KR101229411B1 - Battery pack for preventing fire, oxidation and method for manufacturing thereof - Google Patents

Abstract

PURPOSE: A battery pack for preventing fire and oxidation is provided to prevent oxidation, fire, and explosion of the battery pack by filling gas for preventing oxidation and fire into a sealed inner space of the battery pack. CONSTITUTION: A battery pack(100) comprises: a battery pack case(110) which comprises upper and lower cases(112,114) and side wall cases(120-126); coupling parts(130-136) which couple the inclined both ends of the neighboring side wall cases to each other; airtight elements which seal a coupling side between the side cases; gaskets which are capable of sealing a gap between the upper and lower cases and between the side wall cases; and a gas supply port(200) and a gas discharge port(210) which fill the inner space of the battery pack case with gas for preventing oxidation and fire.

Description

Battery pack for oxidation and fire prevention and manufacturing method {BATTERY PACK FOR PREVENTING FIRE, OXIDATION AND METHOD FOR MANUFACTURING THEREOF}

The present invention relates to a battery pack, and more particularly, to a battery pack for minimizing thickness, filling a gas for oxidation and fire prevention gas inside a battery pack case capable of heat dissipation, insect repellent, and waterproof.

Recently, as technology development and demand for portable electronic devices have increased, the demand for secondary batteries as a power supply source for portable electronic devices has increased rapidly. The secondary battery may be used in the form of a single battery (battery cell) according to the type of external device applied. In addition, a battery pack formed of one unit by electrically connecting a plurality of battery cells may be used.

Small devices such as mobile phones can operate for a predetermined period of time with the power and capacity of a single cell. However, long-term driving and high-power driving are required, such as mobile devices such as notebook computers and camcorders, or electric bicycles, electric scooters, electric cars, and hybrid cars, which consume a lot of power. Electric bicycles, electric scooters, and electric vehicles are mainly used outdoors, and according to weather or road conditions such as rain or snow, there is a problem in that the battery packs mounted on these devices are impacted or water penetrates, causing shorts. .

In addition, the heat generated by the high power driving by the battery pack is also to be discharged to the outside, the conventional battery pack has a problem that the efficiency of the battery pack is lowered because the external discharge of the generated heat is not made well. As a result, the battery cells may explode or fire due to an increase in temperature inside the battery pack.

In addition, since the number of battery cells is increased due to an increase in capacity, such a battery pack has a problem in that the size and weight of a battery pack case for accommodating the battery cells is increased.

SUMMARY OF THE INVENTION An object of the present invention is to provide a battery pack and a method of manufacturing the same, in which a gas for preventing oxidation and fire is filled in a space inside a battery pack case.

Another object of the present invention is to provide a battery pack and a method of manufacturing the battery pack case having a battery pack case in which the corner portion is inclined at an angle from the X-Y axis direction in order to reduce the weight of the battery pack case.

Still another object of the present invention is to provide a battery pack case having a plurality of heat sinks, a battery pack having the same, and a method of manufacturing the same.

Still another object of the present invention is to provide a battery pack having a battery pack case having a thermoelectric sheet on the terminals of a plurality of battery cells to emit heat and mitigate impact, and a method of manufacturing the same.

Still another object of the present invention is to provide a battery pack having a battery pack case having a waterproof o-ring and a method of manufacturing the same.

In order to achieve the above objects, the battery pack is characterized in that the gas supply port and the gas discharge port installed on one side of the battery pack case is filled with the gas for oxidation and fire protection in a sealed inner space. Such a battery pack can prevent oxidation, fire and explosion.

A battery pack of the present invention according to this aspect includes a plurality of battery cells; A battery pack case including an upper case, a lower case, and a plurality of sidewall cases to form an inner space for accommodating the battery cells; A plurality of coupling portions formed at both ends of each of the side wall cases to be inclined and coupled to the both ends of adjacent side wall cases among the side wall cases; A plurality of sealing members installed on the coupling surfaces of the coupling portions to seal the coupling surfaces between the adjacent sidewall cases; The upper case and the upper surface of the combined sidewall cases, and the lower case and the lower surface of the combined sidewall cases, respectively, are installed between the upper case and the upper surface, and the lower case and the lower surface, respectively. A plurality of gaskets; It is installed on one side of the battery pack case includes a gas supply port and a gas discharge port for filling the gas for oxidation and fire protection into the sealed inner space.

