KR101908583B1 - Secondary battery module available for easy gathering and discharging of gas - Google Patents

Abstract

The present invention is characterized in that two battery cells are housed in a case and closed to form a connection mold in which a gas collector is formed at a portion where the electrode bodies of the battery cells are formed, and a connection mold and an electrode body of the battery cells are formed, The secondary battery includes a plurality of battery cells, a plurality of battery cells, and a plurality of battery cells. The plurality of battery cells are connected to each other through a plurality of electrode tabs. Module.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a secondary battery module,

The present invention relates to a secondary battery module in which battery cells are combined to form a module, wherein gas generated in the battery cells by a swelling phenomenon is collected in a space between the battery cells and between the electrode tabs, The present invention relates to a rechargeable battery module,

Generally, unlike a primary battery, a secondary battery can be charged and discharged and is being applied in various fields such as a digital camera, a mobile phone, a notebook, and a hybrid car, and active research is underway. Examples of the secondary battery include a nickel-cadmium battery, a nickel-metal hydride battery, a nickel-hydrogen battery, and a lithium secondary battery. Many researches have been made on lithium secondary batteries having high energy density and discharge voltage among secondary batteries, and they have been commercialized and widely used.

The lithium secondary battery can be manufactured in various forms. Typical examples of the lithium secondary battery include a cylinder type and a prismatic type, which are mainly used in a lithium ion battery. In recent years, a lithium polymer battery, It is made in pouch type and its shape is relatively free.

Such a pouch type lithium polymer battery (hereinafter referred to as "pouch type cell") can be easily bent or bent so that it is formed so as to reinforce the low rigidity of the pouch type cell by joining a rigid case to the outside. A battery module or a battery pack in which a plurality of pouch-shaped cells are stacked.

Since the pouch type cell is not excellent in the mechanical rigidity of the pouch for sealing the electrode body, it is necessary to manufacture the battery module by mounting the pouch type cells in a pack case such as a cartridge for manufacturing a battery module having a stable structure. The electrode tabs of the pouch-shaped cells must be electrically connected in series or in parallel, so that the size of the battery module becomes large and the structure becomes complicated. At this time, the pouch type cell generates a toxic gas inside the pouch due to swelling phenomenon due to overcharging or overdischarge, etc., and when a plurality of pouch type cells are adapted to be formed into a battery module, There is a difficult problem.

A related art related to this is disclosed in US Patent No. 6641949 entitled " Battery vent and Method of assembly ".

US 6641949 B2 (Nov. 4, 2003)

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems as described above, and it is an object of the present invention to provide a secondary battery module in which battery cells are combined to form a module, Which can be easily collected and discharged, by collecting the gas in the space between the battery cells and between the electrode tabs and discharging the discharged gas to a designated external path.

According to an aspect of the present invention, there is provided a rechargeable battery module including: a plurality of battery cells each having electrode taps formed on one side thereof and stacked side by side; A case in which the battery cells are housed therein and the opposite side of the battery cells where the electrode tabs are located is sealed; A connection mold having a plurality of terminals inserted between opposing electrode tabs and pouches of the two battery cells, the plurality of terminals being connected to the electrode tabs, and a gas collecting part penetrating the upper and the lower electrode tabs; And an upper cap coupled to the case and coupled to the case so as to surround the opposite pouch on the side where the electrode tabs of the two battery cells are formed, and a gas discharge part communicating with the gas collecting part; And the gas generated in the battery cells is discharged into opposing battery cells on the side where the electrode tabs of the battery cells are formed and is collected in the gas collection unit and discharged to the outside through the gas discharge unit.

In addition, the pouch on the side where the electrode tab is formed is closely contacted by the connection mold and the case.

In addition, the connection mold is formed with a gas collecting part having a lower side opened, a hollow inside and a gas exhausting tube formed on the upper side, and the upper cap has an insertion hole through which the gas exhausting tube is inserted and exposed to the outside.

