KR20150076416A - Sodium-sulfur rechargeable battery module - Google Patents

Abstract

A sodium-sulfur battery module according to one aspect of the present invention includes a plurality of unit cells which include sulfur electrodes, sodium electrodes, and electrolyte plates which are arranged between the sulfur electrodes and the sodium electrodes, a separation case which is arranged between the unit cells and receives the sodium electrode and the sulfur electrode, and a sealing unit which seals the case and the unit cell. The unit cells are stacked. The electrolyte plate is bonded to the separation case.

Description

[0001] SODIUM-SULFUR RECHARGEABLE BATTERY MODULE [0002]

The present invention relates to a sodium sulfur battery module. More particularly, the present invention relates to a sodium-sulfur battery module having a structure in which a plurality of unit cells are stacked.

Generally, a sodium-sulfur battery is developed as a large-capacity power storage battery because of its high energy density, charge / discharge efficiency, self-discharge, and irregular charge / discharge characteristics.

Sodium sulfur battery is a high-temperature type secondary battery that operates at 300 to 350 degrees Celsius. It uses sodium (Na) as a cathode, sulfur (S) as an anode, and a solid electrolyte having a sodium ion conductivity as an electrolyte. Lt; / RTI >

The sodium sulfur battery can be divided into a tubular type and a flat type, and the tubular sodium sulfur battery includes a cathode vessel enclosing an electrolyte tube and an electrolyte tube. The electrolytic tube is a structure in which a beta alumina ceramic having a property of passing only sodium ions is formed in a tube shape. The inside of the electrolyte tube is filled with sodium, and sulfur and carbon felt are placed between the electrolyte tube and the positive electrode container. The sodium ion moves between the cathode and the anode through the beta alumina, which is an electrolyte tube, and reacts with sulfur and electrons to charge and discharge the battery.

On the other hand, in the plate type sodium sulfur battery, two plate-shaped caps are arranged, and sodium and sulfur are positioned inside the cap. Also, an electrolyte plate is provided between sodium and sulfur, and an electrolyte plate is bonded to an insulator that insulates the caps.

Plate-type sodium sulfur batteries are advantageous in capacity through a lamination arrangement, but may cause unevenness of stress during lamination. In particular, stress is concentrated on the alpha-alumina ceramics which insulates the case of different sizes, resulting in a structure susceptible to load.

In addition, a metal case and alumina ceramics are bonded. Since the metal and ceramics have different thermal expansion rates, they may expand to different sizes when heated, resulting in poor bonding.

Accordingly, an object of the present invention is to provide a sodium sulfur battery module in which structural stability is improved by uniformly supporting a load.

Another object of the present invention is to provide a sodium sulfur battery module capable of reducing the occurrence of defective junctions.

A sodium sulfur battery according to an aspect of the present invention includes a plurality of unit cells including a sulfur electrode, a sodium electrode, and an electrolyte plate disposed between the sulfur electrode and the sodium electrode, A separation case for accommodating the sulfur electrode, and a sealing part for sealing the unit cell and the case, wherein the plurality of unit cells are stacked, and the electrolyte plate is bonded to the separation case.

The separating case includes a cover plate, a first support ring joined to one side of the cover plate and having a sulfur electrode inserted therein, and a second support ring joined to the other side of the cover plate opposite to the one side, And may include a support ring.

Further, the rim, which is an area adjacent to the side edge of the electrolyte plate, can be joined to the first support ring of one of the separation cases and the second support ring of another separation case.

The sealing portion may include a base sealing layer surrounding the rim portion. The base sealing layer may surround the upper and lower surfaces of the electrolyte plate.

Further, a glass bonding layer may be formed between the first supporting ring and the base sealing layer, and the glass bonding layer may be formed to have a larger thermal expansion coefficient than the base sealing layer.

In addition, a buffering sealing layer is formed between the base sealing layer and the glass bonding layer, and the buffering sealing layer has a thermal expansion coefficient larger than that of the base sealing layer and is formed to have a thermal expansion coefficient smaller than that of the glass bonding layer .

The buffering sealing layer may include a first buffering sealing layer, a second buffering sealing layer, and a third buffering sealing layer disposed in layers, the first buffering sealing layer being disposed in contact with the base sealing layer, The third cushioning sealing layer may be disposed to abut the glass bonding layer and the second cushioning sealing layer may be disposed between the first cushioning sealing layer and the third cushioning sealing layer.

