JPH09161843A - Sodium/molten salt battery - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance safety and reliability. SOLUTION: This battery has a positive electrode vessel 3 for housing a positive electrode active material 5 mainly containing sulfur, a battery vessel formed by insulating and connecting a negative electrode vessel 4 for housing a negative electrode material mainly containing sodium to a solid electrolyte vessel 1, and a safety vessel 8 arranged within the negative electrode side space formed by the solid electrolyte vessel 1 and the negative electrode vessel 4. The safety vessel 8 is floatingly supported so as to be suspended through the thin film of the negative electrode active material 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sodium / molten salt battery, and more particularly, to improvement of safety and reliability of a battery for high power storage such as night power storage and electric vehicle.

[0002]

2. Description of the Related Art As a sodium / molten salt battery, Na
There are many kinds of batteries such as / S battery, Na / FeCl battery, and Na / Se battery, but the present invention is to solve the problems common to batteries using Na for the negative electrode. Take up and explain. In a conventional Na / S battery, as shown in FIG. 2, a negative electrode active material (Na) 6 and a positive electrode active material (S) 5 face each other via a solid electrolyte container 1, for example, β-alumina, β ″ -alumina, or the like. The positive electrode (S pole) is composed of S and an auxiliary conductive material (graphite felt) that plays the role of an electron conductor, and the negative electrode (Na electrode) is welded to the negative electrode container 4 and suspended in the safety container 8. Na is stored in
The Na necessary for the battery reaction flows out from the Na supply hole 7 provided at the bottom of the safety container 8 and is supplied to the solid electrolyte container 1.

Therefore, the role of the safety container is to store most of the Na that is unnecessary for the battery reaction, and to suppress the amount of Na that contributes to the direct reaction between Na and S even if the solid electrolyte container is damaged.
It is to ensure the safety of the battery. For the above purpose, the narrower the gap between the safety container and the solid electrolyte container, the smaller the amount of Na that contributes to the direct reaction of Na and S. Further, in the structure of FIG. 2, the safety container also functions as an electrode for taking out electric power generated by the battery. The safety container is housed in the solid electrolyte container in order to keep the volumetric energy density of the battery as large as possible.

However, when the safety container provided for ensuring safety is rigidly joined to the negative electrode container by welding as shown in FIG. 2 (defined as joining while retaining the rigidity of the metal material), Due to the thermal deformation of the safety container, the gap 22 between the safety container and the solid electrolyte container is not uniform. Therefore, a gap size of about 1.6 mm is required so that the safety container does not contact the solid electrolyte container.
It is difficult to reduce below.

When the battery temperature is raised or lowered to 300 to 350 ° C. for the battery operation in such a state, the safety container and the negative electrode container are deformed by thermal stress, and the solid electrolyte container in contact with the safety container is Inappropriate stress may be applied. This tendency is remarkable in the solid electrolyte container having poor straightness and roundness. The solid electrolyte container is a sintered body, and its manufacturing accuracy does not increase like metal working, and it is difficult to improve straightness and roundness. If the stress applied to the solid electrolyte container exceeds the allowable stress, the solid electrolyte container will be damaged.

Further, as a cause of breakage of the solid electrolyte container involved in the safety container, stress due to deformation of the negative electrode terminal 16 is considered. This is because when using a sodium / molten salt battery for power storage, it is necessary to connect a large number of batteries in series and in parallel, and since it becomes a large amount of power, a low resistance bus bar is required, It is a material with a strong momentum and high rigidity. As described above, the conventional safety container rigidly bonded is effective in suppressing the direct reaction between Na and S after the solid electrolyte is damaged, but there is a risk that the damage probability of the solid electrolyte is increased. .

On the other hand, in order to improve safety, JP-A-60-1
In the technique disclosed in Japanese Patent No. 2681, Na is contained in the solid electrolyte.
A sodium reservoir containing Na is installed outside the solid electrolyte, and a metal container filled with a gas is installed inside the solid electrolyte without placing a safety container containing therein. This is because even if the solid electrolyte is damaged, the gas in the metal container suppresses the Na supply from the sodium reservoir and suppresses the direct reaction amount of Na and S to ensure safety. Since Na necessary for the battery capacity is stored in the sodium reservoir outside the solid electrolyte, the volume energy density, which is an important element item for power generation of the battery, is the same as that of the conventional battery as shown in FIG. It is about 40%.