In addition, the secondary battery module of the present invention can easily collect and discharge the gas. The secondary battery module includes: two battery cells having electrode tabs formed on one side thereof and stacked side by side; A case having both sides open to receive the battery cells therein; A lower cap coupled to an open side of the case, the lower cap coupled to an opposite side of the electrode tabs; A first connection mold inserted between opposed pouches of the two battery cells and having a gas flow path passing through the upper and lower sides; A second connection mold coupled to the other side of the first connection mold and having a plurality of terminals formed on one side thereof connected to the electrode tabs and a gas collecting part communicating with the gas flow path; And an upper cap coupled to the case so as to surround an outer side of an opposing pouch on an electrode tab side of the two battery cells and connected to the gas collecting part, ; Wherein the gas generated in the battery cells is discharged into opposing battery cells on the side where the electrode tabs of the battery cells are formed and is collected in the gas collecting part through the gas flow path, .

In addition, the first connection mold has gas discharge grooves formed at the center of both sides thereof, and the gas discharge groove communicates with the gas collecting portion of the second connection mold.

The battery pack according to claim 1, further comprising a cell frame interposed between the two battery cells, the battery cell having an electrode body disposed inside the battery cell, wherein the cell frame includes an upper frame, a pair of side frames, and a lower frame, And the upper frame is integrally formed with the first connection mold to form a gas flow path passing through the upper and lower sides.

The present invention provides a secondary battery module in which gas collection and discharge is easy. In a secondary battery module formed by combining battery cells in a module form, gas generated in the battery cells due to swelling phenomenon is transferred between the battery cells And the space between the electrode tabs, so that it can be discharged to the designated external path, so that it is formed in a compact structure and the gas can be discharged quickly.

1 is a perspective view showing a battery cell according to the present invention.
FIGS. 2 and 3 are an exploded perspective view and an assembled perspective view of a secondary battery module in which gas collection and discharge is easy according to the present invention. FIG.
4 and 5 are cross-sectional views in AA ', BB', CC ', and DD' directions of FIG. 3;
6 is an exploded perspective view showing another embodiment of the present invention.
FIG. 7 is an exploded perspective view and an assembled perspective view of a first connection mold and a second connection mold according to the present invention. FIG.
9 and 10 are cross-sectional views showing respective cross sections of the secondary battery module of FIG. 6 assembled.
11 and 12 are an exploded perspective view and an assembled perspective view showing a combined structure of a battery cell and a cell frame according to the present invention.
13 is an exploded perspective view showing a coupling structure of the upper cap and the second connection mold according to the present invention.
FIG. 14 is a cross-sectional view showing a coupled state of a lower cap according to the present invention. FIG.

Hereinafter, the secondary battery module according to the present invention will be described in detail with reference to the accompanying drawings.

2 and 3 are an exploded perspective view and an assembled perspective view of a secondary battery module in which gas collection and discharge is easy according to the present invention, and FIGS. 4 and 5 are cross- AA ', BB', CC ', DD' of FIG.

As shown in the drawing, the secondary battery module 1000 has a structure in which electrode tabs 120 are formed on one side of the battery cell 100, and two battery cells 100 are stacked side by side. A case 300 in which the battery cells 100 are accommodated and the opposite side of the battery cells 100 on which the electrode tabs 120 are located is sealed; A plurality of terminals 510 inserted between the opposing electrode tabs 120 and the pouches 130 of the two battery cells 100 are connected to the electrode tabs 120, A connection mold 500 in which a collecting part 580 is formed; And a case 300 connected to the upper side of the connection mold 500 and surrounding the opposite pouch 130 on the side where the electrode tabs 120 of the two battery cells 100 are formed, An upper cap 600 in which a gas discharging portion 650 communicating with the gas collecting portion 580 is formed; And the gas generated from the battery cells 100 is discharged to the opposing battery cells 100 on the side where the electrode tabs 120 of the battery cells 100 are formed, And is discharged to the outside through the gas discharging unit 650.

