KR101984817B1 - Automatic fire extinguishing systems for energy storage systems - Google Patents

Abstract

The present invention relates to an automatic fire extinguishing system for an energy storage system, and more particularly, it relates to an automatic fire extinguishing system for an energy storage system, in which a fire generated in one or both of a battery module, a case, and a battery management system of a battery tray, It can evolve within a short period of time and prevent large-scale accidents and environmental pollution caused by fire.

Description

[0001] Automatic fire extinguishing systems for energy storage systems [0002]

The present invention relates to a battery management system, a battery management system, and a battery management system of a battery tray provided in an energy storage system, To an automatic fire extinguishing system for an energy storage system capable of preventing environmental pollution.

An energy storage system (ESS) is an external power source, for example, a device that receives and stores external power from a power plant, and transmits the power to a required place at a required time.

That is, the energy storage system is a high-capacity power storage device including a battery for storing electric power, and it is a storage device that can save power and use it at necessary place and time. As a result, it is now regarded as a new and renewable energy storage device.

However, since the batteries of the energy storage system are concentratedly connected to each other, when deterioration or heat generation occurs in the battery and the battery management system (BMS) When a fire occurs due to a contact failure, there is a problem that can occur due to a large accident.

In order to solve such a problem, a fire extinguishing system for an energy storage system that automatically extinguishes an energy storage system including one or more batteries or a container for transporting a plurality of batteries connected to each other, and the fire extinguishing system control method are disclosed in Korean Patent Laid- No. 10-2015-0077006.

However, in the case of Korean Patent Laid-Open Publication No. 10-2015-0077006, as the power of the battery is applied to the fire extinguishing device, the fire extinguishing device is operated to evolve the fire, There is a problem that the fire can not be evolved.

In the above-mentioned Korean Patent Laid-Open Publication No. 10-2015-0077006

In order to solve the above-described problems, the present invention provides a battery management system, a battery management system, a battery management system, and a battery management method of a battery tray provided in an energy storage system, And it is an object of the present invention to provide an automatic fire extinguishing system for an energy storage system capable of preventing large-scale accidents and environmental pollution caused by a fire.

According to an aspect of the present invention, there is provided an energy storage system having a battery tray including a battery module, a case accommodating the battery module, and a battery management system (BMS) Wherein the battery management system includes a battery management module for managing the battery, the case, the battery management system, and the battery management system, A fire evolving line for evolving a fire generated in at least one of the BMSs; And a carbon dioxide supplying unit configured to supply carbon dioxide to the inside of the fire evacuation line. The present invention relates to an automatic fire extinguishing system for an energy storage system.

Here, it is preferable that the fire evolution line of the carbon dioxide supply unit injects carbon dioxide to both the battery module, the case, and the battery management system (BMS).

The fire evolution line may include a connection line connected to the carbon dioxide supply member; And a carbon dioxide injection line connected to the connection line.

Alternatively, the fire evolution line may include a plurality of branch lines formed between the connection line and the carbon dioxide injection line, and the carbon dioxide injection line may be connected to each of the plurality of branch lines.

The entire carbon dioxide injection line is preferably made of a combustible material having a low melting point.

Alternatively, the entire carbon dioxide injection line is made of a nonflammable material, and the carbon dioxide injection line made of a nonflammable material has injection holes formed at regular intervals, and a flammable material finishing member having a low melting point for closing the injection holes in the injection hole Respectively.

Alternatively, the entire carbon dioxide injection line is made of an incombustible material, and a jet hole is formed at a predetermined interval in the carbon dioxide injection line made of a noncombustible material. The carbon dioxide injection line has a melting point It is preferable to provide a low-combustibility closure member.

Alternatively, the entire carbon dioxide injection line may be made of an incombustible material, and the carbon dioxide injection lines may be divided into a plurality of carbon dioxide injection lines, and one of the carbon dioxide injection lines may be disposed between any one of the carbon dioxide injection lines and the other carbon dioxide injection line. And a connecting member made of an incombustible material for connecting the injection line and the other carbon dioxide injection line, wherein the connecting member is provided with a jetting hole, and a flammable material having a low melting point for closing the jetting hole in the jetting hole of the connecting member Respectively, are preferably provided.

