JPH06104007A - Disaster prevention device in sodium-sulfur battery - Google Patents

Abstract

PURPOSE:To prevent extension of abnormal condition by preventing a corrosive gas or fire caused by abnormality generated in a battery module, from being passed on to other normal battery modules. CONSTITUTION:A plurality of cells 5 of sodium-sulfur battery are stored in a module main body 3, to form a battery module 2. A plurality of battery modules 2 are stored in a storage case l. A connection piping 8 is mounted on the storage case 1, and a gas purifier 7 for purifying gas, which is provided with an exhaust fan 6, is connected to the connection piping 8. An exhaust pipe 9 is mounted on the battery module 2, and the exhaust pipe 9 is connected to the connection piping 8 through a connection piping 10. A check valve 11 serving as a back flow prevention means, is provided on the exhaust pipe 9. A gas detection sensor can be mounted in the battery module 2, to operate an automatic valve provided on the exhaust pipe 9.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention prevents an abnormal state from spreading to other normal battery modules when an abnormality such as a fire occurs in a battery module containing a sodium-sulfur battery cell. The present invention relates to a disaster prevention device for a sodium-sulfur battery.

[0002]

2. Description of the Related Art In sodium-sulfur batteries, active materials such as sodium and sulfur are heated and melted at about 300 ° C., and sodium ions permeate through a β-alumina solid electrolyte tube to react with sulfur. Predetermined electric energy can be obtained. This sodium-sulfur battery is rarely used as a single unit, that is, as a single battery, and is used as a battery module in which a plurality of serially connected battery groups are connected in parallel and housed in a heat insulating container. .

In order to use this battery module for storing electric power, a large number of battery modules are further lined up and stacked and stored in a storage case. When this power equipment is operating normally, there is only electrochemical heat absorption and heat generation due to charging and discharging and heat generation from the circuit resistance, no exhaust gas is generated, and the inside of the storage case is in operation. Only air conditioning is provided to maintain the proper temperature.

[0004]

However, the number of unit cells used in this electric power equipment reaches tens of thousands. And
In a long-term operation, a solid electrolyte tube that separates sodium and sulfur, a cathode container that seals sodium,
Alternatively, cracks may occur in the anode container that seals the sulfur. In this case, sodium and sulfur leaked from the solid electrolyte tube start an abnormal reaction, or the active material leaks from the cathode container or the anode container, and the leaked active material is easily oxidized in a high temperature state, and sulfur dioxide (SO ₂ ) And other corrosive gases may be generated.

Although the corrosive gas does not increase the internal pressure of the battery module to the extent that the latter active material leaks, it still leaks from the battery module within a long time and stays in the same storage case. It may damage the battery parts of the battery module. Also, when a fire occurs in the battery module due to an abnormal reaction as in the former case, the flame leaks to the outside through the gap of the lid of the heat insulation container that constitutes the battery module and is wired around the battery module. There is a problem that the charging / discharging cable and the measuring cable may be burned out.

The present invention has been made by paying attention to the above-mentioned conventional problems, and its purpose is to:
Even if a corrosive gas or a fire occurs due to an abnormality in the battery module, the gas or flame does not transfer to other normal battery modules, and a disaster prevention device for sodium-sulfur batteries that can prevent the spread of abnormal states is provided. To do.

[0007]

In order to achieve the above object, in the first invention, a large number of sodium-sulfur battery cells are housed in a module body to form a battery module, and the battery module is housed. A plurality of batteries are stored in a case, a connection pipe is attached to the storage case, a gas purification device for purifying gas is connected to the connection pipe, an exhaust pipe is attached to the battery module, and the exhaust pipe is connected to the connection pipe. It is characterized in that it is connected to a pipe and a backflow prevention means is provided in the exhaust pipe.

