KR102032169B1 - Energy storage device - Google Patents

Abstract

The present invention relates to an energy storage device having an earthquake-proof function and fuse function for fire prevention. More specifically, when an abnormal shape occurs in enclosure of the energy storage device due to deformation by earthquake and ground subsidence, an overcurrent flows through a metal plate in which a plurality of batteries are connected in series or short circuit occurs for various other reasons, thereby resulting in fire. The technique for easily disconnecting the metal plate is provided when the short circuit occurs.

Description

Energy storage device with seismic and fuse functions to prevent fires {ENERGY STORAGE DEVICE}

The present invention relates to an energy storage device in which a seismic function and a fuse function are installed to prevent fire. In detail, when an abnormal shape occurs in a housing of the energy storage device due to deformation or ground subsidence due to an earthquake, a plurality of batteries may be used. It provides a technology that makes it possible to easily disconnect a metal plate when an overcurrent flows or subsequently short-circuits (short circuits) for a variety of other reasons, leading to a fire.

In general, the energy storage device connects several batteries in series to accommodate them in the enclosure. If the enclosure is deformed by an earthquake or an abnormal shape occurs in the enclosure due to ground subsidence, the battery connection part becomes loose when the ground is loosened. An arc occurs and leads to a fire. In consideration of this case,

Energy Storage System (ESS: Energy Storage System) refers to a storage device that stores energy like a battery and can be used at any time. Since electric energy has a difference between production and storage, production in using electric energy The ESS is a system for storing and using energy efficiently, which allows for the production of energy.

Therefore, when the ESS is activated, energy produced at the dawn of relatively low energy consumption can be stored so that it can be effectively used when energy supply is concentrated, and the operation rate of energy production can be increased.

In addition, it is recognized as an important energy system that can solve the current electric power shortage because it can accumulate and regenerate small amounts of renewable energy.

Among them, the ESS demonstration project in Jeju Island is expected to solve the electricity shortage because it is proceeding with 8 megawatts which is equivalent to one substation.

Recently, energy production facilities such as wind power and solar power are rapidly increasing due to the expansion of renewable energy supply to secure energy at the national level.

Renewable energy is being actively researched in developed countries and other countries in that it is a key solution to the depletion of fossil energy and environmental problems. In particular, the photovoltaic power generation system that generates power by using solar energy among new renewable energy has been in the spotlight recently due to the advantages of no pollution and easy installation and maintenance.

There are two types of photovoltaic power generation systems such as a standalone power generation system that operates solely with a photovoltaic power generation system and a grid-connected power generation system that operates in conjunction with a photovoltaic power generation system and a commercial power system.

The converters and inverters that make up the photovoltaic power generation system are determined by the internal circuit elements according to the electric shock voltage or electric current set during system design. In this case, since capacity is fixed, a separate system must be constructed when capacity expansion is requested, which makes it difficult in terms of space and power consumption.

Among them, the Republic of Korea Patent No. 10-1084214 (system-associated power storage system and power storage system control method) has published a power storage system that can expand the capacity while improving the space and power consumption.

However, in the prior art, in most cases, the focus is on expanding capacity while improving power consumption.

If there is no technical function to prevent fire or monitor the situation because there is no disaster prevention function, the problem cannot be solved quickly and the fire cannot be prevented in advance.

Because of this, if a fire occurs there is a problem that the entire expensive energy storage device is burned out.

In addition, the configuration of the energy storage device, a plurality of trays are connected in series in the rack, a plurality of rechargeable batteries (batteries) are accommodated in the trays are connected between the rechargeable battery and the rechargeable battery in series by a metal plate.

Therefore, when a tray accommodated in an enclosure (called a rack) of an energy storage device due to an earthquake-deformation or ground subsidence is shaken, a plurality of batteries are also shaken. At this time, the connection circuit for connecting the battery to the battery becomes far from the terminals of the battery. In this case, a plurality of overlapping metal plates (see FIG. 4) are shaken to cause an arc, which causes a fire.

As can be seen in Figure 4 the plurality of metal plate, a plurality of

The batteries 20 are shaken in a state where they are connected to each other by the metal plate 2

In this case, the metal plate 2 has a configuration in which a plurality of thin iron plates are stacked so as to have elastic force.

Therefore, if it becomes loose, there is a probability of an arc between the metal plate and the metal plate. This technique is a prior art.

Therefore, when the metal plate becomes loose, an arc occurs, which causes the entire energy storage device to burn out.

In particular, since a plurality of metal plates are in close contact with each other (like one metal plate), when an overcurrent flows through the metal plates, they are not easily disconnected, causing a fire due to an overload.

