KR101262218B1 - Air plate cell and the method thereof - Google Patents

Abstract

PURPOSE: An air cathode cell and a manufacturing method thereof are provided to be continuously recycled by separating an air cathode part only when performance degradation occurs after long term use and to solve waste problems. CONSTITUTION: An air cathode cell comprises an osmotic film(1) which prevents sodium components and other minerals of an electrolyte solution from penetrating into an air cathode material and only allows ionized moisture to enter into the air cathode; the air cathode material(2) which is formed by pulverizing carbon sheets and activated charcoal into predetermined sizes; and a non-woven fabric(3) which freely supplies air to the air cathode material and emits moisture penetrated into the air cathode material side. The non-woven fabric uses manganese dioxide and the electrolyte uses salt water, sodium chloride, an aqueous solution, and sea water. [Reference numerals] (AA) Configuration of an air cathode; (BB) Ionized moisture penetration; (CC) Air penetration

Description

Air cathode cell and method for manufacturing same

The present invention relates to an air cathode battery and a method for manufacturing the same, and more specifically, the sheet is made into pieces without using the carbon sheet as it is, and then small pieces of non-sheet form are collected through separate reprocessing by mixing activated carbon and a depolarizing agent. The present invention relates to an air cathode battery made of granules of small pieces and a method of manufacturing the same.

In the case of conventional air cathode batteries, an air cathode battery having a form made of carbon powder or carbon sheet is used.

Since the sheeted air anode is processed by attaching cellophane paper to the electrolyte and the closing part, the cathode is not used anymore when scratches or damage occurs in the sheet part.

On the other hand, Korean Patent No. 0897367 relates to a metal air battery composed of a long shelf life and easy to fabricate and assemble, and is a disposable metal composed of a flexible and volume-controlled battery assembly and a rigid box containing electrolyte passages. An air battery, which has a long shelf life, which is a disadvantage of conventional metal air batteries, and provides fast and inexpensive production means. The present invention provides a method of manufacturing an air anode, which is easy to bond or weld, A method of eliminating breakage and loss due to internal discharge during long term storage has been proposed.

As described above, in the conventional invention, a battery having a long storage period and a loss is developed, but continuous reuse is possible, and when performance is degraded when used for a long time, there is a problem in that regeneration is not possible by separating the air cathode part separately.

In addition, since the cathode material of the air cathode battery, which is currently made, is made in the form of a sheet or a compressed plate, there is a problem in that a temperature characteristic increases in proportion to a high efficiency reaction.

In order to solve the above problems, the present invention does not use the carbon sheet as it is, the sheet is made into pieces, and then the activated carbon and the depolarizing agent are mixed, and the air made in the form of granules of small pieces gathered into small pieces through a separate reprocessing process. Providing a positive electrode battery, it is possible to reuse continuously, especially when the performance decreases during long time use, it is possible to recycle by separating only the air anode part separately, which can recycle up to 80% and solve the waste problem immediately. An object thereof is to provide a cathode cell and a method of manufacturing the same.

The air cathode battery of the present invention is located in the contact area of the electrolyte solution to prevent the sodium component and other minerals contained in the electrolyte solution to penetrate into the air cathode material, and to move only the ionized water to enter the air cathode Osmotic pressure film; Air cathode material obtained by grinding a carbon sheet, activated carbon, and a depolarizing agent into a predetermined size; And a nonwoven fabric for freely supplying air to the air cathode material and discharging moisture penetrated toward the air anode material to the outside, wherein the nonwoven fabric uses manganese dioxide, and the electrolyte is brine, sodium chloride, aqueous solution, It is characterized by using sea water.

The carbon sheet, the activated carbon, and the depolarizing agent of the air cathode material are ground to a diameter of 2 mm to 5 mm, and the carbon sheet, the activated carbon, and the depolarizing agent are mixed at 45 wt%: 45 wt%: 10 wt%, respectively, and the carbon sheet And activated carbon is to add the same amount to each other to match the activity ratio, the depolarizing agent is characterized in that it is maintained at 10% to control the reaction rate and the like.

