Chemistry: electrical current producing apparatus – product – and – Current producing cell – elements – subcombinations and... – Include electrolyte chemically specified and method
Reexamination Certificate
1999-04-30
2001-03-13
Chaney, Carol (Department: 1745)
Chemistry: electrical current producing apparatus, product, and
Current producing cell, elements, subcombinations and...
Include electrolyte chemically specified and method
C429S306000, C429S309000, C429S212000
Reexamination Certificate
active
06200707
ABSTRACT:
TECHNICAL FIELD
The present invention relates to electrochemical devices, and molded solid electrolytes and molded electrodes used in the electrochemical devices. More particularly, the present invention relates to molded articles holding therein an electrolyte material and electrode material by adding a polymer compound to these electrochemical device constituting materials, and an electrochemical device fabricated using these molded articles.
BACKGROUND ART
Electrochemical devices such as battery cells comprise an electrolyte layer where ion transfer takes place and an electrode layer where electron transfers to ions takes place together with the ion transfer. Polymer compounds are added to the electrolyte layer and electrode layer for the following purposes.
1) Addition to the Electrolyte Layer
Since electrolytes are usually liquid with a supporting salt dissolved in a solvent, and hence require a container for containing the liquid, electrochemical devices using such electrolytes are difficult to make smaller and thinner. To solve this problem, researches are being conducted on all-solid state electrochemical devices using solid electrolytes in place of traditional liquid electrolytes.
Among others, lithium batteries have been researched vigorously as the type of battery that can obtain high energy density since lithium is a substance with a light atomic weight and large ionization energy, and nowadays, lithium batteries are extensively used as power sources for portable appliances.
On the other hand, with the widespread use of lithium batteries, concern has been growing in recent years about the safety of batteries because of increased internal energy associated with the increase in the amount of active material content and also because of increasing amounts of organic solvents which are flammable materials used as electrolytes.
As a method to ensure the safety of lithium batteries, it is extremely effective to use solid electrolytes, which are nonflammable, in place of organic solvent electrolytes. It is therefore important to use solid electrolytes for lithium batteries in order to ensure high safety levels as well as to achieve the earlier noted small and thin construction.
Materials such as lithium halide, lithium nitride, lithium oxygen acid salt, or their derivatives, are known as materials for lithium ion conductive solid electrolytes used in such batteries. Amorphous solid electrolytes of lithium ion conductive sulfides such as Li
2
S-SiS
2
, Li
2
S-P
2
S
5
, Li
2
S-B
2
S
3
, and the like, and lithium ion conductive solid electrolytes formed from such glasses doped with a lithium halide such as LiI or a lithium salt such as Li
3
PO
4
, are known to exhibit high ionic conductivity of the order of 10
−4
to 10
−3
S/cm or higher.
As compared with these inorganic solid electrolytes, a polymer solid electrolyte comprising an organic substance is obtained from a solution of a lithium salt and an organic polymer compound by allowing the solvent to evaporate. This polymer solid electrolyte has excellent workability compared with inorganic solid electrolytes, in that it can be easily formed into a thin film and in that the resulting solid electrolyte thin film has flexibility.
As a solid electrolyte having flexibility or rubber elasticity, there has recently been proposed a novel solid electrolyte, named the “polymer in salts” electrolyte, that comprises an inorganic salt and a polymer and has lithium ion conductivity of extremely high density compared with the above-described polymer solid electrolyte (C. A. Angell, C. Liu, and E. Sanchez, Nature, vol. 362, (1993) 137).
In electrochemical devices using liquid electrolytes also, a porous polymer compound is usually used as a separator in the electrolyte layer. The separator may mechanically prevent an electrical contact between the electrodes, and is required not only to have excellent liquid retentivity for retaining the liquid electrolyte and be chemically stable in the electrochemical device, but also to be electrochemically stable since it is used in contact with the electrodes.
2) Addition to the Electrode Layer
An electrode is formed by molding an electrode active material and contacting the same with a current collector. If the electrode active material is simply molded by a pressure molding process, the cohesive force working between electrode active material particles primarily depends only on van der Waals forces. However, since conventional electrochemical devices use liquid as the electrolyte, if the molded electrode formed by the pressure molding process alone is immersed in the liquid electrolyte, liquid molecules are adsorbed onto the surfaces of the electrode active material particles, as a result of which the cohesive force working between the active material particles decreases and active material particles drop off the molded electrode into the liquid electrolyte, resulting in that the shape of the molded electrode cannot be retained. To increase the formability of the electrode, usually a polymer compound is added as a binding agent to the molded electrode.
To the electrolyte layer or electrode layer of an electrochemical device, polymer compounds are added for the above-described purposes, but the prior art techniques have had the following problems.
The inorganic solid electrolytes described above are ceramic or glass, and in battery cell applications, the materials are usually used in the form of pellets obtained by pressure molding pulverized solid electrolyte powder. However, since the pellets are hard and brittle, there has been the problem that they lack workability and are difficult to be made thin.
The organic solid electrolytes, on the other hand, have low ionic conductivity of the order of 10
−4
S/cm or less at room temperature, which has not been sufficient for practical lithium cell electrolytes. To solve this problem, it has been proposed to make a polymer solid electrolyte with increased ionic conductivity by adding a plasticizer. However, plasticizers are flammable by their nature, and the addition of a plasticizer in turn gives rise to such problems as decreased lithium ion transport number or decreased reactivity with the lithium anode. Furthermore, whether a plasticizer is added or not, it is hard to say that these organic solid electrolytes have sufficient performance as lithium battery electrolytes.
Further, most of the solid electrolytes generally known as the “polymer in salt” electrolyte have low ionic conductivity, of the order of 10
−4
S/cm or less, which cannot be said to be sufficient for lithium battery electrolytes. If an ambient temperature molten salt such as AlCl
3
-LiBr-LiClO
4
is used as the inorganic salt, high ionic conductivity can be obtained, but this in turn tends to cause an electrochemical reduction of aluminum and, therefore, cannot be said to be suitable for lithium cell electrolytes.
As earlier described, the molded electrode is constituted by a mixture, which is prepared by mixing a polymer compound as a binder into the electrode active material. The polymer compound is usually an electrically insulating substance and tends to interfere with the ion transfer, thus interfering with the electrochemical reaction occurring at the electrode/electrolyte interface and also the dispersion of ions within the electrode. If the mixing ratio of the polymer compound is increased to improve the formability, there arises the problem that the operating characteristics of the electrochemical device tend to drop.
Further, the molded electrode is formed by mixing in a dispersing medium a mixture comprising an electrode active material, a binder, and an electron conductive material added if necessary to increase the electron conductivity within the electrode, and by loading or coating a current collector with the resulting slurry and allowing the dispersing medium to evaporate. To enhance the coating or loading properties of the slurry, it is desirable that the polymer compound used as the binder be soluble in the dispersing medium used.
When a sol
Iwamoto Kazuya
Kondo Shigeo
Masaka Fusazumi
Takada Kazunori
Takeuchi Yasumasa
Akin Gump Strauss Hauer & Feld L.L.P.
Chaney Carol
Matsushita Electric - Industrial Co., Ltd.
Ruthkosky Mark
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