In one embodiment, each of the gas supply port and the gas discharge port; An opening that is partially exposed at one side of the battery pack case; A pipe inserted into the battery pack case and connected to the opening; And a valve installed between the opening and the pipe to open and close according to gas supply and discharge.

In another embodiment, the pipe is provided so that the gas supply port and the gas discharge port supply or discharge gas at different positions of the internal space.

In another embodiment, the coupling portion; One end of one of the adjacent sidewall cases is inclinedly extended, and the other end of the other one adjacent to the one extending inclined to form a coupling surface, the coupling surface is the one and the other Has an angle of inclination 45 degrees outward with respect to the XY coordinate system formed by the sidewall casings.

In another embodiment, the coupling portion; An insertion groove into which the sealing member is inserted in the vertical direction of the coupling surface is formed in the coupling surface of any one of the adjacent side wall cases.

In another embodiment, the battery pack further comprises: A power input terminal provided at one side of the battery pack case to supply power for charging the battery cells; A circuit board installed in the inner space and receiving power from the power input terminal to charge or balance and control the battery cells; A signal input terminal provided at one side of the battery pack case to input signals for charging and discharging the battery cells to the circuit board; A separating plate separating the internal space into a space for installing the circuit board and the battery cells, respectively; Is installed on one side of the battery pack case opposite to the circuit board to transfer heat generated from the circuit board to one side of the battery pack case, or installed between the plurality of terminals formed on the battery cells and the upper case And a plurality of thermoelectric sheets transferring heat generated from the terminals to the upper case and buffering vibrations and shocks applied from the outside of the upper case.

In another embodiment, each of the gas supply port and the gas discharge port; The pipe is installed to be disposed between the circuit board and the separator.

According to another feature of the invention, there is provided a method of manufacturing a battery pack. According to this method, gas for oxidation and fire prevention can be filled in the internal space of the battery pack.

In the battery pack manufacturing method according to this aspect, an upper case, a lower case, and a plurality of sidewall cases are coupled to seal the inner space of the battery pack case accommodating the plurality of battery cells in the inner space. A gas supply port installed at one side of the battery pack case to supply oxidation and fire protection gas to the sealed inner space, and gas discharge for discharging a mixed gas of air and the oxidation and fire protection gas mixed in the inner space; It has a port. A gas supply pipe connected to a gas supply source is mounted on the gas supply port to supply the oxidation and fire protection gas to the internal space, and at the same time, a gas discharge pipe is connected to the gas discharge port to discharge the mixed gas. Subsequently, the concentration of the oxidation and fire protection gas in the internal space is measured using the discharged mixed gas, and when a concentration of a predetermined level or more is detected, the gas discharge pipe is separated from the gas discharge port, and the gas supply port The gas supply pipe is separated from the gas to complete the oxidation and fire protection gas filling.

As described above, the battery pack of the present invention includes a gas supply port and a gas discharge port for filling oxidation and fire protection gas into an inner space of the sealed battery pack, thereby preventing oxidation, fire, and explosion. Can provide.

In addition, the battery pack of the present invention includes a plurality of coupling parts which are both ends of the adjacent side wall case is extended to be inclined mutually, thereby minimizing the thickness of the side wall case, thereby reducing the weight of the battery pack.

In addition, the battery pack of the present invention can improve the heat dissipation effect by providing a plurality of heat dissipation fins on the surface of the side wall case.

In addition, the battery pack of the present invention is provided with an O-ring on the coupling surface of the coupling portion, and by installing a gasket between the upper and lower case and the side wall case coupled, it is possible to seal the internal space of the battery pack case, thereby waterproofing effect To provide.

In addition, the battery pack of the present invention includes a thermoelectric sheet between a portion where the most heat is generated, for example, between the side wall case and the circuit board, and between the terminals of the battery cells and the upper case, thereby preventing heat dissipation due to balancing adjustment and heat dissipation of the terminals. It can be delivered quickly to the battery pack case to improve the heating effect, and to alleviate the vibration and shock generated from the outside.