[0008]

As described above, in the prior art, it was not possible to achieve both safety and high volume energy density. That is, Na of Na / S battery
When the stored safety container is rigidly joined to the negative electrode container, there is a problem that the solid electrolyte is damaged by thermal deformation of the safety container when the temperature of the battery rises or falls. Further, in order to improve safety, if a sodium reservoir storing Na is installed outside the solid electrolyte container,
There is a problem that the size of the battery becomes large and the volume energy density is lowered.

Further, in the Na / S power storage device, many batteries are connected in series and parallel.
If the solid electrolyte of the battery of the present invention is damaged and the inside of the battery is short-circuited, a large short-circuit current may flow from the other assembled battery connected to these batteries, which may lead to damage of other healthy batteries. Furthermore, when the battery seal part between the electrical insulating material for electrically insulating the positive electrode and the negative electrode and the negative electrode container and the positive electrode container, that is, the heat-pressure contact part is damaged by the thermal deformation of the safety container, the battery active material is discharged from the seal part. Leaks and shorts out inside the battery. As a result, a short-circuit current flows inside the battery, and a large amount of Joule heat is generated inside the battery, resulting in a high temperature, which may lead to damage to the battery container.

Therefore, it is an object of the present invention to provide a safe / reliable sodium / molten salt battery which is free from damage to the solid electrolyte and a reduction in volumetric energy density.

[0011]

Means for Solving the Problems The feature of the present invention to achieve the above object is that a solid electrolyte container and a negative electrode container are arranged in a solid electrolyte container in a negative electrode side space formed for accommodating a negative electrode active material. The safety container faces the solid electrolyte container, and the outer surface shape of the facing safety container is opposed to the inner surface shape of the solid electrolyte container to form a uniform narrow gap between both surfaces, and the gap is filled. The thin film of the negative electrode active material thus formed is floatingly supporting the safety container.

Another feature of the present invention is to dispose a solid electrolyte container in a space formed by a positive electrode container and a negative electrode container,
The positive electrode active material is stored in the positive electrode side space surrounded by the positive electrode container and the solid electrolyte container, and the negative electrode active material is stored in the negative electrode side space surrounded by the negative electrode container and the solid electrolyte container, There is provided a battery container in which the three containers are insulated and joined via an electric insulating material so that the solid electrolyte container functions as a solid electrolyte, and the battery container is safe in the solid electrolyte container in the negative electrode side space. A safety container is floatingly supported by a thin film of the negative electrode active material interposed between the solid electrolyte container and the safety container around the lower portion of the safety container facing the solid electrolyte container. , And a soft metal reservoir for accumulating a conductive soft metal in the upper part of the safety container, and the soft metal reservoir facing the negative electrode container is interposed between the negative electrode container and the soft metal reservoir. Are In that it is floating supported by Ki軟 metal. According to the present invention, a sodium / molten salt battery having high safety and reliability, in which damage to the solid electrolyte and reduction in volumetric energy density are avoided, is provided.

[0013]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a vertical sectional view showing a sodium / molten salt battery according to an embodiment of the present invention.
The Na / S battery as the sodium / molten salt battery of the present embodiment has a positive electrode container 3 made of “metal material” and a negative electrode container 4 made of “metal material” and is made of “β” -alumina ”or the like. "S + Na ₂ Sx" is provided in the space on the positive electrode side surrounded by the positive electrode container 3 and the solid electrolyte container 1.
A positive electrode active material 5 made of, for example, and a negative electrode active material 6 made of “Na” or the like in a negative electrode side space surrounded by the negative electrode container 4 and the solid electrolyte container 1, and the solid electrolyte container 1 is a separator. So as to form the solid electrolyte as described above, the battery container is formed by insulatingly bonding the above-mentioned three containers at a portion such as the heat press contact portion 12 via the electric insulating material 2 made of “α-alumina” or the like.

