Patent Description:
As a capacitor meeting uses where high energy density and high power density properties are required, attention has been recently paid to an accumulator device what is called a hybrid capacitor with the principles of electricity accumulation in the lithium ion secondary battery and the electric double layer capacitor combined. This accumulator device is an organic electrolyte capacitor having a negative electrode composed of a carbonaceous material capable of occluding and deoccluding lithium ions, by which a high energy density is achieved by lowering the potential thereof by causing lithium ions occluded and supported (hereinafter also referred to as "doped") in the carbonaceous material in advance by a chemical method or electrochemical method (see, for example, <CIT> and <CIT>).

As such accumulator devices, there are known that of a wound-type which has an electrode unit configured by winding an electrode stack, which is obtained by stacking a positive electrode and a negative electrode on each other through a separator capable of being impregnated with an electrolytic solution, from one end thereof, that of a laminated-type which has an electrode unit composed of an electrode stack obtained by alternately stacking a plurality of positive electrodes and a plurality of negative electrodes on each other through a separator capable of being impregnated with an electrolytic solution, and the like. In addition, as outer containers for housing the electrode unit, are known that of a metallic can shape (see <CIT>), that of a coin shape (see <CIT>), that composed of a laminate film having an aluminum layer as an intermediate layer (see <CIT>), and the like. Iron, steel or the like has been used as a metallic material forming the can-shaped outer container. However, aluminum or an aluminum alloy has also been recently used from the viewpoint of weight saving of the accumulator device.

It is also referred to <CIT> and <CIT>. <CIT> discloses a pouched lithium secondary battery, and <CIT> discloses an accumulator device.

However, when the outer container is formed by aluminum or an aluminum alloy in the above-described accumulator device, the following problems are caused.

When an electrode is doped with lithium ions from a lithium ion supply source in the outer container, fine lithium metal powder may suspend without being doped to adhere to an inner surface of the outer container in some cases. The fine lithium metal powder adhered to the inner surface of the outer container is easy to form an alloy with the aluminum forming the outer container, thereby causing a problem of forming the cause of corrosion of the outer container.

The present invention has been made on the basis of the foregoing circumstances and has as its object the provision of an accumulator device that can prevent aluminum forming an outer container from forming an alloy with lithium even when fine lithium metal powder is isolated from a lithium ion supply source to adhere to the outer container.

According to the present invention, there is provided an accumulator device as specified in claim <NUM>.

Such an accumulator device is suitable for use as a lithium ion capacitor.

According to the accumulator device of the present invention, the outer container is set to a positive potential, so that the aluminum or the aluminum alloy in the outer container can be prevented from forming an alloy with lithium even when fine lithium metal powder is isolated from the lithium ion supply source to adhere to the outer container.

The accumulator devices according to the present invention will hereinafter be described taking embodiments that they are embodied as a lithium ion capacitor as examples.

<FIG> is an explanatory sectional view illustrating the construction of a lithium ion capacitor according to an embodiment of the present invention.

This lithium ion capacitor is a wound-type lithium ion capacitor with a positive electrode and a negative electrode each having a band shape stacked and wound through a separator and has a cylindrical wound-type electrode unit <NUM>, an outer container <NUM> housing this electrode unit <NUM> and formed of aluminum or an aluminum alloy, and an electrolytic solution injected into this outer container <NUM> and containing a lithium salt.

<FIG> is an explanatory sectional view illustrating the construction of the wound-type electrode unit, and <FIG> is an explanatory view of an electrode stack forming the wound-type electrode unit, in which (a) is a plan view, and (b) is a sectional view taken along a longitudinal direction.

