery cell 480 is located directly at the point.

That is, the outermost outer peripheral surface of the cross-section of the eighth cylindrical battery cell 480 may be a circular rim of the battery cell, and the diameter of the circular rim of the battery cell is a sixth semi-circular through hole hh6, a sixth circular through hole ( ch6), the seventh circular through-hole ch7, it may be preferable to have a diameter smaller than the diameter of the first virtual circle connecting the respective center points of the twelfth circular through-hole ch12 and the ninth semi-circular through-hole hh9.

In other words, the outer peripheral surface of the eighth cylindrical battery cell 480 has a sixth semi-circular through-hole (hh6), a sixth circular through-hole (ch6), a seventh circular through-hole (ch7), a twelfth circular through-hole (ch12), The ninth semi-circular through-hole hh9 may be invaded with the same radius.

That is, the cylindrical battery cell 400 may be described as being in surface contact with ch.

Although not directly shown in FIG. 3, the eighth cylindrical battery cell 480 has a sixth semi-circular through-hole (hh6), a sixth circular through-hole (ch6), a seventh circular through-hole (ch7), and a twelfth circular through-hole ( ch12) and a portion thereof may be seen through the ninth semi-circular through-hole hh9.

In other words, the eighth cylindrical battery cell 480 has a sixth semi-circular through-hole (hh6), a sixth circular through-hole (ch6), a seventh circular through-hole (ch7), a twelfth circular through-hole (ch12), and a second 9 It blocks some space of the semicircular through-hole hh9, and the film has an effect that moisture inflow from the outside can be suppressed as much as the space.

In addition, a sixth semi-circular protrusion hu6 is inserted into the sixth semi-circular through-hole hh6, an eighth circular protrusion cu8 is inserted into the sixth circular through-hole ch6, and a seventh circular through-hole ( A ninth circular protrusion cu9 is inserted into ch7, a twelfth circular protrusion cu12 is inserted into the twelfth circular through-hole ch12, and a ninth semi-circular protrusion ( Because hu9) is inserted, due to the same height difference as described above, moisture is directly transferred to the 6th semi-circular through-hole (hh6), the 6th circular through-hole (ch6), the 7th circular through-hole (ch7), and the 12th circular through-hole (ch12), the inflow into the ninth semi-circular through-hole (hh9) can be primarily suppressed.

Meanwhile, the first cylindrical battery cell 410 , the second cylindrical battery cell 420 , and the fourth cylindrical battery cell 440 may have an equilateral triangle connecting the center points of each.

Meanwhile, the second cylindrical battery cell 420 , the third cylindrical battery cell 430 , and the fifth cylindrical battery cell 450 may have an equilateral triangle connecting the center points of each.

Meanwhile, the fifth cylindrical battery cell 450 , the seventh cylindrical battery cell 470 , and the eighth cylindrical battery cell 480 may have an equilateral triangle connecting the center points of each.

Meanwhile, connecting the center points of the fourth cylindrical battery cell 440 , the sixth cylindrical battery cell 460 , and the seventh cylindrical battery cell 470 may be an equilateral triangle.

In other words, a cylindrical battery may have a 3x2x3 arrangement from a transverse direction to a longitudinal direction.

In other words, a cylindrical battery may have a 2x3x2 arrangement from longitudinal to transverse direction.

Meanwhile, reference numeral 341 is connected to the fourteenth circular protrusion cu14 and the thirteenth circular protrusion cu13 , and reference numeral 342 is connected to the twelfth circular protrusion cu12 and the eleventh circular protrusion cu11 .

The first rear end portion 151 has one end connected to the seventh semi-circular protrusion hu7 and the other end exposed from the sixth fastening portion 335 .

The second rear end portion 152 has one end connected to the eighth semi-circular protrusion hu8 and the other end exposed from the fifth fastening portion 334 .

The second fastening part 331 is bent to grip the upper housing part 100 between the third semi-circular protrusion hu3 and the first semi-circular protrusion hu1 .

The third fastening part 332 is bent to grip the upper housing part 100 between the second semi-circular protrusion hu2 and the first semi-circular protrusion hu1 .

The fourth fastening part 333 is adjacent to the second semi-circular protrusion hu2 and is bent so as to grip the upper housing part 100 at a position maximally separated from the first terminal closing part 161 .