Further, in the solid electrolyte container 1, a safety container 8 containing a large amount of the negative electrode active material 6 is disposed so as to face the solid electrolyte container 1. At this time, the outer surface shape 8a of the safety container 8 faces the inner surface shape 1a of the solid electrolyte container 1 so as to face each other so as to form a substantially uniform narrow gap between both surfaces. At the bottom of the safety container 8, the safety container 8
From the surface of the solid electrolyte container 1 to N as the negative electrode active material 6
A Na supply hole 7 for appropriately supplying a is provided. The negative electrode active material 6 supplied from the Na supply holes 7 is filled in the above-mentioned narrow gap 22 to form a thin film of the negative electrode active material 6. Therefore, when viewed from the negative electrode active material 6 side, the thin film of the negative electrode active material 6 supports the safety container 8.

On the other hand, the space on the positive electrode side is occupied by the positive electrode active material 5 and the positive electrode cover gas space 14. The negative electrode side space is occupied by the negative electrode active material 6, the safety container 8, and the negative electrode cover gas space 13. Then, the electricity generated by the ions of the filled negative electrode active material 6 passing through the solid electrolyte container 1 transfers the positive electrode terminal 17 connected to the positive electrode container 3 and the negative electrode terminal connected to the negative electrode container 4. 16
Taken out of Although the positive electrode terminal may be referred to as a positive electrode and the negative electrode terminal may be referred to as a negative electrode, they are the same.

By the way, in the sodium / molten salt battery of the present embodiment, a convex portion 4a, which is a portion of the negative electrode container 4 protruding, is provided at a position substantially in the center of the negative electrode container 4 and corresponding to the upper portion of the safety container 8. It is provided. Further, a soft metal reservoir 10 is provided on the upper portion of the safety container 8 at a portion corresponding to the convex portion 4a of the negative electrode container 4. The size of the soft metal reservoir 10 is larger than the size of the protrusion 4 a, and the protrusion 4 a is housed in the soft metal reservoir 10. Further, the soft metal reservoir 10 stores a soft metal 24 having conductivity. Then, the convex portion 4a of the negative electrode container 4 is placed on the soft metal 24 stored in the soft metal reservoir 10. In other words, the convex portion 4a of the negative electrode container 4 and the soft metal reservoir 10 of the safety container 8, that is, the negative electrode container 4 and the safety container 8
And are facing each other via the soft metal 24. In other words, when viewed from the soft metal 24 side, the soft metal 24 supports the safety container 8. When viewed from the side of the safety container 8, the safety container 8 is floatingly supported by the negative electrode active material 6 filled in the gap 22 and the soft metal 24 stored in the soft metal reservoir 10. Can be said. In this floating-supported state, the negative electrode terminal 16, the convex portion 4a of the negative electrode container 4, the soft metal 24, the soft metal reservoir 10, and the safety container 8 are electrically connected. Therefore, the current of the negative electrode in this case flows from the solid electrolyte container 1 through the thin film of the negative electrode active material 6 existing in the gap 22 to the convex portion 4a and the negative electrode terminal 16 through the safety container 8 and the soft metal 24, and A current path necessary for charging and discharging is formed.

According to the present invention, unlike the above structure, the safety container 8 is not rigidly joined to the negative electrode container 4 but is floatingly supported while being electrically connected, so that the allowable stress of the solid electrolyte container is increased by thermal deformation. Contact between the safety container and the solid electrolyte container which would be exceeded is avoided. As a result, the gap size of the gap 22 between the safety container 8 and the solid electrolyte container 1 can be reduced to, for example, 0.1 mm or less.
As described above, it was difficult to reduce the width to 1 mm or less in the conventional technique.

Therefore, the amount of Na required for the cell reaction held in the gap 22 can be made to be a very small minimum amount, and Na and S when the solid electrolyte container 1 is damaged.
Since the direct reaction of is suppressed, the safety of the battery can be sufficiently ensured. In addition, reducing the amount of Na held in the gap 22 to the required minimum amount leads to downsizing of the battery.