The electrode unit <NUM> is formed by cylindrically winding an electrode stack 10A, which is obtained by stacking a band-like positive electrode <NUM>, a band-like second separator <NUM> and a band-like negative electrode <NUM> in this order on a band-like first separator <NUM>, from one end thereof. Here, in the positive electrode <NUM> and the negative electrode <NUM>, respective electrode layers, which will be described subsequently, are arranged so as to oppose each other through the second separator <NUM>. In the illustrated embodiment, the electrode stack 10A is wound in such a manner that the negative electrode <NUM> is located inside. In addition, the first separator <NUM> and the second separator <NUM> are longer than the positive electrode <NUM> and the negative electrode <NUM>. In the electrode stack 10A, the positive electrode <NUM> is stacked on a central portion excluding one end portion 13a and the other end portion 13b of the first separator <NUM>, and the negative electrode <NUM> is stacked on a central portion excluding one end portion 14a and the other end portion 14b of the second separator <NUM>.

In the present invention, "the positive electrode" means an electrode from which an electric current flows out upon discharging and into which an electric current flows upon charging, and "the negative electrode" means an electrode into which an electric current flows upon discharging and from which an electric current flows out upon charging.

A lithium ion supply source <NUM> composed of filmy lithium metal is arranged between one end portion 13a of the first separator <NUM> and one end portion 14a of the second separator <NUM> in a state wound substantially one time in the electrode unit <NUM> so as not to come into direct contact with the positive electrode <NUM> and the negative electrode <NUM>. In addition, a lithium ion supply source <NUM> composed of filmy lithium metal is arranged between the other end portion 13b of the first separator <NUM> and the other end portion 14b of the second separator <NUM> in a state wound substantially one time in the electrode unit <NUM> so as not to come into direct contact with the positive electrode <NUM> and the negative electrode <NUM>.

As illustrated in <FIG>, two tapes <NUM> having a pressure-sensitive adhesive layer on one surfaces thereof are provided on an outer peripheral surface of the electrode unit <NUM>, i.e., an outer surface of the other end portion 13b of the first separator <NUM>, for fixing the electrode unit <NUM>. By providing such tapes <NUM>, it is easy to house the electrode unit <NUM> into the outer container <NUM>, and assembly workability of the lithium ion capacitor can be improved.

The negative electrode <NUM> is obtained by forming an electrode layer 12b containing a negative electrode active material on at least one surface of a band-like negative electrode current collector 12a as illustrated in <FIG>. In the illustrated embodiment, the electrode layer 12b is formed so as to cover the surface of a portion excluding one side edge portion 12e to be located near to one end wall portion <NUM> of the outer container <NUM> in the negative electrode current collector 12a, and the surface of one side edge portion 12e of the negative electrode current collector 12a is in an exposed state.

On the other hand, the positive electrode <NUM> is obtained by forming an electrode layer 11b containing a positive electrode active material on at least one surface of a band-like positive electrode current collector 11a as illustrated in <FIG>. In the illustrated embodiment, the electrode layer 11b is formed so as to cover the surface of a portion excluding the other side edge portion 11e to be located near to the other end wall portion <NUM> of the outer container <NUM> in the positive electrode current collector 11a, and the surface of the other side edge portion 11e of the positive electrode current collector 11a is in an exposed state.

In the electrode stack 10A, the positive electrode <NUM> is stacked on the first separator <NUM> in such a manner that the other side edge portion 11e of the positive electrode current collector 11a projects from the other side edge of the first separator <NUM>, and the negative electrode <NUM> is stacked on the second separator <NUM> in such a manner that one side edge portion 12e of the negative electrode current collector 12a projects from one side edge of the second separator <NUM>. In the electrode unit <NUM>, the other side edge portion 11e of the positive electrode current collector 11a, which projects from the other side edge of the first separator <NUM>, projects form the other end (lower end in <FIG>) of the electrode unit <NUM> and is folded inward. On the other hand, one side edge portion 12e of the positive electrode current collector 12a, which projects from one side edge of the second separator <NUM>, projects form one end (upper end in <FIG>) of the electrode unit <NUM> and is folded inward.

