Metal working – Method of mechanical manufacture – Electrical device making
Reexamination Certificate
2001-01-23
2004-06-29
Weiner, Laura (Department: 1745)
Metal working
Method of mechanical manufacture
Electrical device making
C429S300000, C429S303000, C429S162000, C429S163000, C429S185000, C429S233000, C029S623400, C029S623100
Reexamination Certificate
active
06755873
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to a gel electrolyte battery having a gel electrolyte.
2. Description of Related Art
As a power source for a portable electronic equipment, such as a portable telephone set, a video camera or a notebook personal computer, the importance attached to batteries is increasing. For reducing the size and weight of the electronic equipment, such a battery is desired which not only is of a large capacity but also is lightweight and space-saving. Viewed in this light, a lithium battery, having a high energy density and high output density, is suited very much. A lithium battery, employing a carbon material as a negative electrode material, has an average discharge voltage of not lower than 3.7 V and undergoes lesser cyclic deterioration during charging/discharging, so that it has a merit that a high energy density can readily be realized.
The lithium battery is desired to exhibit flexibility and shape freedom, and lithium batteries of various shapes, such as a sheet battery of thin thickness and large area, or a card battery of a thin thickness and a small area, are also desired. However, in the conventional technique of enclosing a battery device comprised of positive and negative electrodes and an electrolytic solution within an exterior metallic can, it is difficult to fabricate batteries of variable shapes such as those depicted above. Moreover, the use of the electrolytic solution tends to complicate the manufacturing process or renders it necessary to provide leakage-resistant means.
For overcoming the above-mentioned problems, such battery is being envisaged which uses a solid electrolyte employing an electrically conductive organic high polymer material or organic ceramics, or a gelated solid electrolyte having an electrolytic solution impregnated into a matrix polymer, referred to below as a gel electrolyte. With the solid electrolyte battery, employing the solid electrolyte, or with the gel electrolyte battery, employing the gel electrolyte, in which the electrolyte is immobilized, it is possible to fabricate the battery using a film-shaped exterior material to a reduced thickness, thus providing a higher energy density than is possible with the conventional battery.
However, the gel electrolyte battery has a deficiency that, since the electrolytic solution is held in the matrix polymer, the electrolytic solution cannot sufficiently seep into the layer of the active materials of the electrodes. As a result, lithium ions cannot be migrated sufficiently across the electrodes, with the result that a desired battery capacity cannot be achieved.
Moreover, in a gel electrolyte battery, the solvent in the gel electrolyte tends to be decomposed at the time of activation charging to evolve gases, with the result that local gaps are produced between the layer of the active material and the gel electrolyte to impair the adhesion between the layers of the active materials of the electrodes and the gel electrolyte. If such gap is produced between the layer of the active material and the gel electrolyte, the battery in storage is deteriorated appreciably in battery voltage to prove a reject to lower the production yield. Moreover, lithium ion migration across the electrodes is retarded to render it extremely difficult to realize the desired battery capacity.
SUMMARY OF THE INVENTION
It is therefore an object of the present invention to provide a method for the preparation of a non-aqueous electrolyte battery in which adhesion between the layers of the active materials of the electrodes and the gel electrolyte is improved and kept to prevent voltage troubles from occurring to improve the production yield to enable the fabrication of a non-aqueous electrolyte battery having a high battery capacity.
In one aspect, the present invention provides a method for preparation of a gel electrolyte battery in which a battery device is accommodated in an exterior material of a laminated film and sealed therein by heat fusion, in which the method includes a battery device preparation step of layering a positive electrode and a negative electrode via a gel electrolyte to form the battery device, an accommodating step of accommodating the battery device from the battery device preparation step in the laminated film and a heating step of heating the battery device, accommodated in the laminated film in the accommodating step, under a pressured state.
In another aspect, the present invention provides a method for preparation of a gel electrolyte battery in which a battery device is accommodated in an exterior material of a laminated film and sealed therein by heat fusion, in which the method includes a battery device preparation step of layering a positive electrode and a negative electrode via a gel electrolyte to form the battery device, an accommodating step of accommodating the battery device from the battery device preparation step in the laminated film, a charging step of charging the battery device accommodated in the laminated film in the accommodating step, a discharging step of discharging the battery device following the charging step and a heating step of heating the battery device from the discharging step under a pressured state.
According to the present invention, the seeping of a gel electrolyte into the electrode is accelerated by applying pressuring and heating to a battery device provided with the gel electrolyte. Since the pressuring and heating are applied to the battery device, the adhesion between the gel electrolyte layer and a layer of the active material of the electrode is restored to improve the production yield, even if a gap is produced between the layer of the active material of the electrode and the gel electrolyte due to gases evolved in activation charging. As a result, the adhesion between the layer of the active material of the electrode and the gel electrolyte is improved to provide a gel electrolyte battery having a high capacity and superior charging/discharging characteristics and operational reliability.
REFERENCES:
patent: 6399241 (2002-06-01), Hara et al.
patent: 6428934 (2002-08-01), Hatazawa et al.
Mizutani Toru
Ono Takashi
Shida Masayuki
Sonnenschein Nath & Rosenthal LLP
Sony Corporation
Weiner Laura
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