1 is a perspective view showing the configuration of a battery pack according to the present invention;
2 and 3 are perspective views showing the internal configuration of the battery pack shown in FIG.
4 is a plan view illustrating one coupling portion to which sidewall cases illustrated in FIG. 1 are coupled;
FIG. 5 is a cross-sectional view illustrating a coupling state between terminals of the battery cell and the upper case of FIG. 3; FIG.
FIG. 6 is a cross-sectional view showing the configuration of the gas supply port and the gas discharge port shown in FIG. 1; FIG. And
7 is a view showing a configuration for filling the gas for oxidation and fire protection of the battery pack according to an embodiment of the present invention.

The embodiments of the present invention can be modified into various forms and the scope of the present invention should not be interpreted as being limited by the embodiments described below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the components in the drawings are exaggerated in order to emphasize a clearer explanation.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 1 to 7.

1 is a perspective view showing the configuration of a battery pack according to the present invention.

Referring to FIG. 1, the battery pack 100 of the present invention is a large capacity battery pack used in, for example, an electric vehicle, a hybrid car, a golf cart, an electric bicycle, an electric scooter, and the like. The internal space of the battery pack case 110 to accommodate the 160 of the oxidation and fire protection gas has a structure for filling. The battery pack also has a configuration for heat dissipation, insect repellent and waterproof.

That is, the battery pack case 110 is generally provided in a rectangular parallelepiped shape, and includes an upper case 112, a lower case 114, and a plurality of sidewall cases 120 to 126. Each of the upper and lower gates 112 and 114 and the side wall cases 120 to 126 is provided in a plate shape having a constant thickness.

The upper case 112 is coupled to the upper surface of the side wall cases 120 to 126 that are coupled to each other and the lower case 114 is coupled to the lower side of the side wall cases 120 to 126 that are coupled to each other. For example, each of the upper and lower cases 112 and 114 is provided in the shape of a plate having the same or substantially similar size as the upper or lower surface of the side wall cases 120 to 126, which are mutually coupled.

Each of the side wall cases 120 to 126 is provided in the shape of a rectangular plate having a predetermined thickness. In order to improve the bonding force between the adjacent side wall cases and minimize the thickness, (130 to 136).

In addition, any one of the side wall cases 120 to 126 is provided with a gas supply port 200 and a gas discharge port 210 for filling the gas for oxidation and fire protection in the inner space.

In addition, each of the side wall cases 120 to 126 includes a plurality of radiating fins 140 protruding outward to dissipate heat of the battery pack 100. The radiating fins 140 extend in the vertical direction on the outer surface of the side wall case 120 to 126. In order to improve the heat radiation effect, a plurality of heat dissipation fins 140 are arranged on the outer surface of the side wall case 120 to 126 at regular intervals. In addition, the heat dissipation fins 140 may prevent the side wall cases 120 to 126 from being bent due to the minimized thickness of the side wall cases.

In detail, the side wall cases 120 to 126 include first to fourth side wall cases 120 to 126. The first sidewall case 120 and the third sidewall case 124 are disposed parallel to each other and the second sidewall case 122 and the fourth sidewall case 126 are disposed parallel to each other.

One of the first to fourth sidewall cases 120 to 126 includes a gas supply port 200 and a gas discharge port 210 for filling the internal space of the battery pack case 110 with oxidation and fire protection gas. Is provided. Oxidation and fire protection gases include, for example, nitrogen (N 2) gas and the like. The gas supply port 200 and the gas discharge port 210 are sealed by caps 220, 230, and the like when the gas for oxidization and fire protection is filled in the internal space. The gas supply port 200 and the gas discharge port 210 may be installed at various positions according to the structure and internal space of the battery pack case 110. In this embodiment, the gas supply port 200 and the gas discharge port 210 are installed side by side on one side of the first side wall case 120, for example, above the power input terminal 102.

At both ends of each of the first to fourth side wall cases 120 to 126, coupling portions 130 to 136 are formed. The engaging portions 130 to 136 are formed such that both ends of each of the first to fourth side wall cases 120 to 126 are inclined at a predetermined angle in the outward direction with respect to the side wall case. The engaging portions 130 to 136 have the same thickness as the side wall case and extend to have a predetermined length.

The coupling parts 130 to 136 may include a first coupling part 130 to which the first and second side wall cases 120 and 122 are coupled, and a second coupling to which the second and third side wall cases 122 and 124 are coupled to each other. The third coupling portion 134 to which the portion 132, the third and fourth sidewall cases 124 and 126 are coupled, and the fourth coupling portion to which the fourth and first sidewall cases 126 and 120 are coupled ( 136).