The positive electrode current collector 11a and the negative electrode current collector 12a (hereinafter, both may also be referred to as "electrode current collector" collectively) are each composed of a porous material having pores passing through from a front surface to a back surface. Examples of the form of such a porous material include expanded metal, punching metal, metal net, foam and porous foil having through-holes formed by etching.

The shape of the pores in the electrode current collector may be suitably set to any form such as a circle or a rectangle. The thickness of the electrode current collector is preferably <NUM> to <NUM> from the viewpoints of strength and weight saving.

The porosity of the electrode current collector is generally <NUM> to <NUM>%, preferably <NUM> to <NUM>%. Here, the porosity is calculated out according to [<NUM> - (Mass of electrode current collector/True specific gravity of electrode current collector)/(Apparent volume of electrode current collector)] x <NUM>.

Various materials generally used in applications such as organic electrolyte batteries may be used as the material of the electrode current collector. Specific examples of the material for the negative electrode current collector 12a include stainless steel, copper and nickel, and examples of the material for the positive electrode current collector 11a include aluminum and stainless steel.

Such a porous material is used as the electrode current collector, whereby lithium ions discharged from the lithium ion supply sources <NUM> and <NUM> freely moves between the respective electrodes through the pores in the electrode current collector, so that the electrode layers 12b and 11b in the negative electrode <NUM> and the positive electrode <NUM> can be doped with the lithium ion.

In the present invention, it is preferable that at least part of the pores in the electrode current collector are closed with a conductive material hard to fall off, and the electrode layer 11b or 12b is formed on one surface of the electrode current collector in this state. Productivity of the electrode can thereby be improved, and lowering of reliability of the lithium ion capacitor, which is caused by falling-off of the electrode layer 11b or 12b from the electrode current collector, can be prevented or inhibited.

The thickness (total thickness of the electrode current collector and the electrode layer) of each electrode is made small, whereby a higher power density can be achieved.

The shape and number of the pores in the electrode current collector may be suitably set in such a manner that a lithium ion in an electrolytic solution, which will be described subsequently, can move between front and back surfaces of the electrode without being interrupted by the current collector, and the pores are easily closed by the conductive material.

The electrode layer 12b in the negative electrode <NUM> contains a negative electrode active material capable of reversibly supporting a lithium ion.

As the negative electrode active material making up the electrode layer 12b, may be suitably used, for example, graphite, non-graphitizing carbon or a polyacenic organic semiconductor (hereinafter referred to as "PAS") which is a heat-treated aromatic condensed polymer having a polyacenic skeleton structure with an atomic ratio (hereinafter referred to as "H/C") of hydrogen atoms/carbon atoms of <NUM> to <NUM>.

In the lithium ion capacitor according to an embodiment of the present invention, the electrode layer 12b in the negative electrode <NUM> is formed on the negative electrode current collector 12a with a material containing the above-described negative electrode active material such as the carbonaceous material or PAS. However, a forming process thereof is not specified, and any publicly known process may be utilized. Specifically, a slurry with negative electrode active material powder, a binder and optional conductive powder dispersed in an aqueous medium or organic solvent is prepared, and this slurry is applied to the surface of the negative electrode current collector 12a and dried, or the slurry is formed into a sheet in advance, and the resultant formed product is stuck on the surface of the negative electrode current collector 12a, whereby the electrode layer 12b can be formed.

Here, examples of the binder used in the preparation of the slurry include rubber binders such as SBR, fluorine-containing resins such as polyethylene tetrafluoride and polyvinylidene fluoride, and thermoplastic resins such as polypropylene and polyethylene. Among these, the fluorine-containing resins are preferred as the binder, and a fluorine-containing resin having an atomic ratio (hereinafter referred to as "F/C") of fluorine atoms/carbon atoms of not lower than <NUM> and lower than <NUM> is particularly preferably used, with a fluorine-containing resin having F/C of not lower than <NUM> and lower than <NUM> being further preferred.