In addition, the second cushioning sealing layer may have a greater thermal expansion coefficient than the first cushioning sealing layer, and may have a smaller thermal expansion coefficient than the third cushioning sealing layer.

The battery pack may further include a first outer case and a second outer case disposed on the outer side of the sodium sulfur battery module and supporting the unit cell, the first outer case including a first outer cover plate and a first outer support ring A sodium electrode is inserted into the first outer support ring, the second outer case includes a second outer cover plate and a second outer support ring, and a sulfur electrode may be inserted into the second outer support ring.

The sodium sulfur battery module further includes a first end plate supported to abut against the first outer case, a second end plate abutted against the second outer case, a pressure end plate disposed apart from the first end plate, And an elastic member disposed between the first end plate and the pressurizing end plate, and a tie bar may be installed to penetrate the first end plate, the second end plate, and the pressurizing end plate.

As described above, according to the present invention, since the rims are disposed between the first support ring and the second support ring and are joined to the first support ring and the second support ring, stress acts on the support rings in a straight line direction to eliminate stress unevenness . In addition, since the buffering sealing layer is formed, it is possible to prevent a defective junction from occurring due to the difference in thermal expansion.

Further, since the separating case is provided, the sodium sulfur battery module can be easily formed by stacking the separating cases between the unit cells.

Further, since the base sealing layer is formed on the side surface, the upper surface and the lower surface of the rim of the electrolyte plate, the leakage of sodium can be prevented.

1 is a cross-sectional view illustrating a sodium sulfur battery module according to a first embodiment of the present invention.
FIG. 2 is a partial cross-sectional view showing a bonded portion in the sodium sulfur battery module according to the first embodiment of the present invention.
3 is a cross-sectional view illustrating a sodium sulfur battery module according to a second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It will be apparent to those skilled in the art that the embodiments described below may be modified in various forms without departing from the spirit and scope of the present invention, .

The drawings are schematic and illustrate that they are not drawn to scale. The relative dimensions and ratios of the parts in the figures are shown exaggerated or reduced in size for clarity and convenience in the figures, and any dimensions are merely illustrative and not restrictive.

FIG. 1 is a cross-sectional view illustrating a sodium sulfur battery according to an embodiment of the present invention, and FIG. 2 is a partial cross-sectional view illustrating a bonded portion in a sodium sulfur battery according to an embodiment of the present invention.

1 and 2, the sodium sulfur battery module 100 of the present embodiment includes a plurality of unit cells 10, a separation case 23, a sealing portion 40, a first outer case 21, And a second outer case (22).

The unit cell 10 includes a sulfur electrode 11 and a sodium electrode 12 and an electrolyte plate 13 disposed between the sulfur electrode 11 and the sodium electrode 12. The sulfur electrode 11 includes a felt collector and sulfur impregnated in the felt collector. For example, the felt collector may be made of a graphite felt having pores formed therein, and the sulfur may be impregnated into the pores in a molten state.

The sodium electrode 12 includes a sodium container 12a that houses sodium and a sodium 12b that is liquid in the sodium container 12a. The opening 12c in which the sodium 12b can escape so that the sodium 12b filled in the sodium container 12a can come into contact with the electrolyte plate 13 is formed on the surface facing the electrolyte plate 13 in the sodium container 12a, Is formed. Sodium which has passed through the opening 12c is filled between the electrolyte plate 13 and the separating case 23 and comes into contact with the inner wall of the electrolyte plate 13.

The electrolyte plate 13 is made of beta alumina ceramics capable of passing sodium ions. The electrolyte plate 13 has a flat plate structure, and may be formed into a polygonal plate shape such as a circular plate or a rectangular plate, and the shape thereof is not particularly limited as long as it is a flat plate structure.

The electrolyte plate 13 selectively permeates only sodium ions and serves to prevent shorts of the cases. The electrolyte plate 13 directly contacts the separating case 23 with the sealing portion 40 therebetween.

The unit cell 10 uses sodium as a cathode and sulfur as an anode. During the discharge of the unit cell 10, sodium ions move through the electrolyte plate 13 to the anode side, and react with sulfur and electrons to form sodium polysulfide. At the time of charging, sodium polysulfide releases electrons and separates into sodium ion and sulfur.

The sodium ion passes through the electrolyte plate 13, moves to the cathode side, receives electrons, and returns to sodium. Charging / discharging of the unit cell 10 is performed at a temperature of approximately 300 캜 to 350 캜.

The separation case 23 is disposed between the unit cells 10 and the first outer case 21 and the second outer case 22 are disposed on the outermost side of the sodium sulfur battery module 100.