The first to fourth coupling units 130 to 136 form a coupling surface such that an inner surface to which adjacent sidewall cases are coupled has an angle with respect to an inner surface of the sidewall case. For example, as shown in FIG. 4, the coupling surface is angled 45 degrees from the X and Y axes on the XY coordinate axis, which originates from a linear edge portion of each of two adjacent sidewall cases 120 and 126 that extends perpendicularly. It is formed to be inclined. Each of the first to fourth coupling units 130 to 136 is coupled to the adjacent sidewall cases 120 and 126 using a plurality of fastening screws 130c.

The first side wall case 120 is disposed on the front surface of the battery pack 100 and includes a power input terminal 102 for supplying power for charging the battery cells 160 into the battery pack 100, A signal input terminal 104 for transmitting various control signals according to battery charging, battery balancing and the like is provided on the circuit board (180 in FIG. 2) of the pack 100. In addition, the first side wall case 120 is provided with a gas supply port 200 and the gas discharge port 210 side by side above the power input terminal (102). First and second coupling parts 130 and 132 are provided at both sides of the first sidewall case 120. That is, one end of the first side wall case 120 is coupled to the fourth side wall case 126 by the first coupling part 130, and the other end thereof is the second side wall case 122 by the second coupling part 132. Combined with.

The second sidewall case 122 is coupled with the first and third sidewall cases 120 and 124. To this end, both sides of the second sidewall case 122 are provided with second and third coupling parts 132 and 134, respectively. The third side wall case 124 is provided with third and fourth coupling parts 134 and 136 at both ends thereof, and is coupled to the second and fourth side wall cases 122 and 126, respectively. The fourth sidewall case 126 is provided with fourth and first coupling parts 136 and 130 at both ends thereof, and is coupled to the third and first sidewall cases 124 and 120.

Each of the first to fourth side wall cases 120 to 126 is provided with a plurality of coupling parts 150 for coupling the upper case 112 and the lower case 114. The fastening portions 150 protrude outward from the surfaces of the first to fourth side wall cases 120 to 126, respectively. The fastening part 150 extends in the vertical direction from the outer surface of the side wall case and protrudes. The fastening part 150 is formed with a threaded hole passing through the threaded hole in the vertical direction, and is screwed to the upper case 112 and the lower case 114 through the threaded hole.

The battery pack 100 according to the present invention includes the battery pack case 110 coupled to adjacent side wall cases using a plurality of engaging portions 130 to 136 extending obliquely, Can be minimized. Further, a plurality of heat dissipation fins 140 may be provided on the surfaces of the side wall cases 120 to 126 to improve the heat dissipation effect.

2 and 3 are perspective views illustrating a part of an internal configuration of the battery pack shown in FIG. 1.

2 and 3, in the battery pack 100, a circuit board 180 is installed on one side of the battery pack case 110, and a plurality of battery cells 160 are stacked side by side on the other side of the battery pack case 110. A separation plate 170 is installed between the circuit board 180 and the battery cells 160.

The battery cells 160 are exposed to the terminals 162 and 164 at the upper portion thereof and are electrically connected to each other in series or in parallel. For example, terminals 162 and 164 include first and second terminals 162 and 164 for one battery cell. The first terminal 162 is electrically connected to the second terminal 164 through the inside of the battery cell 160, and the second terminal 164 is connected to the adjacent battery cells in series or in parallel with each other.

The separation plate 170 separates the internal space of the battery pack case 110 into a space for accommodating the battery cells 160 and a space for installing the circuit board 180. That is, the separator 170 fixes the battery cells 160 stacked in the battery pack case. The separation plate 170 is spaced apart from the bottom surface of the circuit board 180 by a predetermined distance to support the circuit board 180.

The circuit board 180 includes, for example, a battery charging circuit, a balancing control circuit, a control circuit for controlling them, and the like, and is electrically connected to the power input terminal 102 and the signal input terminal 104. The circuit board 180 receives power to charge the battery cells 160, senses the balancing current, and discharges the battery cell 160 through the balancing control circuit.