The amount of the binder used is <NUM> to <NUM>% by mass, preferably <NUM> to <NUM>% by mass based on the negative electrode active material though it varies according to the kind of the negative electrode active material and the shape of the resulting electrode.

Examples of the conductive material optionally used include acetylene black, Ketjen Black (trademark), graphite and metal powder. The amount of the conductive material used is preferably <NUM> to <NUM>% by mass in terms of a proportion based on the negative electrode active material though it varies according to the electric conductivity of the negative electrode active material and the shape of the resulting electrode.

When the electrode layer 12b is formed by applying the slurry to the negative electrode current collector 12a, a primer layer of a conductive material is preferably formed on a surface to be coated of the negative electrode current collector 12a. If the slurry is directly applied to the surface of the negative electrode current collector 12a, the slurry may be leaked out of the pores in the negative electrode current collector 12a because the negative electrode current collector is a porous material, or it may be difficult in some cases to form an electrode layer 12b having a uniform thickness because the surface of the negative electrode current collector 12a is irregular. The primer layer is formed on the surface of the negative electrode current collector 12a, whereby the pores are closed by the primer layer, and a smooth surface to be coated is formed, so that the slurry is easily applied, and an electrode layer 12b having a uniform thickness can be formed.

The thickness of the electrode layer 12b in the negative electrode <NUM> is designed with it balanced with the thickness of the electrode layer 11b in the positive electrode <NUM> in such a manner that a sufficient energy density is surely attained in the resulting lithium ion capacitor. However, when the electrode layer is formed on one surface of the negative electrode current collector 12a, the thickness is generally <NUM> to <NUM>, preferably <NUM> to <NUM> from the viewpoints of the power density and energy density of the resulting lithium ion capacitor and industrial productivity.

The electrode layer 11b in the positive electrode <NUM> contains a positive electrode active material capable of reversibly supporting a lithium ion and/or an anion such as, for example, tetrafluoroborate.

As the positive electrode active material making up the electrode layer 11b, may be suitably used, for example, active carbon, a conductive polymer or PAS which is a heat-treated aromatic condensed polymer having a polyacenic skeleton structure with H/C of <NUM> to <NUM>.

The electrode layer 11b in the positive electrode <NUM> can be formed according to the same process as in the electrode layer 12b in the negative electrode <NUM>.

As the first separator <NUM> and the second separator <NUM>, may be used, for example, a porous material which is durable against an electrolytic solution and the positive electrode active material or the negative electrode active material, has open cells or connected pores capable of being impregnated with the electrolytic solution and is low in electric conductivity.

As materials for the first separator <NUM> and the second separator <NUM>, may be used cellulose (paper), cellulose/rayon, polyethylene, polypropylene and other publicly known materials. Among these, cellulose (paper) is preferred from the viewpoints of durability and profitability.

No particular limitation is imposed on the thickness of the first separator <NUM> and the second separator <NUM>. However, the thickness is preferably generally about <NUM> to <NUM>.

The lithium ion supply source <NUM> or <NUM> is preferably bonded under pressure to or stacked on a metallic current collector (hereinafter referred to as "the lithium electrode current collector") 15a or 16a as illustrated in <FIG>. In such a structure, a lithium electrode terminal (not illustrated) is provided on the lithium electrode current collector 15a or 16a, or one side edge portion located near to one end wall portion <NUM> in the lithium electrode current collector 15a or 16a is provided so as to project from respective one side edge portions of the first separator <NUM> and the second separator <NUM>, whereby such a lithium ion supply source can be electrically connected to a negative electrode terminal <NUM>.

As this lithium electrode current collector 15a or 16a, that having a porous structure like the electrode current collector is preferably used in such a manner that lithium metal making up the lithium ion supply source <NUM> or <NUM> is easily bonded under pressure to or vapor-deposited on the current collector, and a lithium ion passes through as needed. In addition, the material for the lithium electrode current collector 15a or 16a used is preferably that does not react with the lithium ion supply source <NUM> or <NUM>, such as stainless steel.