In summary, the feature of the present invention is that the safety container disposed in the solid electrolyte container in the negative electrode side space formed for accommodating the negative electrode active material in the solid electrolyte container and the negative electrode container is By contacting with the solid electrolyte container through the thin film of Na as the negative electrode active material and contacting with the negative electrode container through the soft metal, the safety container is floatingly supported without being rigidly joined to the negative electrode container. There is a point. At this time, in the negative electrode, a current path is formed from the solid electrolyte to the safety container via the Na thin film and further to the negative electrode container via the soft metal, and the battery reaction proceeds smoothly. Further, since there is a negative electrode active material that can be substituted as a soft metal, the negative electrode active material can also be used as a soft metal. In other words, a safety container containing Na as a negative electrode active material can be used as the negative electrode. It can also be said that the active material is suspended in the air through a thin film and is floatingly supported without being rigidly joined to the negative electrode container.

Specifically, the safety container is floatingly supported by using a negative electrode active material and a soft metal (or a negative electrode active material which can be substituted for the soft metal). Here, the soft metal is defined as a metal having a low rigidity at room temperature and a lower rigidity or liquefaction at a battery operating temperature and having conductivity. Floating support means floating in a fluid and
It is defined as a supporting method in which the spatial position is determined. Based on the above, a soft metal reservoir for electrically connecting the safety container and the negative electrode container is provided at the upper end of the safety container.

According to the present invention, damage to the solid electrolyte or the heat-pressure contact due to thermal deformation of the safety container is prevented, and even if the solid electrolyte or the heat-pressure contact is damaged and a battery short circuit or an abnormal temperature rise occurs, the damage is caused. A sodium / molten salt battery is provided that electrically isolates the battery from other healthy series-parallel batteries and is safe and has improved safety and reliability without loss of volumetric energy density.

In this embodiment, the sodium element is used as the soft metal 24. However, a metal such as a lithium element, a potassium element, or a lead element, or a composite metal containing these elements as a main component is used as described above. Any material that meets the definition can be applied. On the other hand, if the negative electrode active material 6 meets the definition of a soft metal, such as sodium, it can be said that the soft metal 24 is the same material as the negative electrode active material 6 in terms of manufacturing.

By the way, in this embodiment, the negative electrode cover gas space 13 is provided in the negative electrode side space which is the upper portion of the solid electrolyte container 1, and the negative electrode cover gas space 13 is filled with an inert gas. A battery container having such a structure is provided, and an electrical insulating material 2
The heat-pressure contact portion 12 that is a joint portion between the negative electrode container 4 and the negative electrode container 4 does not come into contact with Na and is not corroded by Na, or the solid electrolyte container 1 or the like is deformed due to thermal deformation that occurs when the temperature is raised or lowered during battery operation. It is to prevent damage.

That is, without the negative electrode cover gas space 13 containing the inert gas, the expanded Na easily reaches the heat press contact portion 12 when the temperature rises during battery operation, and Na contacts the heat press contact portion 12, Corrosion of the hot press contact part 12. When the negative electrode cover gas space 13 is absent and is filled with Na, the volume of Na expands due to the phase change of Na from a solid to a liquid at the time of temperature rise, and the hot press contact portion 12 and the negative electrode container. 4 caused abnormal stress, and the heat press contact part 12 and the negative electrode container 4
May be damaged. On the other hand, when the negative electrode cover gas space 13 is present, the gas pressure of the inert gas causes N
a is prevented from expanding, or the negative electrode cover gas space 13
Serves as a buffer to prevent contact and damage.

That is, in this embodiment, the negative electrode side space formed by the negative electrode container 4 containing the safety container 8 and the solid electrolyte container 1 was provided with the negative electrode cover gas space 13 to fill the negative electrode side space. It is intended to prevent adverse effects (for example, damage) on the negative electrode container 4 and the solid electrolyte container 1 when the negative electrode active material 6 or the soft metal 24 according to the present invention expands at the time of temperature rise.