Alternatively, the entire carbon dioxide injection line may be made of a noncombustible material, the carbon dioxide injection line made of a noncombustible material may be provided with a closure member made of bimetal, and a pin member projecting to the carbon dioxide injection line may be provided on the inner surface of the closure member, Is formed.

The present invention relates to a method of controlling an energy storage system, which is provided in a battery tray, a case, and a battery management system of a battery tray provided in an energy storage system through carbon dioxide supplied by the carbon dioxide supply unit in a non- The fire can be evolved in a short period of time, thereby preventing a large-scale accident caused by a fire and environmental pollution.

1 is a front view schematically showing an automatic fire extinguishing system for an energy storage system according to an embodiment of the present invention,
2 is a partially enlarged front view schematically showing a first example of a fire evolution line,
3 is a front view schematically showing a second example of the fire evolution line,
Fig. 4 is a cross-sectional view schematically showing an example of a closure member taken along the line A-A in Fig. 3,
Fig. 5 is a cross-sectional view schematically showing another example of the closure member,
6 and 7 are sectional views schematically showing still another example of the closing member,
8 is a front view schematically showing a third example of the fire evolution line,
9 is an exploded cross-sectional view taken along the line B-B in Fig. 8,
Fig. 10 is an assembled cross-sectional view of Fig. 9,
11 is a front view schematically showing a fourth example of the fire evolution line.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. It is to be understood that the scope of the present invention is not limited to the following embodiments, and various modifications may be made by those skilled in the art without departing from the technical scope of the present invention.

1 is a front view schematically showing an automatic fire extinguishing system for an energy storage system according to an embodiment of the present invention.

1, the automatic fire extinguishing system for an energy storage system according to an embodiment of the present invention includes a battery module 100, a case 110 for housing the battery module 100, And a battery management system (BMS) 120. The battery management system (BMS) 120 includes a battery tray (not shown).

The battery module 100, the case 110, and the battery management system (BMS) 120 are well known in the Korean Patent Laid-Open Publication No. 10-2016-0028205. do.

Particularly, a fire may be generated in the battery tray due to a contact failure of the battery management system (BMS) 120. In order to quickly evolve the generated fire, the battery module 100, the case 110 ), A fire evolution line (210) for injecting carbon dioxide into at least one of the battery management system (BMS) (120) to evolve a fire generated in one or more of the battery module, the case and the battery management system )and; And a carbon dioxide supply unit 220 including a carbon dioxide supply member 220 for supplying carbon dioxide to the inside of the fire evolution line 210.

1, the carbon dioxide supplying unit 20 may be installed inside the case 110, and the carbon dioxide supplying member 220 may be formed of various types such as a carbon dioxide gas cylinder in which high-pressure carbon dioxide is compressed and stored.

The fire evolution line 210 may be disposed around the battery module 100, the case 110, and the battery management system (BMS), respectively.

2 is a partially enlarged front view schematically showing a first example of a fire evolution line;

As shown in FIG. 2, the fire evolution line 210 may include a connection line 211 and a carbon dioxide injection line 212.

The connection line 211 may be made of a non-combustible material such as a metal pipe pipe.

One side of the connection line 211 may be hermetically connected to the upper portion of the carbon dioxide supply member 220.

One side of one carbon dioxide injection line 212 may be hermetically connected and fixed to the other side of the connection line 211.

The other side of the carbon dioxide injection line 212 of the first example can be closed.

The entire carbon dioxide injection line 212 of the first example may be made of a combustible material such as plastic having a low melting point.