When a conductive porous material such as stainless steel mesh is used as the lithium electrode current collectors 15a and 16a, at least a part of lithium metal making up the lithium ion supply sources <NUM> and <NUM>, particularly, at least <NUM>% by mass thereof is preferably embedded in pores in the lithium electrode current collectors 15a and 16a, whereby spaces produced between electrodes by loss of lithium metal lessen even after lithium ions are supported in the negative electrode <NUM>, and reliability of the resulting lithium ion capacitor can be more surely retained.

The thickness of the lithium electrode current collectors 15a and 16a is preferably about <NUM> to <NUM>.

The thickness of the lithium metal bonded under pressure to the lithium electrode current collectors 15a and 16a is suitably determined in view of the amount of lithium ions supported in the negative electrode <NUM> in advance, but is generally <NUM> to <NUM>, preferably about <NUM> to <NUM>.

The amounts of the lithium metal making up the lithium ion supply sources <NUM> and <NUM> are preferably set to an amount of lithium ions to be doped in such a manner that the potential of the positive electrode <NUM> after the positive electrode <NUM> and the negative electrode <NUM> are short-circuited becomes <NUM> V or lower. In addition, the amount of the lithium metal making up the lithium ion supply source <NUM> and the amount of the lithium metal making up the lithium ion supply source <NUM> are preferably distributed in such a manner that, for example, the negative electrode <NUM> is doped with lithium ions from both sides of the outer peripheral surface and the inner peripheral surface in the electrode unit <NUM> as uniformly and quickly as possible.

No particular limitation is imposed on the material of a base member of the tape <NUM> so far as it has durability against the electrolytic solution and does not adversely affect the resulting lithium ion capacitor. However, for example, polyimide or polypropylene is preferably used.

The tape <NUM> preferably has a thickness of about <NUM> to <NUM> and a width of about <NUM> to <NUM> because the electrode unit <NUM> can be stably fixed, and workability is also improved.

The tape <NUM> may be provided so as to be wound at least once or less than once around the electrode unit <NUM>.

The outer container <NUM> is constructed by integrally forming one end wall portion <NUM> and the other end wall portion <NUM>, which are each in the form of a disc, on both ends of a cylindrical peripheral wall portion <NUM>. Here, "integrally" also includes a case where these portions are integrally formed through respective joints by welding or the like. In the illustrated embodiment, one end wall portion <NUM> is integrally formed by being welded to a peripheral edge of the peripheral wall portion <NUM> at one end thereof. The other end wall portion <NUM> is integrally formed continuously with the other end of the peripheral wall portion <NUM> by integral molding.

The electrode unit <NUM> is arranged in the outer container <NUM> along an axial direction of the outer container <NUM> in such a manner that one end of the electrode unit <NUM>, i.e., one side edge portion 12e of the negative electrode current collector 12a, is located near to one end wall portion <NUM>.

A positive electrode terminal <NUM> and a negative electrode terminal <NUM> of a metallic nut type having a spiral inner peripheral surface or a hollow-columnar metallic bolt type having a spiral outer peripheral surface are provided at one end wall portion <NUM> of the outer container <NUM> separately from each other so as to project from an outer surface of said one end wall portion <NUM>. Specifically, the positive electrode terminal <NUM> is fixed to the outer surface of the one end wall portion <NUM> of the outer container <NUM> at a proximal end portion thereof and is provided in an electrically connected state. On the other hand, the negative electrode terminal <NUM> is provided so as to extend through the one end wall portion <NUM> of the outer container <NUM> in a thickness-wise direction, and a gasket <NUM> composed of an insulating material is provided between the negative electrode terminal <NUM> and the one end wall portion <NUM> at a portion extending through the one end wall portion <NUM> in the negative electrode terminal <NUM>, whereby the negative electrode terminal <NUM> is in an electrically insulated state to the one end wall portion <NUM>.