1, the electrode tab 120 is formed on one side of the electrode assembly 110. [ The electrode body 110 is formed of an anode, a cathode, an electrolyte, and a separator separating the anode and the cathode. The electrode body 110 is filled with and discharged from the electrode body. It is the part that transmits the current that flows when charging. The battery cell 100 may be a sealed pouch type cell surrounded by the pouch 130 or an external member coupled to the outside of the pouch type cell. The electrode body 110 sealed by the pouch 130 may be a pouch- Or may protrude from only one side surface of the base 130, or may protrude from both sides.

In this case, as shown in FIG. 2, the two battery cells 100 are stacked side by side so that the electrode tabs 120 face each other. When the electrode bodies 110 protrude from one side of the pouch 130, And the pouches 130 of the two battery cells 100 are stacked so that the pouches 130 protrude outward in the width direction. That is, the battery cells 100 are stacked such that the electrode tabs 120 of the two battery cells 100 are spaced apart from each other by a certain distance.

Referring to FIG. 3, the case 300 is inserted into the case 300 by inserting two battery cells 100 in a stacked state. The case 300 may be formed of a thin metal plate having a thickness of 0.1 mm to 1.0 mm, and a central portion of both sides in the width direction may be recessed inwardly of the case 300, or a plurality of grooves recessed inward may be formed The two battery cells 100 accommodated in the case 300 can be brought into close contact with each other.

The lower cap 400 may be formed in a hollow shape so that the upper side of the lower cap 400 is open. When the two battery cells 100 are inserted into the case 300, 120 to the open side of the case 300 on the opposite side. That is, the lower cap 400 is formed as a cap type so that the opened lower side of the case 300 is inserted into the hollow inside of the lower cap 400, and the lower side of the case 300 is sealed. At this time, when the lower cap 400 is coupled with the battery cells 100 housed in the case 300, the electrode tabs 120 protrude to the outside of the upper side of the case 300, It is preferable that the case 300 is formed to be slightly shorter than the battery cell 100 because the electrode tabs 120 are easily connected electrically.

A connection mold 500 is inserted between the electrode tabs 120 and the pouch 130 of the two battery cells 100 and a plurality of terminals 510 formed on one side of the connection mold 500 are connected to the electrode pads 130, Tabs 120 are connected. As shown in FIG. 4B, the connection mold 500 includes a gas collecting part 580 passing through the upper and lower parts, so that the gas generated from the battery cells 100 is collected by the gas collecting part 580. At this time, the connection mold 500 is inserted between the opposing electrode tabs 120 of the two battery cells 100 and the pouch 130, and the terminals 510 are electrically connected to the electrode tabs 120 by welding Lt; / RTI > That is, the connection mold 500 is inserted between the opposing electrode tabs 120 of the two battery cells 100 and the pouch 130 to support the inside of the electrode tab 120, And the gas collecting part 580 is formed to secure the terminals 510 connected to the electrode tabs 120 and the battery cells 100 To be discharged to the outside. Before the connection mold 500 is inserted, a hot melt adhesive or the like may be applied between the pouches 130 of the two battery cells 100, and then the connection mold 500 may be inserted and fixed.

The upper cap 600 is inserted into the coupling mold 500 and then coupled to the upper side of the coupling mold 500. The upper cavity 600 is hollow and the lower side is opened to be inserted and coupled to the outer side of the case 300. The upper cap 600 is coupled to the case 300 so as to surround the opposite pouch 130 on the side where the electrode tabs 120 of the two battery cells 100 are formed, A communicating gas discharging portion 650 is formed.

Thus, the gas generated in the battery cells 100 is discharged into the battery cells 100 on the side where the electrode tabs 120 of the battery cells 100 are formed, is collected in the gas collection unit 580, (650).

In this case, the upper cap 600 is formed with a cut-out portion 610 so that the terminals 510 of the connection mold 500 are exposed to the outside, so that the terminals 510 are connected to the external circuit after the upper cap 600 is coupled And the periphery of the incision portion 610 is preferably closed so that the gas is not discharged to the outside through the incision portion 610.