The portion of the carbon dioxide injection line 212 of the first example adjacent to the ignition point of the battery module 100, the case 110 and the battery management system (BMS) 120 can be melted and melted, Carbon dioxide is injected from the melted portion of the line 212 to the ignition point of the battery module 100, the case 110 and the battery management system (BMS) 120 to evolve the ignition point.

3 is a front view schematically showing a second example of the fire evolution line.

The fire evolving line 210 of the second example is composed of the connection line 211 and the carbon dioxide injection line 212. The entire carbon dioxide injection line 212 of the second example may be made of a noncombustible material.

The carbon dioxide injection line 212 of the second example which can be made of a noncombustible material is provided with the battery module 100, the case 110, the battery management system (BMS) 120, And a spray hole 213 for injecting carbon dioxide into the case 110 and the BMS 120 may be formed at regular intervals.

Fig. 4 is a cross-sectional view schematically showing an example of a closure member taken along the line A-A in Fig. 3;

As shown in FIG. 4, an example of a flammable material, which is made of plastic having a low melting point and closes the injection hole 213, may be adhered to the injection hole 213 in a variety of ways .

The closure member 214 in the injection hole 213 melts and melts due to the high-temperature flame of the fire generated in the battery module 100, the case 110 and the battery management system (BMS) The case 110 and the battery management system BMS 120 in which a fire has been generated through the opened spray hole 213 can be opened and the carbon dioxide So that the fire can be suppressed.

5 is a cross-sectional view schematically showing another example of the closing member.

5, the closure member 214 may surround the outer surface of the carbon dioxide injection line 212 in the vicinity of the injection hole 213, so that the carbon dioxide injection line 212 around the injection hole 213, And may be formed in an annular shape or the like so as to be closely attached to the outer surface of the base 212.

Figs. 6 and 7 are sectional views schematically showing still another example of the closing member. Fig.

As another example, the carbon dioxide injection line 212 made of a non-combustible material may be provided with a plurality of closure members 214, which may be formed in various shapes such as an annular shape made of bimetal, have.

The bimetal, which can form the closure member 214, has a property of bending when heat is applied. On the inner surface of the closure member 214, which may be formed of the bimetal, the bimetal protrudes toward the outer surface of the carbon dioxide injection line 212 A plurality of pin members 217 may be formed at regular intervals.

A bimetal capable of forming the closure member 214 due to the high temperature sparks generated in the battery module 100, the case 110 and the BMS 120 is supplied to the carbon dioxide injection line 212 7, the pin member 217 pierces into the inside of the carbon dioxide injection line 212, so that the carbon dioxide injection line 212 is pressed against the carbon dioxide injection line 212. As a result, As the line 212 ruptures, the carbon dioxide filled in the carbon dioxide injection line 212 is leaked to the outside of the carbon dioxide injection line 212 to suppress the fire.

It is possible to suppress the fire more easily even if the carbon dioxide injection line 212 does not melt due to the fire through the closure member 214 made of another bimetal.

8 is a front view schematically showing a third example of the fire evolution line.

The fire evolving line 210 of the third example includes the connection line 211 and the carbon dioxide injection line 212. The entire carbon dioxide injection line 212 of the third example may also be made of a nonflammable material.

Particularly, in order to reuse the carbon dioxide injection line 212 of the third example, the carbon dioxide injection line 212 made of a nonflammable material is distributed to a plurality of carbon dioxide injection lines 212, The connection member 215 may be provided between the carbon dioxide injection line 212 and one of the carbon dioxide injection lines 212 as shown in FIG.

FIG. 9 is an exploded sectional view taken along the line B-B of FIG. 8, and FIG. 10 is a coupled sectional view of FIG.

9 and 10, the connection member 215 may be formed with the injection hole 213 and the injection hole 213 may be formed of a flammable material having a low melting point And the closure member 214 may be respectively provided.

One side of the connecting member 215 may be detachably screwed to the other side of any one of the carbon dioxide injection lines 212 so that the connecting member 215 and the carbon dioxide injection line 212 are communicated with each other, The other side of the member 215 may be releasably screwed to one side of the other carbon dioxide injection line 212.