FIG. 3 is a longitudinal sectional view showing a second embodiment of the sodium / molten salt battery according to the present invention. In the second embodiment, the shape of the soft metal reservoir 10 that stores the soft metal 24 that electrically connects the safety container 8 and the negative electrode container 4 and the floating support of the safety container 8 are improved. In order to withstand the vibration when the sodium / molten salt battery is used in a portable application such as an automobile, the upper end of the soft metal reservoir 10 is squeezed, and the upper end has a function of a lid so that the soft metal 24 vibrates. It is possible to prevent liquid leakage due to the above, ensure electrical conductivity, and reduce the cost because the lid is integrally processed.

For example, the upper end of the safety container 8 and the negative electrode container 4
The space between and is narrower than 0.2mm. As a result, even if both the upper end portion and the negative electrode container 4 come into contact with each other due to vibration, point contact occurs, and the stress applied to the solid electrolyte container 1 in the present invention is the stress generated when the conventional safety container 8 is rigidly joined. Much smaller than That is, comparing with the allowable stress of the solid electrolyte of the solid electrolyte container 1 of 200 MPa,
The stress is 20 to 30 MPa which can be ignored. Therefore, both functions of preventing liquid leakage and floating support are ensured. That is, this embodiment has a structure that can withstand running vibrations and earthquakes, and maintains the electrical connection between the negative electrode container 4 and the safety container 8 while maintaining the soft metal reservoir provided at the upper end of the safety container 8. The upper end portion of the safety container is drawn so as to prevent the soft metal 24 in the container 10 from flowing out, and has a lid function.

FIG. 4 is a vertical sectional view showing a third embodiment of the sodium / molten salt battery according to the present invention. The third embodiment improves the electrical contact between the negative electrode container 4 and the soft metal 24 and improves the wettability of the negative electrode container in contact with the soft metal with the soft metal.

The soft metal 24 of the negative electrode container 4 (that is, the convex portion 4a)
A coating layer 18 coated with a material that easily wets Na is provided on the surface in contact with. As the coating material, for example, when Na is used as a soft metal, a material that forms an intermetallic compound with Na, such as gold, platinum, or lead, is effective. More specifically, the contact resistance before the negative electrode container is wet with the soft metal is several Ω, but when it is wet with the present invention, it is reduced to 1 mΩ or less. In this embodiment, the surface portion of the negative electrode container that comes into contact with the soft metal is coated with a material that easily wets the soft metal. Thereby, the internal resistance can be reduced and the battery efficiency can be improved.

FIG. 5 is a vertical sectional view showing a fourth embodiment of the sodium / molten salt battery according to the present invention. In the fourth embodiment, when the battery fails due to damage to the solid electrolyte due to deformation of the safety container or the negative electrode, or damage to the seal portion of the battery container, the short-circuit current flowing from another assembled battery or within the battery unit A means for interrupting the generated short-circuit current is provided inside or outside the negative electrode container or inside and outside.

In the embodiment of FIG. 5, the convex portion 4a of the negative electrode container 4 is used.
An example is shown in which a fuse 21 inside the negative electrode is provided at the tip of the negative electrode, and a fuse 20 outside the negative electrode is provided at the negative electrode terminal 16 as an external bus bar. The fuse 21 in the negative electrode has a fuse function of detecting a temperature or / and a current and interrupting the internal circulating current due to a short circuit of a seal portion flowing between the negative electrode container 4 and the soft metal 24 or a short circuit inside the battery. It is provided as a thing. The negative electrode fuse 20 is provided as a device for blocking an abnormal current from another external assembled battery. That is, the fuse 20 outside the negative electrode and the fuse 21 inside the negative electrode are divided. The fuse material is preferably an Al-based alloy because of its coexistence with Na. Further, the coating layer 18 may be provided on the negative electrode fuse 21.