delete

In the method of manufacturing the air cathode battery of the present invention, the surface of the carbon pieces is made in a smooth form, and in order to use the reaction more densely in the structure, the sheeted carbon material is cut into small grains, and then again milled. Primary carbon sheet processing step of 2mm to 5mm diameter, and activated carbon and depolarizing agent are absorbed densely into the tissue at 45 wt%: 45 wt%: 10 wt%, respectively, in carbon granules in the form of powder and granule, respectively. The air cathode battery thus produced includes a second processing step, and the air cathode battery generated in this way coexists with each other in the form of powder and granulated material, so that air can be smoothly introduced into the components and is stable. The electron ions can be easily introduced from the electrolyte to make the reaction more efficient, and the sodium and other components in the electrolyte solution It prevents minerals from penetrating into the air anode material, allows only the ionized water to move and enter the air anode, ionized water penetrates on one side and air penetrates on the other side, ionized water and air Is reacted inside the air cathode cell to generate electricity.

According to the present invention, the air cathode battery and the manufacturing method thereof do not use the carbon sheet as it is, and then make the sheet into pieces, and then mix the activated carbon and the depolarizing agent and reprocess it into a granule form of small pieces of small pieces which are not in the form of sheets. Providing the air cathode battery made, it is possible to reuse continuously, and if the performance decreases during long time use, only the air cathode part can be separated and regenerated.

According to the present invention, by using an air cathode battery capable of making electricity by using a large amount of salt water or seawater as an electrolyte, when the air cathode material is used for a long time, the efficiency of the anode material may be regenerated and used again. Can be.

Since the present invention is not in the form of a sheet or a plate like other conventional structures, when the efficiency decreases after a long time of use, the anode material is separated and the substance dissolved in sodium and other electrolytes penetrated into the water is separated into water and then separated into a shade. When dried and put back into the mold, the initial efficiency can be used again at any time, reusing up to 80% and solving the waste problem immediately.

1 is a view showing a production process of an air cathode battery according to the present invention.
2 is a view showing the internal structure and the experimental product of the air cathode battery according to the present invention.
Figure 3 is a view showing the hourly current value and the voltage value of the air cathode battery according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the drawings.

As shown in Fig. 1 and Fig. 2, the air cathode battery according to the present invention is largely composed of an osmotic pressure film 1, an air cathode material 2, and a nonwoven fabric 3.

The osmosis-development film 1 is a film located at the portion where the electrolyte solution contacts.

The air cathode material 2 is a material obtained by grinding a carbon sheet, activated carbon, and a polarizing agent into a predetermined size, and preferably, the carbon sheet, the activated carbon, and the polarizing agent are ground to a diameter of 2 mm to 5 mm.

If the carbon sheet, the activated carbon, and the polarizing agent are pulverized to 2 mm or less, there is a problem that heat is generated because the air flow on the opposite side is deformed into a powder form.

In addition, if the carbon sheet, activated carbon, and the polarizing agent is pulverized to 2 mm or more, the reaction area becomes smaller and the air holes become larger, thereby preventing the present invention from achieving the desired object.

In order to obtain an optimized result of the present invention, it is preferable to mix the carbon sheet, the activated carbon and the depolarizing agent at 45 wt%: 45 wt%: 10 wt%, respectively. It is preferable to add the same amount, and to keep the depolarizing agent at 10% to control the reaction rate and the like.

The nonwoven fabric 3 is for freely supplying air toward the air cathode material 2 and for quickly and easily discharging moisture penetrated into the air anode material 2 to the outside.

For example, the nonwoven fabric 3 is a material for freely supplying air toward the air anode material 2 and quickly and easily discharging moisture penetrated into the air anode material 2 to the outside, and its function is to provide air anode. The material 2 serves to hold the frame of the air cathode material 2 in the form of external impact or granules + powder.

Specifically, referring to the drawings, the configuration of the air cathode battery according to an embodiment of the present invention as shown in Figure 1 (a), (b), (c) carbon sheet, activated carbon, a depolarizing agent (for example manganese dioxide Prepare.

That is, the processing method of the air cathode battery according to the present invention is divided into the processing method of the primary carbon sheet and the processing of mixing the three components of the secondary.

As shown in Figs. 1 (a) and (d), the sheeted carbon material is cut into small grains.

The carved carbon grains are then made smaller again with a grinder (eg mortar).

Here, the reason for reprocessing with mortar is that the carbon is cut into small pieces while the tissue is made of sheets, and the sheet-shaped carbon is less cohesive and the surface of the small pieces is not smooth and rough. As moisture is easily absorbed, a rapid reaction occurs, but a shortening of the use time occurs.