The separating case 23 has a cover plate 23a and a first support ring 23b which is joined to one side of the cover plate 23a and into which the sulfur electrode 11 is inserted and a cover plate 23a, And a second support ring 23c which is joined to the other surface facing the first electrode 22 and into which the sodium electrode 12 is inserted.

The separation case 23 is made of a metal material such as aluminum or stainless steel. The surface of the separating case 23 may be coated with a corrosion resistant layer containing chromium, molybdenum or the like as a main component.

The cover plate 23a is in the form of a flat plate, and may be in the form of a polygonal plate such as a disk or a rectangular plate. The first support ring 23b and the second support ring 23c are annular in which a hole is formed on the inner side and have a circular cross section. The first support ring 23b and the second support ring 23c are joined so as to protrude from surfaces of the cover plate 23a facing each other.

A sodium containing chamber in which the sulfur electrode 11 is inserted is formed at one side of the separation case 23 and a sodium containing chamber is inserted at the opposite side to the sodium electrode 12. The cover plate 23a and the first support ring 23b and the second support ring 23c can be joined by hot pressing and the cover plate 23a and the first support ring 23b and the second support ring 23c May be integrally formed.

It is not necessary to separately bond the plurality of cases by applying the separation case 23 as in the present embodiment and only the sodium electrode 12 and the sulfur electrode 11 are accommodated and laminated in the separation case 23, The battery module 100 can be easily manufactured.

The first outer case 21 and the second outer case 22 are disposed on the outermost side of the sodium sulfur battery module 100 to support the unit cells 10. The first outer case 21 and the second outer case 22 are disposed on different sides of the sodium sulfur battery module 100.

The first outer case 21 is made of a metal material such as aluminum or stainless steel. The surface of the first outer case 21 may be coated with a corrosion resistant layer composed mainly of chromium, molybdenum, or the like. The first outer case 21 also serves as an external terminal of the anode.

The first outer case 21 includes a first outer cover plate 21a and a first outer support ring 21b and a sulfur electrode 11 is inserted into the first outer support ring 21b. The first outer support ring 21b may be fixed to the first outer cover plate 21a by hot pressing and the first outer support ring 21b and the first outer cover plate 21a may be integrally formed . And the first outer support ring 21b is joined to only one side of the first outer case 21. [

The second outer case 22 is made of a metal material such as aluminum or stainless steel. The surface of the second outer case 22 may be coated with a corrosion resistant layer composed mainly of chromium, molybdenum, or the like. The second outer case 22 also serves as an external terminal of the anode.

The second outer case 22 includes a second outer cover plate 22a and a second outer support ring 22b and a sodium electrode 12 is inserted into the second outer support ring 22b. The second outer support ring 22b may be fixed to the second outer cover plate 22a by hot pressing and the second outer support ring 22b and the second outer cover plate 22a may be integrally formed . And the second outer support ring 22b is joined to only one side of the second outer case 22. [

The sealing portion 40 bonds the electrolyte plate 13 to the separating case 23, the first outer case 21 or the second outer case 22. The sealing portion 40 bonded to the separating case 23 and the first outer case 21 or the second outer case 22 has the same structure so that the sealing portion 40 bonded to the separating case 23 will be described below. Will be described.

The edge portion which is adjacent to the side edge of the electrolyte plate 13 is located between the first support ring 23b of one of the separation cases 23 and the second support ring 23c of the other separation case 23, Is joined to the first support ring (23b) and the second support ring (23c). The rim portion of the electrolyte plate 13 means a portion extending inward from the side end of the electrolyte plate 13 by a predetermined length. The rim portion supports an axial load transmitted from the first support ring 23b and the second support ring 23c.

When the electrolyte plate 13 is directly bonded to the first support ring 23b and the second support ring 23c as in the present embodiment, the electrolyte plate 13 is supported by the first support ring 23b and the second support ring 23c ) And supports the load, so that the load can be more stably supported. The sealing portion 40 includes a base sealing layer 41 surrounding the rim portion and a buffer sealing layer 42 formed on the base sealing layer 41 and a glass bonding layer 45 formed on the buffer sealing layer 42 do.

The base sealing layer 41 is formed to surround the rim of the electrolyte plate 13. The base sealing layer 41 may be made of a material having a very low ionic conductivity such as sodium adhesive or glass adhesive.