That is, in the present embodiment, in order to interrupt the short-circuit current when the battery fails, the fuse 21 in the negative electrode is attached to the soft metal side portion of the negative electrode container that comes into contact with the soft metal, or
A fuse 21 inside the negative electrode is provided at the soft metal side portion, and a fuse 20 outside the negative electrode is provided at the negative electrode terminal portion of the negative electrode container as a current interrupting means. This further improves safety. The negative electrode terminal of the negative electrode container may be an external bus bar.

FIG. 6 is a longitudinal sectional view showing a fifth embodiment of the sodium / molten salt battery according to the present invention. In the fifth embodiment, the negative electrode container 4 is provided with an injection pipe 25 having a Na injection function, a fuse function, and a negative electrode function. In the figure, Na is a vacuum or inactive state in the space on the negative electrode side in the battery container, passes through the injection pipe 25 and the soft metal reservoir 10, passes through the gap 22 between the safety container 8 and the solid electrolyte container 1, and passes through the Na supply hole. The liquid is injected from the outside into the safety container 8 from 7. After the Na injection, the injection pipe 25 has a stopper 25a.
Sealed. Alternatively, instead of the plug 25a, the fuse 20 outside the negative electrode is used for sealing. Alternatively, the injection tube 25
It is also possible to melt and seal.

The soft metal 24 is injected after Na injection.
It can be injected in a similar manner. Furthermore, the coating layer 18 may be provided on the injection pipe 25. According to the present embodiment,
It is possible to easily fill the safety container 8 and the soft metal reservoir 10 with Na or a soft metal without oxidizing them. That is, in this embodiment, the efficiency of the injection of the soft metal into the soft metal reservoir is improved, and the negative electrode terminal has the function of the injection hole for injecting Na or the soft metal through the soft metal reservoir. In other words, it can be said that the negative electrode container has an injection pipe for injecting the soft metal into the soft metal reservoir or for injecting the negative electrode active material through the soft metal reservoir.

FIG. 7 is a longitudinal sectional view showing a sixth embodiment of a sodium / molten salt battery according to the present invention. The sixth embodiment has a gap 22 between the safety container 8 and the solid electrolyte container 1.
A spacer 23 made of a porous material is provided on the above.
By providing the spacers 23, it is possible to make the gap size of the gap 22 uniform and to maintain it uniform. In addition, the spacer 23 also serves to prevent direct contact between the safety container 8 and the solid electrolyte container 1 and eliminate damage such as damage due to contact.

As the spacer 23, a porous body having a hole for allowing the negative electrode active material 6 to flow, such as foam metal or glass fiber, is adopted. In order to absorb thermal deformation at high output during battery operation or abnormal high temperature due to solid electrolyte damage, or deformation due to external force, the metal foam as a porous body should have a "crush margin". Is preferred. Therefore, as the spacer 23, a foam metal made of Al or Ni material is most suitable. Further, the spacer 23 is not necessarily a conductor and may be glass fiber or alumina fiber.

In this embodiment, in the battery container, the safety container has a porous body around the lower part of the safety container facing the solid electrolyte container, and the safety container is supported by the porous body. Therefore, the gap size between the safety container and the solid electrolyte container becomes uniform, and the safety and reliability are further improved.

[0038]

EFFECTS OF THE INVENTION According to the present invention, not only is the solid electrolyte kept sound and safe without an unnecessary load being applied to the solid electrolyte, but it is also possible to always take out current with a low resistance and reduce the volume energy density. There is an effect that a sodium / molten salt battery having no deterioration and high safety and reliability can be obtained.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing a sodium / molten salt battery according to an embodiment of the present invention.

FIG. 2 is a vertical sectional view showing a conventional sodium / molten salt battery.

FIG. 3 is a vertical sectional view showing a second embodiment of a sodium / molten salt battery according to the present invention.

FIG. 4 is a vertical sectional view showing a third embodiment of a sodium / molten salt battery according to the present invention.

FIG. 5 is a vertical cross-sectional view showing a fourth embodiment of a sodium / molten salt battery according to the present invention.

FIG. 6 is a vertical sectional view showing a fifth embodiment of a sodium / molten salt battery according to the present invention.

