JPH08162374A - Electrical energy storage body - Google Patents

Abstract

PURPOSE: To prolong the charge-discharge cycle life of an electrical energy storage body by a method wherein at least a part of the electrode material of the electrical energy storage body is formed of material which contains manganese oxide or double oxide, wherein the electrical energy storage body is composed of at least two electrodes which confront each other and electrolyte. CONSTITUTION: Mixed powder composed of oxide which contains manganese dioxide and carbon added so as to make the mixed powder conductive is kneaded well with butyl carbitol acetate.α-terpineol into paste, and an electrode material 2 is formed out of the paste. The electrode material 2 is printed on a Ti electrode board 1, burned, and fixed. Then, the electrode boards 1 each provided with the fixed electrode material 2 are made to confront each other, and a separator 3 of glass fiber is inserted between the electrode material 2. Then, the opposed electrode boards 1 are fixed with an insulating seal 7 of rubber, adhesive agent, or the like, and then electrolyte solution 5 is poured through an electrolyte solution inlet 5. By this setup, an electrical energy storage body excellent in performance can be obtained at a low cost without using rate metal.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to electric energy storage devices such as batteries and electric double layer capacitors.

[0002]

2. Description of the Related Art Currently, secondary batteries and electric double layer capacitors are widely used as energy storage devices.
Each of these energy storage elements has advantages and disadvantages.

Comparing the secondary battery and the electric double layer capacitor, respectively, the secondary battery has a relatively high energy density, but has a low input / output density and a short charge / discharge cycle life. Further, the electric double layer capacitor has a large input / output density, and has a small energy density in spite of a long charge / discharge cycle life. An electric energy storage device proposed to make up for each of these drawbacks is disclosed in Japanese Patent Application Laid-Open No. 4294515. As shown in FIG. 5, this uses an electric energy storage using an electrode 23 and an electrolyte 24 in which a metal or metal oxide 22 is bonded to the surface of activated carbon 21 by a mechanochemical method. When an electric potential is applied to the electrode of the electric energy store configured as described above, first, the electric double layer 25 is generated at the interface between the electrode and the electrolyte,
When a potential is further applied to the electrodes, the ions in the charged electrolyte move into the electric double layer 25 to store energy. After that, the ions in the electrolyte that have moved into the electric double layer are taken up by the metal or the metal oxide in the electrode, and the energy is further stored. Eventually energy is stored both in the electric double layer and in the electrodes. Thus, not only can the electrolyte be incorporated into the electric double layer, but also the ions in the electrolyte can be incorporated into the metal or metal oxide in the electrode. Therefore, it is possible to realize an energy storage device having a large input / output density and energy density and a long charge / discharge cycle life. In addition, in the same publication, as metals that bond to activated carbon, Au, Ag, Pt, Ph, Ru,
Ti, Ir, Co, Cu, Zu, Ni, Fe and the like can be mentioned, and as the metal oxide that binds to activated carbon, Rh, Ru,
Oxides of Ti, Ir, Co, Cu, Zn, Ni, Fe and the like are mentioned.

[0004]

In the prior art, among the metals shown above, the rare metals (Pt, Rh, Ru,
When Ir) is used as an electrode by being bonded to activated carbon, the performance is considerably better than when other metals are used. However, these metals are very few and costly. Therefore, when attempting to produce a consumer device using these metals, there is a problem of resource depletion and the like, which is not practical.

Therefore, the present invention has as its technical problem the provision of an electric energy storage body which does not become resource-depleted, uses inexpensive and abundant materials, and has excellent performance.

[0006]

The technical means (hereinafter referred to as the first technical means) taken in the invention of claim 1 to solve the above technical problems is at least two electrodes facing each other. And an electrolyte, and an electric energy storage body comprising an electrolyte, wherein at least a part of the electrode material contains a manganese oxide or a complex oxide thereof, and electric energy is stored and released through the electrolyte. That is, the electric energy storage body is used.

In order to solve the above technical problems, a second aspect is provided.
The technical means taken in the invention (hereinafter referred to as the second technical means) is that ions in the electrolyte are adsorbed and desorbed inside the electrode material to cause a change in the crystal structure of the electrode material. The electric energy storage body according to claim 1, characterized in that electric energy is stored and released without the electric energy storage body.