In order to solve the above conventional problems,

In the present invention, at least one or two metal plates 2a of the plurality of metal plates 2 have a thinner metal plate thickness than the other plurality of metal plates.

As described above, when one or two metal plates 2a of the plurality of metal plates 2 are thinned, when the overcurrent flows, the thin metal plate 2a melts and disconnects first.

After that, the overcurrent is concentrated in the remaining plurality of metal plates.

It is intended to provide a technique in which the remaining plurality of metal plates 2b are continuously disconnected or simultaneously disconnected.

The above problems are further found in the detailed description.

Looking at the configuration by the accompanying drawings,

A commercial power and an inverter for converting the commercial power into a DC power output to the energy storage device or the DC power of the energy storage device is imported into the AC power by converting the AC power into a commercial power.

Looking further at the configuration of the energy storage device (corresponding to Protection 1), a plurality of trays 1 are connected in series to a rack (container), and a plurality of batteries (batteries) are accommodated in the tray 1 in series. It is in a wired or parallel configuration.

One side of the plurality of metal plates 2 having a plurality of metal plates superimposed on the terminals 21 of the battery 20 accommodated in the tray 1 is connected, and the other side of the plurality of metal plates 2 having the plurality of metal plates superimposed thereon is provided with the plurality of metal plates 2. To the terminal 21a of the second battery 20a to which the metal plate 2 of the
In the configuration to be connected

The plurality of metal plates 2 are spaced apart from each other by a plurality of metal plates 2 overlapping a plurality of metal plates to facilitate disconnection when an overcurrent flows through the plurality of metal plates 2;

At least one or two metal plates 2a in the plurality of overlapping metal plates 2 form a thinner metal plate thickness when compared to the remaining plurality of metal plates 2b.
When the overcurrent flows, the thin metal plate 2a with the thin metal plate melts and melts first, and then the remaining metal plates 2b melt and break.

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As explained earlier,

In the present invention, at least one or two metal plates 2a of the plurality of metal plates 2 have a thinner metal plate thickness than the other plurality of metal plates.

As described above, when one or two metal plates 2a of the plurality of metal plates 2 are thinned, when the overcurrent flows, the thin metal plate 2a melts and disconnects first.

After that, the overcurrent is concentrated in the remaining plurality of metal plates.

The remaining plurality of metal plates 2b are continuously disconnected or simultaneously disconnected.

By configuring in this way, the energy storage device can be protected from fire.

The above effects are further found in the detailed description.

1 is a perspective view of an energy storage device equipped with a seismic function to prevent fire,
2 is an exploded perspective view of the main part in FIG.
3 is a perspective view of a state in which a battery is removed from a rack as a perspective view of an energy storage device in which a seismic function is installed to prevent fire;
4 is an explanatory diagram of another embodiment of the present invention.

Looking at the configuration by the accompanying drawings,

A commercial power and an inverter for converting the commercial power into a DC power output to the energy storage device or the DC power of the energy storage device is imported into the AC power by converting the AC power into a commercial power.

Looking further at the configuration of the energy storage device (corresponding to Protection 1), a plurality of trays 1 are connected in series to a rack (container), and a plurality of batteries (batteries) are accommodated in the tray 1 in series. It is in a wired or parallel configuration.

One side of the plurality of metal plates 2 superimposed on the terminals 21 of the battery 20 accommodated in the tray 1 is connected, and the other side of the plurality of metal plates 2 is connected to the one side of the plurality of metal plates 2.

To the terminal 21a of the second battery 20a connected in series with a plurality of metal plates 2

In the configuration to be connected

The plurality of metal plates 2 are spaced apart from each other by a predetermined distance to facilitate disconnection when overcurrent flows through the plurality of metal plates 2,

At least one or two metal plates 2a of the plurality of metal plates 2 are formed to have a thinner metal plate thickness when compared to the remaining plurality of metal plates 2b.

An embodiment of the above configuration will be described below.

As described above, the plurality of metal plates 2 are spaced apart from each other to facilitate disconnection when overcurrent flows through the plurality of metal plates 2.

Thus, when an overcurrent flows in the space | interval circuit 2c which mutually spaced apart the some metal plate 2, and the conventional closely-contacted circuit (state where several metal plates contacted each other) in close contact with each other,

Among the plurality of metal plates 2 corresponding to the separation circuit 2c of the present invention, there is a high probability that one weak metal plate is melted and disconnected.

In this case, when the overcurrent flows to the weak metal plate among the plurality of metal plates 2, the wire is disconnected first and then the overcurrent is concentrated to the remaining plurality of metal plates.