Further, in the second aspect of the present invention, ventilation means is provided in each of the exhaust pipes, and a gas detection sensor is attached to each battery module so that an abnormality occurs in any of the battery modules and corrosive gas is generated in the battery module. When a gas is generated, the gas detection sensor detects this corrosive gas and activates the exhaust pipe ventilation prevention means and the gas purification device attached to a normal battery module other than that battery module, and the battery module in which the abnormality occurs It is characterized in that the contaminated air inside and inside the storage case is purified to prevent an abnormal state from spreading to a normal battery module.

[0009]

In the disaster prevention device of the present invention, since the exhaust pipe is attached to the battery module and the exhaust pipe is connected to the connecting pipe connected to the gas purifying device, a fire occurs in the battery module and a flame or Even if a high-temperature reaction product gas is generated, it flows out from the exhaust pipe to the gas purifying device through the connecting pipe without leaking out through the gap of the battery module. Further, since each exhaust pipe is provided with the backflow prevention means, even if an abnormality occurs in one battery module, the backflow prevention means prevents corrosive gas from entering another normal battery module. It is possible to prevent the spread of abnormal conditions.

Further, according to the present invention, a gas detection sensor is attached to the battery module, the gas detection sensor detects a corrosive gas, and the exhaust pipe of a normal battery module other than the battery module whose gas is detected by the detection signal from the sensor. It is arranged to activate the ventilation means. for that reason,
Even if an abnormality occurs in one battery module and a corrosive gas is generated in the battery module and the gas reaches the gas purification device, the non-polluting air in the normal battery module connected by piping is sucked. Is prevented.

[0011]

【Example】

(First Embodiment) A first embodiment of a disaster prevention device for a sodium-sulfur battery embodying the present invention will be described below in detail with reference to the drawings.

As shown in FIG. 2, a plurality of battery modules 2 are vertically and horizontally arranged in a rectangular box-shaped storage case 1, and are vertically stacked. As shown in FIG. 1, the battery module 2 is hermetically formed by a module body 3 and a lid 4 which are formed in a rectangular box shape by a heat insulating material, and a large number of single cells 5 of sodium-sulfur battery are provided therein. It is housed. And the battery module 2
The spaces are connected by electrical wiring (not shown).

A gas purifying device 7 equipped with an exhaust fan 6 is connected to the storage case 1 by a connecting pipe 8, and a gas such as sulfur dioxide (SO ₂ ) in the storage case 1 is sucked into the suction port 8a.
Aspirate and purify. That is, the gas purification device 7
A sodium hydroxide aqueous solution is filled in the inside, and the corrosive gas is absorbed and removed by passing through the sodium hydroxide aqueous solution. Then, the gas after the purification treatment is released into the atmosphere to prevent pollution of the atmosphere.

The exhaust pipe 9 has one end attached to each battery module 2 and the other end attached to the connecting pipe 10. The connecting pipe 10 is connected to the connecting pipe 8 so that the gas from each exhaust pipe 9 is guided to the connecting pipe 8. Since it is unlikely that a plurality of battery modules 2 will cause an abnormal accident at the same time, this connecting pipe 10 is shared and the storage case 1
The number of internal pipes is reduced to secure a space for housing the battery module 2.

A check valve 11 as a backflow preventing means is attached to each exhaust pipe 9, and an abnormality occurs in any of the battery modules 2 to generate a corrosive gas, which gas is connected to the connecting pipe 10.
When it reaches another exhaust pipe 9 through the above, the flow is stopped so that the corrosive gas does not flow into the normal battery module 2. Then, the normal battery module 2 is protected from contamination by corrosive gas. In addition, when the internal pressure of the exhaust pipe 9 rises due to a fire or an abnormal reaction in the battery module 2, the pressure is quickly released, and neither flame nor high temperature reaction product gas is ejected from the battery module 2 into the storage case 1. Therefore, the check valve 11 is always open from the battery module 2 to the connecting pipe 10 side.

In any of the plurality of battery modules 2, if the solid electrolyte tube inside the unit cell 5 is damaged for some reason, the molten metal sodium, which is the active material of the anode and the cathode, comes into direct contact with sulfur. Then, a sudden chemical reaction causes a fire accident, which causes a corrosive gas such as sulfur dioxide or a flame.