The fifth fastening part 334 is bent to grip the upper housing part 100 at a point opposite to the first terminal closing part 161 , and the sixth fastening part 335 is the second terminal closing part 162 . It is bent to grip the upper housing part 100 at a point opposite to the .

Similarly, the ninth fastening part 338 is bent to grip the upper housing part 100 between the sixth semi-circular protrusion hu6 and the fourth semi-circular protrusion hu4.

The eighth fastening part 337 is bent to grip the upper housing part 100 between the fifth semi-circular protrusion hu5 and the fourth semi-circular protrusion hu4.

The seventh fastening part 336 is adjacent to the fifth semi-circular protrusion hu5 and is bent so as to grip the upper housing part 100 at a position that is maximally separated from the second terminal closing part 162 .

The first terminal closing part 161 is provided to surround the side surface of the first electrode part 501 , and the second terminal closing part 162 is provided to surround the side surface of the second electrode part 502 .

4 is a side view according to a preferred embodiment of the present invention.

The second cylindrical battery cell 420 is exposed to the right curved portion 126 of the second upper housing, as described above, only a portion of the surface of the second cylindrical battery cell 420 is exposed.

In other words, only the first surface portion 421 , the second surface portion 422 , and the third surface portion 423 of the second cylindrical battery cell 420 can be exposed to moisture.

The first surface portion 421 is a portion of the upper end of the second cylindrical battery cell 420 , and the third surface portion 423 is a side portion exposed from the second upper housing right curved portion 126 .

The second surface portion 422 indicates that the second upper housing right curved portion 126 is in surface contact with the longitudinal direction of the side portion of the second cylindrical battery cell 420 .

Therefore, compared to the prior art, the surface area exposed to moisture is minimized and the net function of air cooling is preserved.

Moisture may be discharged to the outside through the second discharge guide part 232 while in contact with the surface of the second cylindrical battery cell 420 with a minimum area.

Similarly, the first cylindrical battery cell 410 is partially discharged while being in surface contact with the right curved portion 125 of the first upper housing, and the third cylindrical battery cell 430 is discharged from the third upper housing right curved portion 127 . It is partially discharged as it comes into contact.

However, at this time, the first cylindrical battery cell 410 may be formed so that the center of its exposure is biased toward the first upper housing right flat portion 121 rather than the second upper housing right flat portion 122 by a predetermined distance, The three-cylindrical battery cell 430 may be formed so that the exposed center thereof is biased toward the fourth upper housing right flat portion 124 rather than the third upper housing right flat portion 123 by a predetermined distance.

As such, referring back to FIG. 3 described above, if the cross-sectional shapes of the second circular through-hole ch2 are the first cylindrical battery cell 410, the second cylindrical battery cell 420, and the fourth cylindrical shape Each edge of each battery cell 440 may meet at a point dividing the outer peripheral surface of the second circular protrusion cu2 into thirds.