The specific dimensions of the outer container <NUM> are set according to the dimensions of the electrode unit <NUM> housed in the interior thereof.

As the positive electrode terminal <NUM>, may be suitably used that composed of aluminum. On the other hand, as the negative electrode terminal <NUM>, may be suitably used that obtained by plating the surface of a base composed of copper with nickel.

The outside diameter of each of the positive electrode terminal <NUM> and the negative electrode terminal <NUM> is, for example, <NUM> to <NUM>.

The projected height from one end wall portion <NUM> in each of the positive electrode terminal <NUM> and the negative electrode terminal <NUM> is, for example, <NUM> to <NUM>.

On one end of the electrode unit <NUM>, a disc-like negative electrode current collector plate <NUM> made of a metal is provided with it fixed by a fixing member <NUM> composed of an insulating resin in a state welded to one side edge portion 12e of the negative electrode current collector 12a by, for example, resistance welding and electrically connected thereto, a negative electrode lead wire <NUM> is electrically connected to this negative electrode current collector plate <NUM>, and this negative electrode lead wire <NUM> is further electrically connected to the negative electrode terminal <NUM>, whereby the negative electrode terminal <NUM> is electrically connected to one side edge portion 12e of the negative electrode current collector 12a through the negative electrode current collector plate <NUM> and the negative electrode lead wire <NUM>.

On the other end of the electrode unit <NUM>, a disc-like positive electrode current collector plate <NUM> made of a metal is arranged in a state welded to the other side edge portion 11e of the positive electrode current collector 11a by, for example, resistance welding and electrically connected thereto, and this positive electrode current collector plate <NUM> is further welded to an inner surface of the other end wall portion <NUM> of the outer container <NUM> by, for example, resistance welding and electrically connected thereto, whereby the outer container <NUM> is set to a positive potential, and the positive electrode terminal <NUM> is electrically connected to the other side edge portion 11e of the positive electrode current collector 11a through the positive electrode current collector plate <NUM> and the outer container <NUM> (the other end wall portion <NUM>, the peripheral wall portion <NUM> and the one end wall portion <NUM>).

As the positive electrode current collector plate <NUM>, may be used that composed of aluminum, and as the negative electrode current collector plate <NUM>, may be used that obtained by plating the surface of a base composed of copper with nickel.

The thickness of each of the positive electrode current collector plate <NUM> and the negative electrode current collector plate <NUM> is, for example, <NUM> to <NUM>.

An electrolytic solution composed of an aprotic organic solvent electrolyte solution of a lithium salt is injected into the outer container <NUM>.

As the lithium salt making up the electrolyte, may be used any salt so far as it can transfer lithium ions, does not undergo electrolysis even under a high voltage and can cause the lithium ions to stably exist therein, and specific examples thereof include LiClO<NUM>, LiAsF<NUM>, LiBF<NUM>, LiPF<NUM> and Li(C<NUM>F<NUM>SO<NUM>)<NUM>N.

Specific examples of the aprotic organic solvent include ethylene carbonate, propylene carbonate, dimethyl carbonate, diethyl carbonate, γ-butyrolactone, acetonitrile, dimethoxyethane, tetrahydrofuran, dioxolane, methylene chloride and sulfolane. These aprotic organic solvents may be used either singly or in any combination thereof.

The electrolytic solution is prepared by mixing the above-described electrolyte and solvent in a fully dehydrated state, and the concentration of the electrolyte in the electrolytic solution is preferably at least <NUM> mol/L, more preferably <NUM> to <NUM> mol/L for the purpose of making an internal resistance by the electrolytic solution low.