These corrosive gases and flames flow into the connecting pipe 8 from the exhaust pipe 9 through the connecting pipe 10 due to their pressure and the suction action of the exhaust fan 6. Further, the corrosive gas leaked from the gap between the module body 3 and the lid 4 diffuses in the storage case 1 and flows into the connection pipe 8 from the suction port 8a. Then, this gas is purified by the gas purifying device 7 and exhausted to the atmosphere.

At this time, the check valve 11 attached to the exhaust pipe 9 of the normal battery module 2 other than the abnormal battery module 2 is cut off because the pressure on the connecting pipe 10 side rises and corrodes. The inflow of the volatile gas into the other battery module 2 is prevented. Therefore, even if an abnormality occurs in one battery module 2 and a corrosive gas or a flame is generated, the gas or flame does not transfer to another normal battery module 2, so that an abnormal state of the normal battery module 2 is detected. It is possible to reliably prevent the spread.

As described above, the corrosive gas and flame in the battery module 2 are exhausted from the exhaust pipe 9, the connecting pipe 10 to the connecting pipe 8.
Since the gas in the storage case 1 is guided to the connection pipe 8 from the suction port 8a, there is no risk of corroding or burning the power supply cable or the sensor cable. (Second Embodiment) Next, a second embodiment of the present invention will be described.

As shown in FIG. 3, in this embodiment, the gas sensor 22 is attached to the inner surface of the upper portion of each battery module 2, and the exhaust pipe 9 is ventilated from the check valve 11 to the connecting pipe 10 side. An automatic valve 23 as a means is attached. The gas sensor 22 detects when any one of the cells 5 in the battery module 2 is abnormal and corrosive gas is generated, and detects the corrosive gas to detect other normal battery modules 2
The automatic valve 23 attached to the exhaust pipe 9 is closed. Also,
The automatic valve 23 is composed of an electromagnetic valve, an electric valve, or an automatic valve such as a pneumatic drive, and is normally open.

Next, the electrical configuration for controlling the operation of the disaster prevention device of this embodiment will be described. As shown in FIG. 4, a gas sensor 22 is connected to the control device 24 to detect a corrosive gas detection signal. It is input to the control device 24. In addition, the controller 24 includes the automatic valve 23 and the exhaust fan 6
Is connected, and a signal for closing or opening the automatic valve 23 attached to the exhaust pipe 9 of the normal battery module 2 other than the abnormal battery module 2 and a signal for operating or stopping the exhaust fan 6 are output from the control device 24. Is output.

When a corrosive gas detection signal is input from the gas sensor 22 in the battery module 2 to the controller 24, the controller 24 causes the normal battery modules 2 other than the abnormal battery module 2 to occur. Exhaust pipe 9
Close all automatic valves 23 attached to. at the same time,
The control device 24 operates the exhaust fan 6 to guide the gas to the gas purifying device 7 for purification treatment.

If the abnormality of the unit cell 5 in the battery module 2 is accompanied by the rise of the internal pressure in the battery module 2 due to fire or abnormal reaction, the operation of the gas sensor 22 and the automatic valve 23 as in the first embodiment. Regardless of the above, the contaminated air is guided to the gas purifying device 7, but the gas sensor 22 detects the corrosive gas even when the internal pressure does not rise simply due to the leakage of the active material. Then, based on the detection signal of the gas sensor 22, after the automatic valve 23 attached to the battery module 2 other than the battery module 2 in which the abnormality has occurred is closed, the exhaust fan 6 of the gas purifier operates and the storage case. Contaminated air in the battery module 2 in which an abnormality has occurred is sucked together with the air in 1.

In this case, since the air in the normal battery module 2 is not sucked, the corrosive gas generated from the abnormal battery module 2 is not interfered with the operation of other normal battery modules 2. It can be purified without diffusion.