The battery pack 100 includes a first thermoelectric sheet 182 between the first sidewall case 120 and the circuit board 180. The first thermoelectric sheet 182 quickly transfers heat generated from the resistance of the circuit board 180, for example, the balancing control circuit, to the first sidewall case 120 to dissipate heat. The first thermoelectric sheet 182 is spaced apart from the upper portion of the balancing control circuit of the circuit board 180 by a predetermined distance and mounted inside the first sidewall case 120.

The battery pack 100 includes first and second gaskets 194 and 196 installed on the upper and lower surfaces of the first through fourth sidewall cases 120 through 126, respectively. The first gasket 194 is provided between the upper surface of the first to fourth side wall cases 120 to 126 and the upper case 112 and the second gasket 196 is provided between the upper side of the first to fourth side wall cases 120 to 126, 126 and the lower case 114 to seal the inner space.

The battery pack 100 further includes a terminal fixing member 172 provided at an upper portion of the battery cells 160 to fix the first and second terminals 162 and 164. The first and second terminals 162 and 164 are partially exposed upward from the first and second terminals 162 and 164 and the exposed first and second terminals 162 and 164 are exposed, (162, 164) are prevented from being damaged by external shock or vibration. Second and third thermoelectric sheets 166 and 168 are attached in both directions to upper portions of the first and second terminals 162 and 164 exposed from the terminal fixing member 172. That is, the second thermoelectric sheet 166 is attached in parallel with the top of the first terminals 162, and the third thermoelectric sheet 168 is attached in parallel with the top of the second terminals 164.

Subsequently, the coupling state of the coupling portion of the battery pack, the terminals of the battery cell, and the upper case will be described in detail with reference to FIGS. 4 and 5. Here, one coupling part, for example, will be described using the first coupling part shown in FIG. 4.

That is, referring to FIG. 4, the first coupling part 130 is a part of the first sidewall case 120 and the fourth sidewall case 126 coupled to each other, and one end of the first sidewall case 120 extends inclined. The portion 130b and the portion 130a on which one end of the fourth sidewall case 126 extends obliquely are coupled to each other by using a fastening screw 130c including a bolt and a nut. The engaging surface to which the two parts 130a and 130b are coupled is about 45 degrees with respect to the XY coordinate system having one corner as the origin on the line where the inner surfaces of the first and fourth sidewall cases 120 and 126 extend perpendicular to each other. Has a photographic angle.

A sealing member 190 is provided on a mating surface to which the first and fourth side wall cases 120 and 126 are coupled. The sealing member 190 is provided with, for example, an o-ring and is inserted in the Z axis direction perpendicular to the vertical direction from the X-Y coordinate system. To this end, an insertion groove 192 into which the sealing member 190 is inserted is formed at any one of the coupling surfaces. Of course, the insertion groove 192 may be formed on both sides of the coupling surface.

Therefore, the battery pack 100 of the present invention is waterproof by sealing the internal space by using the sealing member 190 and the first and second gaskets 194 and 196.

5 is a cross-sectional view illustrating a coupling state of a battery cell terminal and an upper case illustrated in FIG. 3.

Referring to FIG. 5, the battery pack 100 is installed between the first and second terminals 162 and 164 of the battery cells 160 and the upper case 112 so that the second and third thermoelectric sheets 166, 168. Each of the second and third thermoelectric sheets 166 and 168 presses the first or second terminals 162 and 164 in close contact with each other in the Z-axis direction, that is, the vertical direction.

Since the second and third thermoelectric sheets 166 and 168 are installed bidirectionally on top of the first and second terminals 162 and 164 of the battery cells 160, the first and second terminals 162 and 164 are provided. Heat generated from the upper case 112 is transferred to the outside to be discharged. In addition, the second and third thermoelectric sheets 166 and 168 are disposed between the upper case 112 and the first and second terminals 162 and 164 to be generated at the first and second terminals 162 and 164. The contact resistance component may be reduced, and vibration and shock applied to the battery cells 160 from the outside may be alleviated.

6 is a cross-sectional view showing the configuration of the gas supply port and the gas discharge port shown in FIG.

