KR970005960Y1 - Recycle device of the electrolyte - Google Patents

Abstract

none

Description

Battery electrolyte return device

1 is a partially cut-away plan view showing the configuration of the present invention

2 is a longitudinal cross-sectional view of FIG.

(A) (b) of FIG. 3 is a plan view and a developed state diagram showing the reactor of the present invention.

4 is a conventional diagram,

(A) Longitudinal cross-sectional view of the return device with rod-shaped reactor

(B) is a longitudinal sectional view of a return device having a reactor of particulate catalyst;

* Description of the symbols for the main parts of the drawings *

1: outer cylinder 2: inner cylinder

3: ceramic case 4: reactor

5a, 5b: uneven portion 6, 7: threaded portion

8a, 8b: outlet 9a, 9b: inlet

10: support 100: return device

S: Shilling

The present invention relates to an electrolyte return device of a storage battery, and more particularly to an apparatus for returning a gas generated by heat generation by sufficient catalytic reaction to an electrolyte using a honeycomb reactor having a large contact area even at a small volume.

The catalyst consists of a cathode and an anode, and an electrolyte solution (sulfuric acid solution, etc.) for the chemical reaction of these electrodes is hermetically coupled to the case.

Such a battery generates gas by continuing charging and discharging, and attempts to realize a maintenance-free battery by reducing and recovering this gas into water by using a catalytic reaction. Such an attempt appears as an implementation of a return device incorporating a catalyst in the battery. have.

Looking at the prior art with respect to the above-mentioned recirculation device as shown in Figure 4 attached to the recirculation device having a rod-shaped reactor 21 made of a porous exhaust stone according to the shape of the reactor constituting the catalyst is sealed in the storage ( 20 and a return device 30 having a reactor 31 in which a porous catalyst is filled with a particulate catalyst in a ceramic housing is known.

The prior arts have the following problems.

That is, the gas passing through the catalyst is in simple contact with the catalyst, so that the internal catalyst does not sufficiently react with the catalyst on the outer surface, thereby reducing the reaction efficiency.

In addition, the decrease in the reaction efficiency requires a quantitative increase of the catalyst compared to the same reaction to increase the manufacturing cost and installation space, moreover, the unreacted gas in the state in which the reaction is not sufficiently made, the case containing the catalyst as a whole Due to the porous case, the discharge is forced and lost by the inflow gas, so that the maintenance of the maintenance-free battery is more difficult.

The present invention devised to solve all the above-described problem has the following purpose.

The present invention provides a reactor for recovering an electrolyte solution of a battery in which a reactor for reducing a gas generated in a battery by a catalytic reaction has a constant induction path, thereby increasing a contact area and a reaction time and thus increasing a return efficiency.

The present invention provides a device for recovering electrolyte solution of a battery battery, in which the installation space can be drastically reduced due to the reduction of the outer shape of the reactor in the catalytic reaction.

The present invention provides a battery electrolyte return device capable of realizing a maintenance-free battery because only a part of waste gas discharged from the catalytic reaction due to high return efficiency.

In order to achieve the above object, the present invention is made of an inner and outer cylinder housing having an unevenness for air cooling, and a ceramic case embedded in the housing and having a honeycomb reactor.

Hereinafter, the technical configuration of the present invention will be described in detail with reference to the accompanying drawings.

In FIG. 1 and FIG. 2, the return apparatus 100 of the present invention forms concave and convex portions 5a on the upper surface, and the concave and convex portions 5b and the lower portion are opened on the side surface and the screw portion (on the inner diameter upper portion). 6) formed outer cylinder 1, the upper part is opened and the uneven part 5a perpendicular to the side is formed and the inlet hole (9a) and the support inclined from the outside to the center by drilling the outlet (8a) at one point The two-divided ceramic cake (3), which houses the inner cylinder (2) forming the thread (7) with the upper outer circumference and the honeycomb reactor (4) formed of the palladium-based catalyst, forms the bottom (10). Including the inlet (9b) made of porous exhaust stone and the outlet (8b) to the porous exhaust stone to one side, so that the outlet (8a) of the inner cylinder (2) and the outlet (8b) of the ceramic case (3) coincide with the support ( 10), the inner cylinder (2) is inserted into the outer cylinder (1) and screwed together with the screw parts (6, 7), but through the sealing (S) It is done in combination.