As described above, in the disaster prevention device of this embodiment, even if an abnormality occurs in the battery module 2 and a corrosive gas or a flame is generated, the gas does not change to another normal battery module 2.
There is no danger of moving to. Therefore, it is possible to prevent the abnormality of the battery module 2 from spreading to other normal battery modules 2 quickly and effectively.

The present invention is not limited to the configuration of the above-described embodiment, and may be embodied by arbitrarily changing the configuration of each part without departing from the spirit of the present invention, for example, as follows. . (A) Instead of the configuration provided with the automatic valve 23 and the check valve 11 in the second embodiment with one automatic valve that operates automatically based on the signal from the gas sensor 22, the gas is shut off To do. (B) The exhaust pipe 9 and the connecting pipe 8 are omitted by omitting the connecting pipe 10.
Connect directly to. (C) Exhaust pipe 9 attached to one battery module 2
Make the number of two or more. (D) In the second embodiment, the gas purification device 7 is configured to be operated at the gas pressure of corrosive gas.

[0027]

According to the first aspect of the present invention, since the battery module is configured as described above in detail, even if an abnormality occurs in the battery module and a fire occurs, the flame and high-temperature reaction product gas of the other normal The situation in which a battery module, a cable, or the like that touches the battery is greatly reduced, and the spread of an abnormal state can be prevented, has an excellent effect. Further, according to the second invention, even when the abnormality of the battery module is the leakage of corrosive gas that does not accompany an increase in the internal pressure, it is possible to quickly and surely prevent the abnormality from spreading to other normal battery modules. can get.

[Brief description of drawings]

FIG. 1 is a schematic partial cross-sectional view showing a disaster prevention device in a sodium-sulfur battery embodying the present invention.

FIG. 2 is a perspective view showing the entire disaster prevention device.

FIG. 3 is a partial cross-sectional view showing a disaster prevention device of a second embodiment.

FIG. 4 is a diagram showing an electrical configuration of a disaster prevention device according to a second embodiment.

[Explanation of symbols]

1 ... Storage case, 2 ... Battery module, 5 ... Single battery, 7
... Gas purifier, 8 ... Connection pipe, 9 ... Exhaust pipe, 11 ... Check valve as backflow prevention means, 23 ... Automatic valve as ventilation prevention means.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Masaaki Oshima 1-3-3 Uchisaiwaicho, Chiyoda-ku, Tokyo Tokyo Electric Power Company, Inc. (72) Akiyasu Okuno 1-3-1 Uchisaiwai-cho, Chiyoda-ku, Tokyo Higashi Within Kyodensha Co., Ltd. (72) Kenji Kawai 53, 1 Hiiragiyama, Obu-cho, Obu-shi, Aichi Prefecture (72) Inventor Takashi Kirisawa 30-30, Tomita-eicho, Yokkaichi-shi, Mie Prefecture 3 (72) Inventor Michitaka Hidaka Nagoya 24-18 Shinkaimachi, Mizuho-ku, Yokohama (72) Inventor Kenji Kato 9-11 Kiba-cho, Minato-ku, Nagoya

Claims (2)

[Claims] 1. A battery module is constructed by accommodating a large number of single cells of a sodium-sulfur battery in a module body, and a plurality of the battery modules are housed in a housing case. A gas purifying device for purifying gas is connected to the connection pipe, an exhaust pipe is attached to the battery module, the exhaust pipe is connected to the connection pipe, and a backflow prevention unit is provided in the exhaust pipe. Disaster prevention device for sodium-sulfur batteries. 2. A ventilation preventing means is provided in each of the exhaust pipes, and a gas detection sensor is attached to each battery module,
When an abnormality occurs in one of the battery modules and corrosive gas is generated in the battery module, the gas detection sensor detects this corrosive gas and detects the exhaust pipes attached to normal battery modules other than that battery module. The ventilation preventing means and the gas purifying device are operated to purify the contaminated air in the battery module and the storage case in which the abnormality has occurred, thereby preventing the abnormal state from spreading to the normal battery module. 1. A disaster prevention device for a sodium-sulfur battery according to 1.