The above-described lithium ion capacitor is obtained by, for example, providing an outer container material with the other end wall portion <NUM> integrally formed on the other end of a cylindrical peripheral wall portion <NUM>, arranging the electrode unit <NUM> into this outer container material, conducting a necessary electrically connecting operation, then welding a disc-like one end wall member provided with the positive electrode terminal <NUM> and the negative electrode terminal <NUM> to one end of the outer container material to integrate them, thereby forming the outer container <NUM>, and further injecting the electrolytic solution into the outer container <NUM>.

In the lithium ion capacitor produced in such a manner, the electrolytic solution capable of supplying a lithium ion is injected into the outer container <NUM>, so that the negative electrode <NUM> and/or the positive electrode <NUM> is doped with a lithium ion discharged from the lithium ion supply source <NUM> or <NUM> by electrochemical contact of the negative electrode <NUM> and/or the positive electrode <NUM> with the lithium ion supply source <NUM> or <NUM> when the capacitor is left to stand for a proper period of time.

In addition, the electrode stack 10A is wound in a state that the lithium ion supply sources <NUM> and <NUM> have been arranged between the first separator <NUM> and the second separator <NUM> in advance, whereby the preparation of the wound electrode unit <NUM> and the arrangement of the lithium ion supply sources <NUM> and <NUM> can be conducted in the same step, so that higher productivity is achieved.

According to the above-described lithium ion capacitor, the outer container is set to a positive potential, so that the aluminum forming the outer container <NUM> can be prevented from forming an alloy with lithium even when fine lithium metal powder is isolated from the lithium ion supply source <NUM> or <NUM> to adhere to an inner surface of the outer container <NUM>.

<FIG> is an explanatory sectional view illustrating the construction of a lithium ion capacitor according to another embodiment of the present invention.

This lithium ion capacitor is a wound-type lithium ion capacitor with a positive electrode and a negative electrode each having a band shape stacked and wound through a separator and has a wound-type electrode unit <NUM> of the construction illustrated in <FIG>, an outer container <NUM> housing this electrode unit <NUM> and an electrolytic solution injected into this outer container <NUM> and containing a lithium salt.

In the outer container <NUM> in this embodiment, a disc-like other end wall portion <NUM> composed of aluminum or an aluminum alloy is integrally formed on the other end of a cylindrical peripheral wall portion <NUM> composed of aluminum or an aluminum alloy, and one end wall portion <NUM> composed of an insulating resin is arranged in an opening of one end of the peripheral wall portion <NUM> so as to close the interior of the outer container <NUM> by a gasket <NUM>. The electrode unit <NUM> is arranged in the outer container <NUM> along an axial direction of the outer container <NUM> in such a manner that one end of the electrode unit <NUM>, i.e., one side edge portion 12e of the negative electrode current collector 12a, is located near to the one end wall portion <NUM>.

A positive electrode terminal <NUM> and a negative electrode terminal <NUM> of a metallic nut type having a spiral inner peripheral surface or a hollow-columnar metallic bolt type having a spiral outer peripheral surface are provided at the one end wall portion <NUM> of the outer container <NUM> separately from each other so as to extend through said one end wall portion <NUM> and project from an outer surface thereof.

On one end (upper end in <FIG>) of the electrode unit <NUM>, a disc-like negative electrode current collector plate <NUM> made of a metal is provided with it fixed by a fixing member <NUM> composed of an insulating resin in a state welded to one side edge portion 12e of the negative electrode current collector 12a by, for example, a welding method such as heat radiation welding (laser welding), ultrasonic welding or resistance welding and electrically connected thereto, a negative electrode lead wire <NUM> is electrically connected to this negative electrode current collector plate <NUM>, and this negative electrode lead wire <NUM> is further electrically connected to the negative electrode terminal <NUM>, whereby the negative electrode terminal <NUM> is electrically connected to one side edge portion 12e of the negative electrode current collector 12a through the negative electrode current collector plate <NUM> and the negative electrode lead wire <NUM>.