As described above, in the secondary battery module of the present invention, which is easy to collect and discharge gas, in a secondary battery module formed by combining the battery cells in a module form, the gas generated in the battery cells by the swelling phenomenon, It is possible to collect gas in the space between the cells and between the electrode tabs and to discharge it to the designated external path, thereby forming a compact structure and discharging gas quickly.

As shown in FIGS. 2 to 5, the terminal 510 is formed with a cathode terminal 511 and a cathode terminal 512 on one side in the longitudinal direction of the connection mold 500 and 500b and a voltage sensing terminal 513 on the other side The anode terminal 511 is bent to one side from the upper surface of the connection mold 500 and the anode terminal 512 is bent from the upper surface to the other side of the connection mold 500, Terminals 513 may be formed on both sides of the upper surface of the connection mold 500. Thus, when the two battery cells 100 are connected in series, the terminals 510 are easily welded to the electrode tabs 120. That is, the terminals 510 formed on the upper surface of the connection mold 500 are formed in a bent shape so that the terminal 510 and the electrode tab 120 can be coupled by welding in a state of being overlapped, The terminal 510 can be extended in the width direction side of the terminal 510. [

The two battery cells 100 are laminated such that the positive electrode tab 120a and the negative electrode tab 120b face each other and the positive electrode terminal 511 is connected to the positive electrode tab 120a of the first battery cell 100a, The negative electrode terminal 512 is connected to the negative electrode tab 120b of the second battery cell 100b and the voltage sensing terminal 513 is connected to the negative electrode tab 120b of the first battery cell 100a and the negative electrode tab 120b of the second battery cell 100b To the positive electrode tab 120a. This is because the electrode tabs 120 having different polarities of the battery cells 100 are stacked so as to face each other in order to connect the two battery cells 100 in series and the first battery cell 100a, The positive electrode tab 120a of the first battery cell 100a is coupled to the negative electrode tab 120b of the second battery cell 100b by the voltage sensing terminal 513, 120b are connected to the negative terminal 512 and the positive electrode tab 120a of the second battery cell 100b is coupled to the positive electrode terminal 511. [ The positive electrode terminal 511 and the negative electrode terminal 512 are formed on one side of the longitudinal direction of the connection mold 500 because the two battery cells 100 are stacked so that the electrode tabs 120 having different polarities face each other, It is preferable that the voltage sensing terminal 513 is formed on the other side in the longitudinal direction.

The two battery cells 100 are stacked such that the positive electrode tab 120a and the negative electrode tab 120b face each other so that the positive electrode terminal 511 is connected to the positive electrode tab 120a of the battery cells 100, The terminals 512 may be connected to the negative electrode tabs 120b of the battery cells 100 so that the two battery cells 100 may be connected in parallel.

The pouch 130 on the side where the electrode tab 120 is formed may be in close contact with the connection mold 500 and the case 300. That is, both sides of the pouch 130 formed with the electrode tabs 120 on the upper side of the battery cell 100 are closely contacted by the connection mold 500 and the case 300 so that the gas generated in the battery cell 100 It is possible to prevent leakage to the pouch 130 on the side where the electrode tab 120 is formed. Thus, the gas can be collected by the gas collecting unit 580 through the spaces between the battery cells 100. 4 and 5, the pouch 130 and the case 300 may be slightly floated, but may be in close contact with each other, and may be in close contact with the upper cap 600 coupled to the outside of the case 300. [ have.

The connection mold 500 is formed with a gas collecting part 580 having a lower side opened and a hollow inside and a gas exhausting pipe 581 formed on the upper side of the connecting mold 500. The upper cap 600 has a gas exhaust pipe 581, The insertion hole 651 may be formed to be exposed to the outside. This is because the gas collecting part 580 is formed inside the connection mold 500 while the inner side and the outer side of the pouch 130 of the battery cells 100 are closely contacted by the connection mold 500 and the case 300, A gas discharge pipe 581 is formed on the upper side so as to communicate with the collecting part 580 and inserted into the insertion hole 651 of the upper cap 600 to discharge the gas to the outside.