11 is a front view schematically showing a fourth example of the fire evolution line.

The fire evolution line 210 of the fourth example may include the connection line 211, the carbon dioxide injection line 212, and the plurality of branch lines 216 as shown in FIG.

The branch line 216 may be formed between the connection line 211 and the carbon dioxide injection line 212.

The branch line 216 may include a main branch line 216a and a plurality of auxiliary branch lines 216b.

One side of the main branch line 216a may be hermetically connected and fixed to the other side of the connection line 211.

One side of the plurality of auxiliary branch lines 216a may be hermetically connected to the other side of the main branch line 216a at regular intervals.

And may be hermetically connected and fixed to one side of the carbon dioxide injection line 212 of the first to third examples on the other side of the plurality of auxiliary branch lines 216a of the branch line 216. [

One of the auxiliary branch lines 216b may be formed in the main branch line 216a, but preferably the carbon dioxide injection line 212 is formed in any one of the battery module 100, the case 110 The case 110 and the battery management system BMS 120 without injecting carbon dioxide into any one of the battery management system BMS 120 and the battery management system BMS 120, The main branch line 216a may be formed with a plurality of the auxiliary branch lines 216b at regular intervals in order to inject carbon dioxide into the main branch line 216a.

The present invention configured as described above can be applied to the battery module 100 of the battery tray provided in the energy storage system through the carbon dioxide supplied from the carbon dioxide supply unit 20 in a non-power source manner without the power supply to the carbon dioxide supply unit 20, The fire generated in any one or both of the case 110 and the battery management system 120 can be evolved in a short period of time to prevent a large accident caused by a fire and environmental pollution.

100; Battery module, 110; case,
120; Battery management system, 20; Carbon dioxide supply.

Claims (9)