There is a high possibility that the remaining plurality of metal plates are continuously disconnected or simultaneously disconnected.

The plurality of metal plates are made of aluminum and serve as a fuse.

As described above, at least one or two metal plates 2a of the plurality of metal plates 2 have a thinner metal plate thickness than the other plurality of metal plates.

As described above, by thinning one or two metal plates 2a among the plurality of metal plates 2,

When overcurrent flows, the thin metal plate 2a melts first and is disconnected.

After that, the overcurrent is concentrated in the remaining plurality of metal plates.

The remaining plurality of metal plates 2b are continuously disconnected or simultaneously disconnected.

As described above, the role of inducing a disconnection when overcurrent flows is thin.

By using the metal plate (2a) it is possible to prevent a fire that may occur due to overcurrent.

As a result, when an abnormal shape occurs in the enclosure of the energy storage device due to ground subsidence and an overcurrent flows through the plurality of metal plates 2, the metal plate 2a is disconnected and then the rest

Since the plurality of metal plates 2b are disconnected, the energy storage device 1 is thereby protected from fire.

 One side of the pressing member 40 is fixed to the terminal 21 by the fixing portion 41, and the other side of the pressing member 40 is composed of an elastic portion 42 for pressing the planes of the plurality of metal plates 2. .

Looking at an embodiment of such a configuration as follows.

Since one side of the pressing member 40 is fixed to the terminal 21 and the other side is configured to press the planes of the plurality of metal plates 2, for example, the battery 20 is shaken due to an earthquake, and the pressing connected to the terminal 21. Even if the member 40 becomes loose, the elastic part 42 presses on the plurality of metal plates 2, so that the arc is unlikely to occur, thereby preventing fire.

In addition, when the battery 20 is shaken, the plurality of metal plates 2 may be loosened, and an arc may occur. In this case, the elastic part 42 is pressed, and thus the plurality of metal plates 2

It does not shake with each other, which reduces the probability of arcing.

The configuration is as follows.

A hole 60 is formed in the terminal 20 of the battery 20 to form a locking portion 61 inside the hole.

In the fixing part 41 to form a locking jaw 43 to be caught by the locking portion 61

When the fixing portion 41 of the pressing member 40 is locked to the locking portion 61

The elastic portion 42 is configured to press the planes of the plurality of metal plates 2.

Looking at an embodiment of the configuration as follows.

In view of the configuration and drawings, the engaging portion 61 is formed inside the hole 60 and the fixing portion 61

By forming the locking jaw 43, the pressing member 40 only by inserting the fixing portion 61 into the hole 60.

Has an effect of being fixed to the terminal 21.

Therefore, the pressing member installation time is greatly shortened.

Here, for reference, dozens of trays are accommodated in the rack and dozens of rechargeable batteries are accommodated in the dozens of trays.

These dozens of batteries are connected by a metal plate (2), so if an arc occurs in any one of the metal plate (2), hundreds of batteries inside the rack is burned out to prevent this.

As a prevention method, the method using the pressing member 40 mentioned in the present invention may be called an inexpensive method including productivity and workability.

In other words, it is a very advantageous invention because it has a large effect in a simple way.

1: tray 2: metal plate
2c: separation circuit 20: battery
20a: second battery 21: terminal
40: pressure member 41: fixed part
42: elastic portion 43: locking jaw
60: hole 61: locking portion

Claims (2)

One side of the plurality of metal plates 2 in which a plurality of metal plates are superimposed on the terminals 21 of the battery 20 accommodated in the tray 1 is connected, and the other side of the plurality of metal plates 2 in which the metal plates are overlapped a plurality of the plurality of metal plates 2. To the terminal 21a of the second battery 20a to which the metal plate 2 is connected in series.
In the configuration to be connected

The plurality of metal plates 2 are spaced apart from each other by a plurality of metal plates 2 overlapping a plurality of metal plates to facilitate disconnection when an overcurrent flows through the plurality of metal plates 2;

At least one or two metal plates 2a in the plurality of overlapping metal plates 2 form a thinner metal plate thickness when compared to the remaining plurality of metal plates 2b.
When the overcurrent flows, the seismic function and the fuse function are installed to prevent fire, which is characterized in that the thin metal plate 2a is melted and disconnected first, and then the remaining plurality of metal plates 2b are melted and disconnected. Energy storage devices.
The method of claim 1
One side of the pressing member 40 is fixed to the terminal 21 by the fixing portion 41, and the other side of the pressing member 40 is formed of an elastic portion 42 for pressing the planes of the plurality of metal plates 2. Energy storage device with seismic function and fuse function to prevent fire.

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