[0008]

According to the above-mentioned first technical means, an electrode is used which contains manganese oxide or its complex oxide in at least a part of the electrode material. Accordingly, it is possible to provide an electric energy storage body having a long charge / discharge cycle life, a high input / output density, and a high energy density. Further, since manganese is used, an electric energy storage body can be produced at low cost, and Ru, I
Since rare metals such as r are not used, there is no fear that these resources will be exhausted.

According to the second technical means, when ions in the electrolyte are adsorbed and desorbed inside the electrode material, these ions do not change the crystal structure of the electrode material. Thereby, the durability of the electrode material is improved and the electrode material can be used for a long time.

[0010]

Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is a conceptual diagram of a charging / discharging mechanism of an energy storage element according to the present invention, and FIGS. 2, 3 and 4 are first, second and third embodiments of the energy storage element according to the present invention, respectively. It is sectional drawing of an example.

Example 1 A mixed powder of an oxide containing manganese dioxide and carbon added for the purpose of imparting conductivity is kneaded with butyl carbitol acetate / α-terpineol or the like to form a paste to form an electrode material 2. To do. The electrode material 2 is printed, baked, and fixed on the electrode substrate 1 made of metal Ti. The electrode substrates 1 on which the electrode material 2 is fixed are opposed to each other, and a separator 3 made of glass fiber is inserted therebetween. The opposing electrode substrates 1 are fixed with an insulating seal 7 such as rubber or adhesive. An electrolytic solution composed of a KOH aqueous solution is injected from the electrolytic solution injection port 6. This makes it an electrical energy store.

Here, the conductivity-imparting agent is not limited to carbon and may be fine particles of Ag, Ni or the like.
The electrode substrate is not limited to Ti, and stainless steel or aluminum can be used depending on the electrolytic solution. The oxide containing manganese dioxide is a mixture of other metal oxides,
It means a complex oxide.

Example 2 A mixed powder of an oxide containing manganese dioxide and carbon added for the purpose of imparting conductivity is kneaded with a water-soluble binder (CMC: carboxymethyl cellulose) and a KOH electrolytic solution to form a paste. The electrode material 2 is molded. A paste-like electrode material 2 is formed on the metal mesh 4 and fixed to the electrode substrate 1. The separator 3 is sandwiched between the two electrodes thus formed, and the two electrodes are insulated by the insulating seal 7 and pressed and fixed.
This forms the electrical energy store. The electrolytic solution is not limited to the KOH aqueous solution, and may be an organic solvent. When using an organic solvent, an organic solvent is used instead of a water-soluble binder.

(Example 3) Manganese nitrate was dissolved in a dispersion liquid in which carbon was dispersed in water to obtain an electrode material 2 as a manganese nitrate / carbon dispersion aqueous solution. The electrode substrate 1 is dipped in the solution-shaped electrode material 2, dried and fired. Electrodes are formed by repeating dipping, drying and firing. The pair of electrodes thus formed are opposed to each other, both electrodes are insulated by the insulating seal 7 via the separator 3, and the electrolytic solution 5 is injected from the electrolytic solution injection port 6. The electrolyte is KOH
Use an aqueous solution. This constitutes an electrical energy store.

The electric energy store constructed as in the above embodiment charges and discharges electric energy based on the following phenomenon.

When a pair of electrodes facing each other are placed with an electrolyte in between and an electric potential is applied, the following phenomenon occurs in the electrodes and in the vicinity thereof, as shown in FIG.

(11) An electric double layer is formed at the interface between the electrode and the electrolyte, and the ions in the electrolyte charged by the applied potential move into the electric double layer.

(12) When a larger potential is applied, cations originally adsorbed in the electrode are desorbed at the positive electrode, and cations of the same kind existing in the electrolyte are adsorbed at the negative electrode, resulting in a potential difference between the electrodes. Is further increased.

(13) Ions adsorbed on the negative electrode are dissociated or diffused from the electrode surface and enter the inside of the electrode.
The penetration position at this time is between the lattices or at the lattice points, and the electrons that are the driving force for adsorption move around without being fixed.