In addition, the secondary battery module 1000, which is easy to collect and discharge gas of the present invention, includes two battery cells 100 formed with electrode tabs 120 on one side and stacked side by side. A case 300 having both sides opened to receive the battery cells 100 therein; A lower cap 400 coupled to an open side of the case 300 and coupled to an opposite side of the electrode tabs 120; A first connection mold 500a inserted between opposed pouches 130 of the two battery cells 100 and having a gas flow path 590 passing through the top and bottom thereof; A plurality of terminals 510 formed on one side of the first connection mold 500a are connected to the electrode tabs 120 and a gas collecting part 580 connected to the gas flow path 590 A second connection mold 500b to be formed; And a second connection mold 500b coupled to the case 300 so as to surround the outside of the opposite pouch 130 on the side where the electrode tabs 120 of the two battery cells 100 are formed. An upper cap 600 having a gas discharging portion 650 communicating with the gas collecting portion 580; And the gas generated from the battery cells 100 is discharged to the opposing battery cells 100 on the side where the electrode tabs 120 of the battery cells 100 are formed, The gas may be collected in the gas collecting part 580 and discharged to the outside through the gas discharging part 650.

This is because the connection mold 500 in the former embodiment is constituted by the first connection mold 500a and the second connection mold 500b as shown in Figures 6 to 10 so that the first connection mold 500a is connected to the two batteries 500a, The second connection mold 500b is coupled to the upper side of the first connection mold 500a and the second connection mold 500b is connected to the upper side of the second connection mold 500b. (510) are formed to connect the terminals (510) to the electrode tabs (120). At this time, a gas flow path 590 is formed in the first connection mold 500a so as to pass through the first connection mold 500a, and a gas collecting part 580 communicating with the gas flow path 590 is formed in the second connection mold 500b, The gas generated in the cells 100 is discharged into the battery cells 100 through the gas passage 590 and collected in the gas collecting unit 580 and discharged to the outside through the gas discharging unit 650.

At this time, the first connection mold 500a has gas discharge grooves 591 formed at the center of both sides thereof, and the gas discharge groove 591 is communicated with the gas collecting part 580 of the second connection mold 500b . 6 to 9, gas discharge grooves 5910 are formed at both sides in the width direction of the first connection mold 500a so that the pouch between the electrode tabs 120 in the longitudinal direction of the battery cells 100 130).

Here, the first connection mold 500a is formed with hollow portions 520 opened on both sides in the longitudinal direction thereof, and coupling holes 521 are formed on both side surfaces of the hollow portions 520, Hooks 540 inserted into the hollow portion 520 of the first connection mold 500a and coupled to the coupling holes 521 may be formed on both sides of the lower surface of the mold 500b. Thus, after the first connection mold 500a is inserted and fixed between the opposing electrode tabs 120 of the battery cells 100, the second connection mold 500b can be press-fitted on the upper side thereof to facilitate coupling .

This is because the connecting mold 500 is formed integrally with the battery cell 100 as in the case of the former case, and is easily fixed between the battery cells 100, Since the first connection mold 500a is inserted and fixed after applying an adhesive or the like, and the second connection mold 500b can be easily coupled to the upper side of the first connection mold 500a, the assembling property is improved.

At this time, a guide 541 is protruded from both sides in the longitudinal direction where the hook 540 of the second connection mold 500b is formed, and the hook 540 is inserted into the hollow portion 520 of the first connection mold 500a And can be easily coupled to the coupling hole 521.