Therefore, when the pieces are reworked in mortar, the surface of the pieces becomes smooth and the tissues of the sheet pieces become more dense, so that the absorption of moisture decreases and the reaction due to the denseness of the internal tissues becomes stable, thereby enabling long-term use. .

Then, mix each material made in the processing steps 1, 2, and 3 into one and put it in the mortar once more.

When three kinds of materials, each of which are in the form of powder and granules, are subjected to mortar processing, activated carbon and manganese dioxide are densely incorporated into the tissue in the first processed carbon grains.

In addition, the powder that is not agglomerated into one another is placed between the organized materials, which makes the reaction more stable in the reaction process.

In addition, since the air cathode battery according to the present invention coexists with each material in the form of powder and the material organized in the form of granules, the air can be smoothly introduced into the components, and the ion can easily enter the electrolyte from the electrolyte. Can make a good efficiency in the reaction. Here, brine, aqueous sodium chloride solution and seawater used as electrolytes are used.

This is to prevent the sodium component and other minerals contained in the electrolyte solution from penetrating into the air cathode material 2 and to move only the ionized water to enter the air anode.

Fig. 2 (b) shows the reaction rate in the configuration of the air cathode battery, in which ionized water penetrates on one side and air penetrates on the other side.

Accordingly, ionized water and air react inside the air cathode battery to generate electricity.

The internal structure of the air cathode battery is a structure in which granules and powder are mixed so that air can easily penetrate into the inside and it is optimized for more active reaction.

On the other hand, as shown in Figure 3 (a), the initial current value of the air cathode battery according to the present invention starts at 400mA.

In the air cathode battery according to the present invention, the reaction increases with time, and the output can be obtained up to 2.8 mA.

As shown in Fig. 3 (b), the initial voltage starts with 1.6V.

Referring to the graph, the air cathode battery according to the present invention generates a material according to the oxidation reaction on the magnesium surface due to the reaction of magnesium over time, and a small change in voltage due to the adsorption of the sodium component in the electrolyte solution It is confirmed.

On the other hand, in the embodiment of the present invention has been described with respect to specific embodiments, various modifications are possible without departing from the scope of the invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the appended claims, but also by the equivalents of the claims.

1: film for osmotic pressure development
2: air anode material
3: nonwoven fabric

Claims (4)

An osmotic pressure film positioned at an area where the electrolyte solution contacts to prevent sodium components and other minerals contained in the electrolyte solution from penetrating into the air cathode material and to move only the ionized water to enter the air cathode;
Air cathode material obtained by grinding a carbon sheet, activated carbon, and a depolarizing agent into a predetermined size; And
And a nonwoven fabric for freely supplying air to the air cathode material and discharging moisture penetrated toward the air anode material to the outside.
The nonwoven fabric uses manganese dioxide, and the electrolyte is an air cathode battery, characterized in that the use of brine, sodium chloride, aqueous solution, sea water. The method of claim 1,
The carbon sheet, the activated carbon, and the depolarizing agent of the air cathode material are ground to a diameter of 2 mm to 5 mm, and the carbon sheet, the activated carbon, and the depolarizing agent are mixed at 45 wt%: 45 wt%: 10 wt%, respectively, and the carbon sheet And activated carbon are the same amount to mutually match the activity ratio, the depolarizer is maintained at 10% in order to control the reaction rate and the like. delete In order to make the surface of the carbon pieces smooth and to use the reaction more densely in the structure, the sheeted carbon material is cut into small granules, and the grinder is made into a 2 mm to 5 mm diameter again. Carbon sheet processing step; And
And a second processing step of densely absorbing the activated carbon and the depolarizing agent into the carbon granules in the form of powder and granules, respectively, at 45 wt%: 45 wt%: 10 wt%, respectively, into the tissue. The air cathode battery has two materials, each of which is in the form of powder and granulated material, which can flow smoothly into the components, and it is stable and more efficient to react with electron ions from the electrolyte. It prevents the sodium component and other minerals contained in the electrolyte solution from penetrating into the air cathode material, allows the ionized water to move into the air cathode, and ionized water on one side. Penetrates and air penetrates the other side, and ionized water and air react inside the air cathode cell to generate electricity. The air cathode battery manufacturing method characterized by the above-mentioned.

Images