Referring to FIG. 6, the battery pack 100 of this embodiment is installed at one side of the side wall case, for example, the first side wall case 120, so that nitrogen (N 2) gas is stored in the internal space of the battery pack 100. It is provided with a gas supply port 200 and a gas discharge port 210 for filling the. Of course, the gas supply port 200 and the gas discharge port 210 may be installed at any position of the upper case 112, the lower case 114, and the first to fourth sidewall cases 120 to 126.

Each of the gas supply port 200 and the gas discharge port 210 has an opening partially exposed to the outside of the first sidewall case 120. That is, male threads are formed on the outer circumferential surface of each of the openings of the gas supply port 200 and the gas discharge port 210. Each of the gas supply port 200 and the gas discharge port 210 covers the respective openings using the caps 220 and 230 when the nitrogen gas is not filled.

Each of the gas supply port 200 and the gas discharge port 210 of the present embodiment is connected to a pipe inserted through the first side wall case 120 and inserted into the internal space, and the lengths of the pipes are different from each other. This is provided to supply or discharge the gas at different locations, to prevent the nitrogen gas supplied to the internal space through the gas supply port 200 is directly discharged to the gas discharge port 210.

Each of the gas supply port 200 and the gas discharge port 210 is provided with valves 204 and 214 for adjusting the gas supply IN and the discharge OUT. For example, the valves 204 and 214 are disposed between the opening and the pipe, and the gas supply pipe 202 and the gas discharge pipe 212 are respectively connected. One end of each of the gas supply pipe 202 and the gas discharge pipe 212 is formed with a female thread corresponding to the opening of each of the gas supply port 200 and the gas discharge port 210, and is mutually coupled to the opening.

Valves 204 and 214 are equipped with automatic or manual valves. In addition, the valves 204 and 214 may be provided, for example, as a jack valve, a ball valve, or the like. In the case of a jack valve, it may be provided as a shredder valve, a prestar valve or a dunlop valve.

The gas supply port 200 is automatically or manually opened when gas is supplied from the gas supply source 208 of FIG. 7, and the gas discharge port 210 is mixed with nitrogen (N2) gas and air from the internal space. When the mixed gas (N2 + Air) is discharged, it is automatically or manually opened, and when nitrogen (N2) gas is supplied to the internal space of the battery pack case 110 above a predetermined concentration level, it is automatically or manually shut off.

Specifically, a process of filling gas, for example, nitrogen gas, for oxidation and fire protection of the battery pack according to an embodiment of the present invention will be described with reference to FIG. 7.

Referring to FIG. 7, first, the battery pack 100 may include the upper case 112, the lower case 114, and the first to the first through the plurality of O-rings 190 and the first and second gaskets 194 and 196. Four sidewall cases 120 to 126 are coupled to each other to seal the internal space of the battery pack case 110. In this state, the caps 220 and 230 of the gas supply port 200 and the gas discharge port 210 are removed.

The gas supply pipe 202 connected to the gas supply source 208 supplying the nitrogen (N2) gas to the gas supply port 200 is mounted, and the gas discharge pipe 212 is connected to the gas discharge port 210. At this time, the valve 204 of the gas supply port 200 is automatically opened so that nitrogen (N2) gas is supplied into the battery pack 100, and at the same time, the valve 214 of the gas discharge port 210 is closed. Open automatically and the mixed gas (N2 + Air) is discharged to the gas discharge pipe (212).

The gas discharge pipe 212 is provided with a filter 218 for separating nitrogen (N2) gas and air (Air), and is connected to the gas supply source 208 through this. In addition, a concentration meter 216 is provided between the gas discharge pipe 212 and the filter 218. Therefore, the air separated through the filter 218 is discharged to the outside, the nitrogen (N2) gas is recovered to the gas supply source 208.

The concentration meter 218 measures the concentration of the mixed gas (N2 + Air) discharged to the gas discharge pipe 212. As a result of the measurement, when a concentration of nitrogen gas is detected, the valve 214 of the gas discharge port 210 is closed and the valve 204 of the gas supply port 200 is closed to complete gas filling.

As described above, the battery pack 100 of the present invention seals the internal space by using the plurality of sealing members 190 and the plurality of gaskets 194 and 196 in the battery pack case 110 coupled to each other, and the gas Nitrogen (N2) gas may be filled in the internal space at a predetermined concentration using the supply port 200 and the gas discharge port 210.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes and modifications may be made without departing from the spirit of the invention. Do.