The base sealing layer 41 includes a side sealing layer 41c coated on the side surface of the electrolyte plate 13 and a top sealing layer 41a coated on the top surface of the electrolyte plate 13 and a bottom sealing layer 41b coated on the bottom surface of the electrolyte plate 13 And a coated lower surface sealing layer 41b. The base sealing layer 41 is formed so as to surround the side surfaces of the electrolyte plate 13 and the upper and lower surfaces connected to the side surfaces. When the base sealing layer 41 is formed to surround the upper surface, the lower surface and the side surface of the electrolyte plate 13, it is possible to prevent sodium from leaking between the separation case 23 and the electrolyte plate 13.

A glass bonding layer 45 is formed between the first supporting ring 23b and the base sealing layer 41 and a glass bonding layer 45 is formed between the second supporting ring 23c and the base sealing layer 41. [ . The glass bonding layer has a thermal expansion coefficient larger than that of the base sealing layer 41. [

The glass bonding layer 45 is made of an adhesive containing glass powder and a binder. The glass bonding layer 45 is formed by adjusting the amount of a substance added to the glass bonding layer 45 such as BaO, Al ₂ O ₃ , SiO ₂ , Can be controlled.

A buffering sealing layer 42 is formed between the base sealing layer 41 and the glass bonding layer 45. The buffering sealing layer 42 has a greater coefficient of thermal expansion than the base sealing layer 41 and has a smaller thermal expansion coefficient than the glass bonding layer 45.

The buffering sealing layer 42 includes a first buffering sealing layer 42a, a second buffering sealing layer 42b, and a third buffering sealing layer 42c. The first cushioning sealing layer 42a is disposed to abut the base sealing layer 41 and has a greater coefficient of thermal expansion than the base sealing layer 41. [ The third cushioning sealing layer 42c is disposed to abut the glass bonding layer 45 and has a thermal expansion coefficient smaller than that of the glass bonding layer 45. [ The second cushioning sealing layer 42b is disposed between the first cushioning sealing layer 42a and the third cushioning sealing layer 42c and has a greater thermal expansion coefficient than the first cushioning sealing layer 42a, Lt; / RTI > layer 42c.

Although the cushioning sealing layer 42 is formed of three layers in the present embodiment, the present invention is not limited thereto. The cushioning sealing layer 42 may be formed of at least one layer.

First cushioning sealing layer (42a) and a second buffer-sealing layer (42b), and a third buffer sealing layer (42c) is for the main component is glass, BaO, Al ₂ O contained in the buffer sealing layer _3, SiO ₂ The amount of the material can be changed to control the thermal expansion rate.

The first cushioning sealing layer 42a, the second cushioning sealing layer 42b, and the third cushioning sealing layer 42c may be in the form of a tape made by tape casting. When the buffering sealing layer 42 is made of tape casting, the buffer sealing layer 42 can be easily attached on the base sealing layer 41, and a plurality of layers can be easily stacked.

The separation case 23 made of metal and the electrolyte plate 13 made of beta alumina ceramic have a large difference in thermal expansion coefficient. Therefore, even when a material having a thermal expansion coefficient intermediate between aluminum and ceramics and metal is used as a sealing agent, there is a high possibility that bonding failure occurs due to a difference in thermal expansion coefficient when heated or cooled to a high temperature.

However, when the buffer sealing layer 42 is formed between the base sealing layer 41 and the glass bonding layer 45 as in the present embodiment, the difference in the thermal expansion rate can be gradually mitigated, It is possible to prevent occurrence of defects.

3 is a cross-sectional view illustrating a sodium sulfur battery module according to a second embodiment of the present invention.

3, the sodium-sulfur battery module 200 according to the second embodiment of the present invention includes the end plates 51, 52, and 53 and the tie bar 54, The same structure as that of the sodium sulfur battery module according to the first embodiment is formed, so that a duplicate description of the same structure will be omitted.

A first end plate 51, a second end plate 52 and a pressing end plate 53 for supporting the outer cases 21 and 22 are installed on the outermost side of the sodium sulfur battery module 200. The first end plate 51 is disposed to abut the first outer case 21 and the second end plate 52 is abutted against the second outer case 22. [ The first end plate 51 and the second end plate 52 are formed in a flat plate shape and are in close contact with the outer cases 21 and 22 to support the outer cases 21 and 22 while pressing them inward.

On the other hand, the first end plate 51 is provided with a pressing end plate 53 via an elastic member 57. The pressing end plate 53 is spaced apart from the first end plate 51 and disposed in parallel with the first end plate 51 to press the first end plate 51 inward. The elastic member 57 may be a coil spring and a plurality of elastic members 57 are arranged between the first end plate 51 and the pressing end plate 53 at predetermined intervals.