Due to the above phenomenon, energy is finally stored in both the electric double layer and the electrode. On this occasion,
It is characterized in that there is no large change in the crystal structure inside the electrode. In addition, since the balance of charges of the electrode material is guaranteed in the state of mixed electron valence, elution of the electrode material unlike the conventional secondary battery is not involved.

Energy is stored by such a mechanism. This corresponds to charging. Such charging is dominated by surface diffusion of adsorption / desorption ions and adsorption / desorption dissociation, and the position of the electron required for charging is not fixed.For example, the oxidation / reduction rate in the electrode reaction of the conventional secondary battery Remarkably faster than

In this state, if the charging power source is removed and a load is connected between the electrodes, (21) the energy stored in the electric double layer is released.

(22) Ions adsorbed on the electrodes are adsorbed and desorbed in the reverse order of charging, and are released into the electric double layer to release energy.

Energy is released by such a mechanism. This corresponds to discharge.

The capacity of the electric energy store accompanied by adsorption / desorption of ions to / from the electrode is more than 10 times larger than the capacity of the conventional electric double layer, and therefore, a very large energy storage is possible and charging / discharging is performed. It has the characteristics of high speed and high input / output density. In addition, the crystal life of the electrode material does not change, resulting in a long service life.

In Examples 1 to 3, the interelectrode potential was 1.2 V in the case of the aqueous electrolyte and 3.0 in the case of the organic electrolyte.
Constant-current charging was performed up to V, and discharging was performed after completion of charging to obtain energy density, power density, charge / discharge cycle life, and effective output at -30 degrees. As a comparative example, the characteristics of an electric double layer capacitor (commercially available product) were also measured. Table 1 shows the measurement results.

[0028]

[Table 1]

As is clear from Table 1, it has become possible to improve the energy density and output density while taking advantage of the characteristics of the charge / discharge cycle life and low temperature characteristics of the electric double layer capacitor.

[0030]

The invention of claim 1 has the following effects.

According to the present invention, in an electric energy storage body composed of at least two electrodes facing each other and an electrolyte, at least a part of the electrode material contains manganese oxide or a complex oxide thereof. As a result, the advantages of the electric double layer capacitor, that is, the long life of the charge / discharge cycle and the high output density can be utilized, while the disadvantages of the low energy density can be eliminated. Further, by using manganese as the metal used for the electrode material, it was possible to provide an electric energy storage body having the same performance as rare metals such as Ru and Ir unlike the prior art. This allows
There was no fear of resource depletion caused by using rare metals, and an inexpensive electric energy storage could be provided.

The invention of claim 2 has the following effects.

When the ions in the electrolyte are adsorbed and desorbed in the electrode, the crystal structure of the electrode material does not change. Thereby, the durability of the electrode material is improved, and the electrode material can be stably used for a long time.

[Brief description of drawings]

FIG. 1 is a schematic view of a charging / discharging mechanism of an energy storage device according to the present invention.

FIG. 2 is a sectional view of a first embodiment of an energy storage device according to the present invention.

FIG. 3 is a sectional view of a second embodiment of the energy storage device according to the present invention.

FIG. 4 is a sectional view of a third embodiment of the energy storage device according to the present invention.

FIG. 5 is a schematic view of a charging / discharging mechanism of an electric energy storage device according to the prior art.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Electrode substrate 2 Electrode material 3 Separator 4 Metal mesh 5 Electrolyte solution 6 Electrolyte solution inlet 7 Insulation seal 8 Electrode 9 Power supply 10 Electric double layer 11 Anion 12 Cation

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Soichi Shin 1 Aisin Seiki Co., Ltd. 2-1, Asahi-cho, Kariya city, Aichi prefecture

Claims (2)

[Claims] 1. An electric energy storage device comprising at least two electrodes facing each other and an electrolyte, wherein at least a part of the electrode material contains manganese oxide or a complex oxide thereof, and an electric power is supplied via the electrolyte. An electric energy storage device, which stores and releases energy. 2. The electric energy is stored and released without adsorbing and desorbing ions in the electrolyte inside the electrode material to cause a change in the crystal structure of the electrode material. The electrical energy store described.