100: battery pack 102: power input terminal
104: signal input terminal 110: battery pack case
112: upper case 114: lower case
120 to 126: side wall case 130 to 136: coupling portion
140: heat dissipation fin 150: fastening portion
160: battery cells 162, 164: terminals
166, 168, 182: thermoelectric sheet 170: separator
172: terminal fixing member 180: circuit board
190: O-ring 192: Insertion groove
194, 196: gasket 200: gas supply port
202: gas supply pipe 204, 214: valve
206: pump 208: gas supply
210: gas discharge port 212: gas discharge pipe
216 densitometer 218 filter

Claims (8)

In a battery pack,
A plurality of battery cells;
A battery pack case including an upper case, a lower case, and a plurality of sidewall cases to form an inner space for accommodating the battery cells;
A plurality of coupling portions formed at both ends of each of the side wall cases to be inclined and coupled to the both ends of adjacent side wall cases among the side wall cases;
A plurality of sealing members installed on the coupling surfaces of the coupling portions to seal the coupling surfaces between the adjacent sidewall cases;
The upper case and the upper surface of the combined sidewall cases, and the lower case and the lower surface of the combined sidewall cases, respectively, are installed between the upper case and the upper surface, and the lower case and the lower surface, respectively. A plurality of gaskets;
A battery pack, comprising: a gas supply port and a gas discharge port installed at one side of the battery pack case to fill oxidation and fire protection gas into the sealed inner space. The method of claim 1,
Each of the gas supply port and the gas discharge port;
An opening that is partially exposed at one side of the battery pack case;
A pipe inserted into the battery pack case and connected to the opening;
And a valve installed between the opening and the pipe to open and close according to gas supply and discharge. The method of claim 2,
The pipe is characterized in that the gas supply port and the gas discharge port is provided with a battery pack, characterized in that for supplying or discharging the gas at different positions of the internal space. The method according to any one of claims 1 to 3,
The coupling portion;
One end of one of the adjacent sidewall cases is obliquely extended, and the other end of the other one adjacent to the one extending inclined to form a coupling surface, the coupling surface is the one and the other And a 45 ° angle outward with respect to the XY coordinate system formed by the sidewall cases of the battery pack. The method of claim 4, wherein
The coupling portion;
The battery pack, characterized in that the insertion groove in which the sealing member is inserted in the longitudinal direction of the coupling surface is formed on any one of the adjacent side wall cases. The method of claim 5, wherein
The battery pack comprising:
A power input terminal provided at one side of the battery pack case to supply power for charging the battery cells;
A circuit board installed in the inner space and receiving power from the power input terminal to charge or balance and control the battery cells;
A signal input terminal provided at one side of the battery pack case to input signals for charging and discharging the battery cells to the circuit board;
A separating plate separating the internal space into a space for installing the circuit board and the battery cells, respectively;
Is installed on one side of the battery pack case opposite to the circuit board to transfer heat generated from the circuit board to one side of the battery pack case, or installed between the plurality of terminals formed on the battery cells and the upper case And a plurality of thermoelectric sheets configured to transfer heat generated from the terminals to the upper case and cushion vibrations and shocks applied from the outside of the upper case. The method according to claim 6,
Each of the gas supply port and the gas discharge port;
The pipe pack is installed so that the pipe is disposed between the circuit board and the separator. In the manufacturing method of the battery pack:
An upper case and a lower case and a plurality of sidewall cases are combined to seal the inner space of the battery pack case accommodating the plurality of battery cells in the inner space;
A gas supply port installed at one side of the battery pack case to supply oxidation and fire protection gas to the sealed inner space, and gas discharge for discharging a mixed gas of air and the oxidation and fire protection gas mixed in the inner space; Having a port;
Mounting a gas supply pipe connected to a gas supply source to the gas supply port to supply the oxidation and fire protection gas to the internal space, and simultaneously connect a gas discharge pipe to the gas discharge port to discharge the mixed gas; next
The concentration of the oxidation and fire protection gas in the internal space is measured using the discharged mixed gas, and when a concentration of a predetermined level or more is detected, the gas discharge pipe is separated from the gas discharge port, and the gas supply port is disconnected from the gas supply port. The method of manufacturing a battery pack, characterized in that to complete the filling of the oxidation and fire protection gas by separating the gas supply pipe.

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