The first connection mold 500a has fixing grooves 530 formed on both sides thereof so that the pouch 130 of the two battery cells 100 can be inserted into the fixing groove 530. [ As shown in FIGS. 6 to 8 and 11, the fixing grooves 530 are formed by the fixing vanes 531 formed to protrude outward at the both ends in the longitudinal direction of both widthwise side surfaces of the first connection mold 500a, The pouch 130 which is the upper edge of the battery cell 100 is inserted into the fixing groove 530 when the one connection mold 500a is inserted between the battery cells 100. [ Since the first connection mold 500a is attached to the pouch 130 of the battery cells 100 by the fixing groove 530, the depth of the first connection mold 500a can be accurately lowered, It is easy to maintain the horizontal positions of the cells 100 and the first connection mold 500a. Since the second connection mold 500b coupled to the upper side of the first connection mold 500a is also horizontally held, the connection position between the electrode tabs 120 and the terminals 510 formed in the second connection mold 500b Is correct. The lower surfaces of the electrode assembly 110 and the first connection mold 500a of the battery cells 100 may be spaced apart from each other by a predetermined distance so that the gas generated from the battery cells 100 flows to the gas collection portion 580 There is an advantage that it is easy to become.

The cell frame 200 further includes a cell frame 200 interposed between the two battery cells 100 and having the electrode body 110 of the battery cells 100 housed therein. The cell frame 200 includes a pair of side frames 220 and a lower frame 230. The cell frame 200 has an opening 201 formed therein and an electrode body 110 of the battery cells 100, And the upper frame 210 is formed integrally with the first connection mold 500a so that a gas flow path 590 passing through the upper and lower portions may be formed.

12 and 13, the cell frame 200 is laminated so that the cell frame 200 is interposed between the two battery cells 100. In this case, the cell frame 200 is formed such that the open portion 201, A frame 210, a pair of side frames 220, and a lower frame 230. The pouch 130 is coupled to the cell frame 200 so that the pouch 130 is closely contacted with the electrode frame 110 of the battery cells 100, And may be coupled to be inserted into the latching groove 221 formed in the side frame 220. As shown in FIG. The upper frame 210 may be integrally formed with the first connection mold 500a and the first connection mold 500a may be coupled to the side frame 220 instead of the upper frame 210. [ have.

Thus, the battery cells 100 can be firmly fixed by the cell frame 200 and the case 300, and the gas generated from the battery cells 100 can flow along the gas flow path 590 to the second connection mold 500b Is collected in the gas collecting part 580 of the gas collecting part 580 and discharged to the outside through the gas discharging pipe 581. Therefore, it is manufactured in a compact form and is electrically connected to the electrode tabs, It is easy to assemble in module form.

The second connection mold 500b is formed with a pair of guide plates 550 at the center of both widthwise sides of the pouch 130 and the first connection mold 500a and the pouch 130 of the two battery cells 100. [ Can be inserted between the guide plates (550). That is, when the second connection mold 500b is inserted between the opposing electrode tabs 120 of the battery cells 100 as shown in FIGS. 7, 8 and 9B, The electrode tabs 120 can be brought into close contact with the side surface of the terminal 510.

The second connection mold 500b is formed with insertion holes 560 and through holes 561 through which the nuts 570 are inserted at both sides in the longitudinal direction and the upper cap 600 is inserted through the through- A fixing hole 620 corresponding to the hole 561 is formed and can be coupled to the nut 570 with a bolt 571 from the outside of the upper cap 600. [

14, since the second connection mold 500b can be formed of plastic resin, the metal nut 570 is inserted and fixed in the insertion groove 560, and the upper cap 600 is covered and bonded The upper cap 600 can be firmly fixed to the second connection mold 500b by being fastened to the nut 570 through the fixing hole 620 and the through hole 561 using the bolt 571 from the outside .

The connection molds 500, 500a and 500b and the upper cap 600 are preferably formed of a plastic material for electrical insulation and the lower cap 400 may be formed of various materials such as plastic or metal.

The lower cap 400 may be coated with molten resin such as hot melt or adhesive or the like on the inner side of the lower cap 400 for fixing the battery cells 100 and the case 300, The injection port 410 may be formed so that the molten resin and the adhesive may be injected after being coupled to the lower side of the case 300.

The protrusions 630 and the grooves 640 are formed on both side surfaces in the width direction of the upper cap 600 so that a plurality of secondary battery modules can be stacked to precisely locate the battery pack when assembled.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It goes without saying that various modifications can be made.