100: upper housing part
110: upper housing front part
120: upper housing right side part
121: first upper housing right flat part
122: second upper housing right flat part
123: third upper housing right flat part
124: fourth upper housing right flat part
125: first upper housing right curved portion
126: second upper housing right curved portion
127: third upper housing right curved part
130: upper housing left side
131: first upper housing left flat part
132: second upper housing left flat part
133: third upper housing left flat part
134: fourth upper housing left flat part
135: left curved portion of the first upper housing
136: second upper housing left curved portion
137: upper housing third left curved portion
140: upper housing rear part
151: first rear finishing part
152: second rear finish
161: first terminal closing part
162: second terminal closing part
200: lower housing part
201: lower surface of the lower housing
210: lower housing front part
220: lower housing right side
221: first lower housing right flat part
222: second lower housing right flat part
223: third lower housing right flat part
224: fourth lower housing right flat part
225: first lower housing right curved portion
226: second lower housing right curved portion
227: third lower housing right curved portion
230: discharge guide part
231: first discharge guide part
232: second discharge guide part
233: third discharge guide part
240: support protrusion
241: first support protrusion
242: second support protrusion
300: upper cap part
310: plate part
320: adhesion part
330: fastening part
331: second fastening part
332: third fastening part
333: fourth fastening part
334: fifth fastening part
335: sixth fastening part
336: seventh fastening part
337: eighth fastening part
338: ninth fastening part
400: cylindrical battery cell
410: first cylindrical battery cell
420: second cylindrical battery cell
421: first surface portion
422: second surface portion
423: third surface portion
430: third cylindrical battery cell
440: fourth cylindrical battery cell
450: fifth cylindrical battery cell
460: 6th cylindrical battery cell
470: seventh cylindrical battery cell
480: eighth cylindrical battery cell
500: electrode part
501: first electrode part
502: second electrode part
ch1: first circular through hole
ch2: second circular through hole
ch3: third circular through hole
ch4: fourth circular through hole
ch5: 5th circular through hole
ch6 : 6th round through hole
ch7: 7th round through hole
ch8: 8th round through hole
ch9: ninth circular through hole
ch10: 10th circular through hole
ch11: 11th circular through hole
ch12: 12th circular through hole
ch13: 13th circular through hole
ch14: 14th circular through hole
cu1: first circular protrusion
cu2: second circular protrusion
cu3: third circular protrusion
cu4: fourth circular protrusion
cu5: fifth circular protrusion
cu6: 6th circular protrusion
cu7: seventh circular protrusion
cu8: eighth circular protrusion
cu9: ninth circular protrusion
cu10: tenth circular protrusion
cu11: 11th circular protrusion
cu12: twelfth circular protrusion
cu13: thirteenth circular protrusion
cu14: 14th circular protrusion
hh1: first semi-circular through-hole
hh2: second semi-circular through hole
hh3 : third semicircular through hole
hh4: fourth semi-circular through hole
hh5: 5th semi-circular through hole
hh6 : 6th semi-circular through hole
hh7 : 7th semi-circular through hole
hh8 : 8th semicircular through hole
hh9: ninth semicircular through hole
hh10: 10th semi-circular through hole
hu1: first semicircular protrusion
hu2: second semicircular protrusion
hu3: third semicircular protrusion
hu4: fourth semicircular protrusion
hu5: fifth semicircular protrusion
hu6: sixth semicircular protrusion
hu7: seventh semicircular protrusion
hu8: eighth semicircular protrusion
hu9: ninth semicircular protrusion
hu10: tenth semicircular protrusion

Claims (10)

In the cylindrical battery cell housing that suppresses the inflow of moisture,
a plurality of cylindrical battery cells 400;
an upper housing part 100 and a lower housing part 200 having a plurality of through-holes continuously formed along the height direction and being vertically coupled to each other to accommodate the cylindrical battery cell 400;
an upper cap part 300 for closing the upper part of the upper housing part 100; including,
The outer diameter of the cylindrical battery cell 400 is smaller than the diameter of a first virtual circle connecting the centers of any three adjacent through holes among the plurality of through holes to the outer circumferential surface, and has a concentricity with the first virtual circle. and a plurality of virtual circles circumscribing the inner circumferential surface of the three through-holes, characterized in that the diameter is larger than the diameter of the second virtual circle having the smallest diameter,
Cylindrical battery cell housing.
According to claim 1,
The end of the through hole has a protrusion that protrudes a predetermined height than the peripheral flat portion; characterized in that it is formed,
Cylindrical battery cell housing.
3. The method of claim 2,
The upper cap part 300 is characterized in that an opening into which the protrusion is inserted is formed,
Cylindrical battery cell housing.
According to claim 1,
The outer peripheral surfaces of the three cylindrical battery cells 400 adjacent to each other among the plurality of cylindrical battery cells 400 meet at a point dividing the outer peripheral surface of the cross section of the through hole into thirds,
Cylindrical battery cell housing.
According to claim 1,
The through-hole is circular or semi-circular, characterized in that it includes at least any one or more,
Cylindrical battery cell housing.
3. The method of claim 2,
The cross-section of the protrusion is circular or semi-circular, characterized in that it includes at least any one or more,
Cylindrical battery cell housing.
4. The method of claim 3,
The opening is circular or semi-circular, characterized in that it comprises at least any one or more,
Cylindrical battery cell housing.
According to claim 1,
Characterized in that the discharge guide part 230 is formed on the lower surface 201 of the lower housing 200,
Cylindrical battery cell housing.
According to claim 1,
Characterized in that a support protrusion 240 is formed on a lower surface of the lower surface portion 201 of the lower housing 200,
Cylindrical battery cell housing.
According to claim 1,
The plurality of cylindrical battery cells 400 are characterized in that the 3x2x3 array,
Cylindrical battery cell housing.

Images