On the other end of the electrode unit <NUM>, a disc-like positive electrode current collector plate <NUM> made of a metal is arranged in a state welded to the other side edge portion 11e of the positive electrode current collector 11a by, for example, resistance welding and electrically connected thereto, a positive electrode lead wire <NUM> is electrically connected to this positive electrode current collector plate <NUM>, and this positive electrode lead wire <NUM> is further electrically connected to the positive electrode terminal <NUM>, whereby the positive electrode terminal <NUM> is electrically connected to the other side edge portion 11e of the positive electrode current collector 11a through the positive electrode current collector plate <NUM> and the positive electrode lead wire <NUM>.

In addition, the positive electrode current collector plate <NUM> is welded to an inner surface of the other end wall portion <NUM> of the outer container <NUM> by, for example, resistance welding and electrically connected thereto, whereby the portions formed of aluminum or the aluminum alloy, specifically, the peripheral wall portion <NUM> and the other end wall portion <NUM>, in the outer container <NUM> are set to a positive potential.

As the insulating resin forming one end wall portion <NUM> in the outer container <NUM>, may be used poly(phenylene sulfide) or the like.

The dimensions and materials of the positive electrode terminal <NUM>, the negative electrode terminal <NUM>, the positive electrode current collector plate <NUM> and the negative electrode current collector plate <NUM>, and the electrolytic solution injected into the outer container <NUM> are the same as in the lithium ion capacitor illustrated in <FIG>.

According to such a lithium ion capacitor, the peripheral wall portion <NUM> and the other end wall portion <NUM> in the outer container <NUM> are set to a positive potential, so that the aluminum forming the peripheral wall portion <NUM> and the other end wall portion <NUM> in the outer container <NUM> can be prevented from forming an alloy with lithium even when fine lithium metal powder is isolated from the lithium ion supply source <NUM> or <NUM> to adhere to inner surfaces of the peripheral wall portion <NUM> and the other end wall portion <NUM> in the outer container <NUM>.

Although the embodiments of the present invention about the lithium ion capacitors have been described above, the present invention is not limited to the above-described embodiments.

For example, as the outer container, there may be used those of various structures so far as it is formed of aluminum or an aluminum alloy.

Further, the electrically connected structure for setting the portion formed of aluminum or the aluminum alloy in the outer container to a positive potential is not limited to the above-described embodiments, and any other proper structures may be adopted.

Furthermore, the present invention is not limited to the lithium ion capacitor and may also be applied to accumulator devices such as a lithium ion secondary battery.

Claim 1:
An accumulator device comprising an outer container (<NUM>) having a tube structure, an electrode unit (<NUM>) arranged in the outer container (<NUM>), a lithium ion supply source (<NUM>, <NUM>) arranged in the outer container (<NUM>), and an electrolytic solution injected into the outer container (<NUM>) and containing a lithium salt, wherein
the electrode unit (<NUM>) is formed by cylindrically winding an electrode stack (10A), which is obtained by stacking a band-like positive electrode (<NUM>), a band-like second separator (<NUM>) and a band-like negative electrode (<NUM>) in this order on a band-like first separator (<NUM>), from one end thereof, and
the positive electrode (<NUM>) comprises a positive electrode current collector (11a) and an electrode layer (11b) containing a positive electrode active material,
the negative electrode (<NUM>) is doped with a lithium ion by electrochemical contact of the lithium ion supply source (<NUM>, <NUM>) with the negative electrode (<NUM>),
the electrode layer (11b) containing the positive electrode active material is formed on at least one surface of the positive electrode current collector (11a) so as to cover the surface of a portion excluding a side edge portion (11e) of the positive electrode current collector (11a), and
the side edge portion (11e) of the positive electrode current collector (11a) is electrically connected to the outer container (<NUM>), whereby the outer container (<NUM>) is set to a positive potential,
characterized in that
the lithium ion supply source (<NUM>, <NUM>) is composed of filmy lithium metal, and
the outer container (<NUM>) is formed of aluminum or aluminum alloy.