A battery tray including a battery module, a case for accommodating the battery module, and a battery management system (BMS) for inserting the case, and an automatic energy storage system for evolving a fire generated in the energy storage system. As an extinguishing device,
A carbon dioxide injection line for injecting carbon dioxide filled in the inside of at least one of the battery module, the case and the battery management system (BMS), and the other end of the carbon dioxide injection line is connected to a connection line Wherein carbon dioxide is injected into the ignition point of the battery module, the case, and the battery management system (BMS) while melting the melted and melted portion of the carbon dioxide injection line adjacent to the ignition point to evolve the fire A fire evolution line in which the entire carbon dioxide injection line is made of a combustible material having a low melting point;
And a carbon dioxide supplying unit including a carbon dioxide supplying member in which high pressure carbon dioxide is compressed and stored so that one side of the connecting line is connected and fixed, and the carbon dioxide is supplied to the inside of the fire evacuation line in a non- Automatic fire extinguishing system for energy storage system.
A battery tray including a battery module, a case for accommodating the battery module, and a battery management system (BMS) for inserting the case, and an automatic energy storage system for evolving a fire generated in the energy storage system. As an extinguishing device,
A carbon dioxide injection line for injecting carbon dioxide filled in the inside of at least one of the battery module, the case and the battery management system (BMS), and the other end of the carbon dioxide injection line is connected to a connection line Wherein the entire carbon dioxide injection line is made of an incombustible material and includes a fire evacuation line in which a jet hole is formed at a predetermined interval in the carbon dioxide injection line made of a noncombustible material;
A carbon dioxide supply part including a carbon dioxide supply part which is connected and fixed to one side of the connection line and is compressed and stored at a high pressure so as to supply carbon dioxide to the inside of the fire evolution line in a non-power source mode without a separate power source;
And is made of a combustible material having a low melting point, and is melted and melted by a high-temperature flame, and is sprayed on the carbon dioxide spraying line made of a non-combustible material, And a closure member for spraying carbon dioxide onto the ignition point of the battery module, the case, and the battery management system (BMS) through the open and opened spray hole to evolve the fire. Automatic fire extinguishing system for energy storage system.
A battery tray including a battery module, a case for accommodating the battery module, and a battery management system (BMS) for inserting the case, and an automatic energy storage system for evolving a fire generated in the energy storage system. As an extinguishing device,
A carbon dioxide injection line for injecting carbon dioxide filled in the inside of at least one of the battery module, the case and the battery management system (BMS), and the other end of the carbon dioxide injection line is connected to a connection line Wherein the entire carbon dioxide injection line is made of an incombustible material and includes a fire evacuation line in which a jet hole is formed at a predetermined interval in the carbon dioxide injection line made of a noncombustible material;
A carbon dioxide supply unit connected to one side of the connection line and configured to supply carbon dioxide to the inside of the fire evacuation line in a non-power source mode without a separate power source;
And is made of a combustible material having a low melting point and is provided on the outer surface of the carbon dioxide spraying line around the spray hole formed at a predetermined interval in the carbon dioxide spraying line made of an incombustible material to close the spray hole, The battery and the battery management system (BMS) through the opening of the spray hole to open the spray hole and spray the carbon dioxide to the ignition point of the battery module, the case, and the battery management system (BMS) And an automatic fire extinguishing system for an energy storage system.
A battery tray including a battery module, a case for accommodating the battery module, and a battery management system (BMS) for inserting the case, and an automatic energy storage system for evolving a fire generated in the energy storage system. As an extinguishing device,
A carbon dioxide injection line for injecting carbon dioxide filled in the inside of at least one of the battery module, the case and the battery management system (BMS), and the other end of the carbon dioxide injection line is connected to a connection line Wherein the entire carbon dioxide injection line is made of a nonflammable material and the carbon dioxide injection line made of a nonflammable material is distributed to a plurality of the carbon dioxide injection lines and the carbon dioxide injection line is arranged between any one of the carbon dioxide injection lines and the other carbon dioxide injection line A fire evacuation line having a connecting member made of an incombustible material connecting one of the carbon dioxide spray lines and the other carbon dioxide spray line and having a spray hole formed in the connecting member;
A carbon dioxide supply unit connected to one side of the connection line and configured to supply carbon dioxide to the inside of the fire evacuation line in a non-power source mode without a separate power source;
And is made of a combustible material having a low melting point, and is melted and melted by a high-temperature flame to open the spray hole, And a closure member for spraying carbon dioxide onto the ignition point of the battery module, the case, and the battery management system (BMS) Device.
A battery tray including a battery module, a case for accommodating the battery module, and a battery management system (BMS) for inserting the case, and an automatic energy storage system for evolving a fire generated in the energy storage system. As an extinguishing device,
A carbon dioxide injection line for injecting carbon dioxide filled in the inside of at least one of the battery module, the case and the battery management system (BMS), and the other end of the carbon dioxide injection line is connected to a connection line The entire carbon dioxide injection line including a fire evolution line made of a non-combustible material;
A carbon dioxide supply unit connected to one side of the connection line and configured to supply carbon dioxide to the inside of the fire evacuation line in a non-power source mode without a separate power source;
Wherein the bimetal is bent in the direction of the outer surface of the carbon dioxide injection line by the high temperature flame, and the bimetal is formed on the inner surface of the carbon dioxide injection line, The carbon dioxide injection line is filled with carbon dioxide which is injected into the battery module, the case, and the battery management system (hereinafter, referred to as " the carbon dioxide injection line ") when the carbon dioxide injection line is gradually pressurized, Wherein the fire extinguishing agent is sprayed to one or more ignition points of the fire extinguisher and the BMS to suppress the fire.
The method according to claim 1,
Wherein the fire evolution line of the carbon dioxide supply unit injects carbon dioxide into both the battery module, the case, and the BMS.
The method according to claim 1,
Wherein the fire evolution line includes a plurality of branch lines formed between the connection line and the carbon dioxide injection line,
Wherein the carbon dioxide injection line is connected to each of the plurality of branch lines. delete delete

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