1000: secondary battery module
100: Battery cell
100a: first battery cell 100b: second battery cell
110: electrode body 120: electrode tab
120a: positive electrode tab 120b: negative electrode tab
130: Pouch
200: cell frame 201: opening part
210: upper frame
220: side frame 221: latching groove
230: Lower frame
300: Case
400: lower cap 410: inlet
500: connection mold
500a: first connection mold 500b: second connection mold
510: terminal 511: positive terminal
512: Negative terminal 513: Voltage sensing terminal
520: hollow part 521: engaging hole
530: Fixing groove 531: Fixing blade
540: Hook 541: Guide
550: guide plate 560: insertion groove
561: Through hole
570: Nut 571: Bolt
580: Gas collection part 581: Gas discharge pipe
590: Gas flow path 591: Gas discharge groove
600: upper cap
610: incision section 620: stationary hole
630: projection 640: home
650: gas discharge part 651: insertion hole

Claims (6)

Two battery cells in which electrode taps are formed on one side of the electrode body, the electrode bodies are sealed by a pouch, and are stacked on each other;
A case in which the battery cells are housed therein and the opposite side of the battery cells where the electrode tabs are located is sealed;
A plurality of terminals formed on one side of the two battery cells are connected to the electrode taps, and the gas collecting pipe is disposed between the opposite electrode taps of the two battery cells, A connection mold having a part formed therein; And
An upper cap coupled to an upper side of the connection mold and coupled to the case so as to surround an opposing pouch on the side where the electrode tabs of the two battery cells are formed, and a gas discharge part communicating with the gas collection part; / RTI >
The gas generated in the battery cells is discharged to the opposing battery cells on the side where the electrode tabs of the battery cells are formed and the gas collected and discharged through the gas collecting part to the outside is easily collected and discharged A secondary battery module.
The method according to claim 1,
Wherein the two battery cells are easy to collect and discharge gas in which the pouch on the side where the electrode tab is formed is closely contacted by the connection mold and the case.
The method according to claim 1,
The connection mold is formed with a gas collecting part having a lower side opened, a hollow interior and a gas exhausting tube formed on the upper side. The upper cap has an insertion hole through which the gas exhausting tube is inserted and is exposed to the outside. Battery module.
Two battery cells in which electrode taps are formed on one side of the electrode body, the electrode bodies are sealed by a pouch, and are stacked on each other;
A case having both sides open to receive the battery cells therein;
A lower cap coupled to an open side of the case, the lower cap coupled to an opposite side of the electrode tabs;
A first connection mold inserted between the two battery cells at one side where electrode tabs of the two battery cells are formed and a gas flow path passing through the upper and lower at positions corresponding to between the electrode tabs of the battery cells in the longitudinal direction, ;
A plurality of terminals formed on one side are connected to the electrode tabs, and a gas collecting part connected to the gas channels is formed. The gas collecting part is formed between the electrode tabs of the two battery cells, A second connecting mold; And
An upper cap coupled to an upper side of the second connection mold and coupled to the case so as to surround an opposing pouch on the side where the electrode tabs of the two battery cells are formed, and a gas discharge part communicating with the gas collection part; / RTI >
The gas generated in the battery cells is discharged into opposing battery cells on the side where the electrode tabs of the battery cells are formed and is collected in the gas collecting part through the gas flow path and discharged to the outside through the gas discharging part. And a secondary battery module that is easy to discharge.
5. The method of claim 4,
Wherein the first connection mold has gas discharge grooves formed at the center of both side surfaces thereof to easily collect and discharge gas through which the gas discharge groove communicates with the gas collecting portion of the second connection mold.
5. The method of claim 4,
Further comprising a cell frame interposed between the two battery cells, the electrode frame of the battery cells being positioned inside,
Wherein the cell frame includes an upper frame, a pair of side frames, and a lower frame, wherein the cell frame has an opening formed therein, the electrode body of the battery cells being positioned in an opening, And the gas flow path passing through the upper and lower portions is formed, thereby facilitating gas collection and discharge.

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