FIG. 7 is a vertical cross-sectional view showing a sixth embodiment of a sodium / molten salt battery according to the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Solid electrolyte container, 1a ... Inner surface shape, 2 ... Electrical insulating material, 3 ... Positive electrode container, 4 ... Negative electrode container, 4a ... Convex part, 5 ... Positive electrode active material, 6 ... Negative electrode active material, 7 ... Na supply hole 8 ... Safety container, 8a ... Outer surface shape, 10 ... Soft metal reservoir, 11 ... Na liquid surface at the end of charging, 12 ... Heat press contact portion, 13 ... Negative electrode cover gas space, 14 ... Positive electrode cover gas space, 15 ... Safety container cover gas Space, 16 ... Negative electrode terminal, 17 ... Positive electrode terminal, 18 ...
Coating layer, 20 ... Negative electrode fuse, 21 ... Negative electrode fuse, 22 ... Gap 23 ... Spacer, 24 ... Soft metal, 25 ... Injection tube, 25a ... Plug.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Naohisa Watabiki 7-2-1, Omika-cho, Hitachi-shi, Ibaraki Hitachi, Ltd. Power & Electric Machinery Development Division

Claims (10)

[Claims] 1. A safety container disposed in the solid electrolyte container in a space on the negative electrode side formed to house a negative electrode active material in the solid electrolyte container and the negative electrode container faces the solid electrolyte container, The outer surface shape of the facing safety container is opposed to the inner surface shape of the solid electrolyte container to form a substantially uniform narrow gap between both surfaces, and the thin film of the negative electrode active material filled in the gap is formed. ,
A sodium / molten salt battery in which the safety container is supported in a floating manner. 2. A solid electrolyte container is disposed in a space formed by the positive electrode container and the negative electrode container, and a positive electrode active material is housed in a positive electrode side space surrounded by the positive electrode container and the solid electrolyte container. , A negative electrode active material is housed in a negative electrode side space surrounded by the negative electrode container and the solid electrolyte container, and the three containers are insulated and joined via an electric insulating material so that the solid electrolyte container functions as a solid electrolyte. And a safety container in the solid electrolyte container in the negative electrode side space, wherein the safety container is a lower part of the safety container facing the solid electrolyte container. Floatingly supported by a thin film of the negative electrode active material interposed between the solid electrolyte container and the safety container in the periphery, and has a soft metal reservoir for storing a conductive soft metal in the upper part of the safety container, The negative electrode container Sodium / molten salt battery, characterized in that it is floating supported by the soft metal in reservoir soft metals are facing is interposed between the negative electrode container said soft metal reservoir. 3. The soft metal according to claim 2, wherein the soft metal is sodium element, lithium element, or potassium element,
Or a sodium / molten salt battery characterized by being a lead element. 4. The sodium / metal according to claim 2, wherein the soft metal is the same material as the negative electrode active material.
Molten salt battery. 5. The sodium / molten salt battery according to claim 2, wherein the safety container has a lid for preventing the soft metal from flowing out at an upper end portion of the safety container. 6. The sodium / molten salt according to claim 2, wherein the surface area of the negative electrode container that comes into contact with the soft metal is coated with a material that easily wets the soft metal. battery. 7. The negative electrode container according to claim 2, wherein a portion of the negative electrode container on a soft metal side in contact with the soft metal, or a portion on the soft metal side and a negative electrode terminal portion of the negative electrode container,
A sodium / molten salt battery having a current interruption means. 8. The negative electrode container according to claim 2, wherein the negative electrode container is used to inject the soft metal into the soft metal reservoir, or to inject the negative electrode active material into the negative electrode side space via the soft metal reservoir. A sodium / molten salt battery, characterized in that it has an injection tube. 9. The sodium / molten salt battery according to claim 2, wherein the battery container has a negative electrode cover gas space in the negative electrode side space. 10. The battery container according to claim 2, wherein the safety container has a porous body around a lower portion of the safety container facing the solid electrolyte container, and the safety container has the porous body. A sodium / molten salt battery characterized in that it is supported by.