A tie bar 54 is provided through the first end plate 51, the second end plate 52 and the pressurizing end plate 53. A nut 56 is provided at the longitudinal end of the tie bar 54, Respectively. The nut 56 serves to fix the tie bars 54 and the end plates 51, 52, 53 by fixing them.

 When the nut 56 is moved to the longitudinal center of the tie bar 54, the elastic member 57 is contracted, and the contracted elastic member 57 presses the first end plate 51 inward, Thereby allowing the module 100 to maintain structural stability.

While the illustrative embodiments of the present invention have been shown and described, various modifications and alternative embodiments may be made by those skilled in the art. Such variations and other embodiments will be considered and included in the appended claims, all without departing from the true spirit and scope of the invention.

100, 200: sodium sulfur battery module 10: single cell
11: sulfur electrode 12: sodium electrode
12a: Sodium container 12b: Sodium
12c: opening 13: electrolyte plate
21: first outer case 21a: first outer cover plate
21b: first outer support ring 22: second outer case
22a: second outer cover plate 22b: second outer support ring
23: separating case 23a: cover plate
23b: first support ring 23c: second support ring
40: sealing part 41: base sealing layer
41a: an upper surface sealing layer 41b: a lower sealing layer
41c: side sealing layer 42: buffer sealing layer
42a: first buffering sealing layer 42b: second buffering sealing layer
42c: third buffering sealing layer 45: glass bonding layer
51: first end plate 52: second end plate
53: pressure end plate 54: tie bar
56: Nut 57: Elastic member

Claims (10)

A plurality of unit cells including a sulfur electrode and a sodium electrode, and an electrolyte plate disposed between the sulfur electrode and the sodium electrode;
A separation case disposed between the unit cells to receive the sodium electrode and the sulfur electrode; And
A sealing part sealing the unit cell and the case;
Lt; / RTI >
Wherein the plurality of unit cells are stacked, and the electrolyte plate is bonded to the separating case. The method according to claim 1,
The separating case includes a cover plate, a first support ring joined to one side of the cover plate, and a second support member joined to the other side of the cover plate opposite to the one side of the cover plate, A sodium-sulfur battery module comprising a ring. 3. The method of claim 2,
Wherein a rim portion, which is an area adjacent to a side edge of the electrolyte plate, is bonded to a first support ring of one of the separation cases and to a second support ring of another separation case. 3. The method of claim 2,
Wherein the sealing portion includes a base sealing layer surrounding the rim portion, and the base sealing layer surrounds a top surface and a bottom surface of the electrolyte plate, the top surface extending from the side surface and the side surface. 3. The method of claim 2,
A glass bonding layer is formed between the first supporting ring and the base sealing layer, and the glass bonding layer has a thermal expansion coefficient larger than that of the base sealing layer. 6. The method of claim 5,
A buffer sealing layer is formed between the base sealing layer and the glass bonding layer and the buffer sealing layer has a thermal expansion coefficient larger than that of the base sealing layer and has a thermal expansion coefficient smaller than that of the glass bonding layer, . The method according to claim 6,
Wherein the buffering sealing layer comprises a stacked first buffering sealing layer, a second buffering sealing layer, and a third buffering sealing layer, wherein the first buffering sealing layer is disposed to abut the base sealing layer, 3 < / RTI > cushioning sealing layer is disposed in abutment with the glass bonding layer and the second cushioning sealing layer is disposed between the first cushioning sealing layer and the third cushioning sealing layer. 8. The method of claim 7,
Wherein the second cushioning sealing layer has a greater thermal expansion coefficient than the first cushioning sealing layer and has a smaller thermal expansion coefficient than the third cushioning sealing layer. 9. The method of claim 8,
Wherein the first outer case includes a first outer cover plate and a first outer support ring, and the first outer case and the first outer case include a first outer case and a second outer case disposed on the outer side of the sodium sulfur battery module and supporting the unit cell, A sodium electrode is inserted into the first outer support ring, the second outer casing includes a second outer cover plate and a second outer support ring, and a sulfur electrode is inserted into the second outer support ring. 10. The method of claim 9,
The sodium sulfur battery module includes a first end plate supported to abut against the first outer case, a second end plate abutting against the second outer case, a pressure end plate spaced apart from the first end plate, And an elastic member disposed between the first end plate and the pressurizing end plate,
A tie bar is provided so as to pass through the first end plate, the second end plate, and the pressurizing end plate.

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