Wherein the honeycomb reactor 4, as shown in FIG. 3, when the size of the cell is large and the density is small, the induction path 4a through which the inflow gas flows as shown in (a) is moved upward and downward. Alternately, it may be formed to be distributed to the adjacent cell, or (b) in the case of a small cell cell having a high density and high density as shown in (b), the inlet gas may be distributed from the bottom to the top.

Looking in more detail with respect to the effect of the present invention to achieve the configuration as described above are as follows.

As is known, it is used by combining the return device of the present invention to the gas outlet of the battery, the battery is generated by distilled water gasified by hydrogen and oxygen according to the charge and discharge.

In other words, 2H ₂ O → 2H ₂ + O ₂ generated by the ionization, the reactor is used to reduce the hydrogen and oxygen gas to H ₂ O through the catalytic reaction, the hydrogen and oxygen gas due to the catalyst The combined rise in temperature causes water vapor to condense and the water vapor condenses and is reduced to water and recovered.

The device 100 of the present invention is the ionized gas is introduced into the inlet (9a) of the inner cylinder 2 is filled in the inner cylinder and at the same time is introduced into the ceramic case (3) through the inlet (9b) to the porous exhaust stone The gas moves up and down along the induction path 4a between adjacent cells from the center cell of the honeycomb reactor 4, which is a catalyst (see FIG. 3 (a)). ) Has the effect of increasing the reaction time by inducing the passage time of the gas and increasing the contact area as a result of the increase of the contact area, and also the explosion-proof safety performance by protecting the outlet of the residual gas by the dual structure of the case. This greatly improves and has the ability to reduce the direct impact on the surrounding environment in the event of large gas spills.

Therefore, most of the gas is heated by the catalytic reaction to vaporize the water, which is air cooled by the uneven parts 5a, 5b, and 5c of the outer cylinder 1 and the inner cylinder 2 to condense with water.

Eventually, the condensed water is recovered to the inclined inlet (9a) of the inner cylinder (2) is subjected to the process of recovering the electrolyte flowing into the storage battery again.

On the other hand, other gas components that do not cause a catalytic reaction while moving the induction furnace 4a of the honeycomb reactor are formed at one side of the outlet 8b and the inner cylinder 2 of the ceramic case 3 made of porous exhaust stone. It is discharged to the outside through the outlet (8a).

The seal (5) is to act as a confidentiality of the inner cylinder (2) and the outer cylinder (1).

Of course, in the case of FIG. 3 (b), the contact area is increased by the honeycomb reactor of small size and high density cell, thereby increasing the catalytic reaction in the gas distribution process.

As described above, the present invention forms a catalyst as a honeycomb reactor, and the gas reacts as it moves along a certain induction path during the catalytic reaction, so that the contact area and the reaction time increase, so that the inside and the outside of the reactor work well. As a result, the return efficiency is increased, and in the catalytic reaction, the reactor is used in the reaction evenly compared to the prior art, so the reaction space is sufficiently reduced even if the external appearance is small, thereby greatly reducing the installation space. The increase in return efficiency is a very good design that enables the realization of a maintenance free battery.

Claims (2)

In a battery electrolyte return device for recovering and recovering the gas of the battery with water as a catalyst reactor, the concave-convex portion 5a is formed on the upper surface, and the concave-convex portion 5b and the lower portion are vertically opened on the side surface and the inner diameter upper portion is formed. The outer cylinder 1 having the threaded portion 6 formed thereon and the upper portion are opened and the uneven portion 5a perpendicular to the side is formed, and the inlet opening 9a is drilled at one point through the outlet opening 8a and the lower portion is inclined from the outside to the center portion. And a two-divided ceramic case (3) for forming an inner cylinder (2) and a honeycomb reactor (4) formed of a palladium-based catalyst, forming a support (10) and forming a screw portion (7) with an upper outer periphery. The inlet (9b) of the furnace porous exhaust stone and the outlet (8b) of the porous exhaust stone to one side, the support 8 so that the outlet (8a) of the inner cylinder (2) and the outlet (8b) of the ceramic case (3) It rests in (10), and inserts this inner cylinder 2 into the said outer cylinder 1 By screwing the screw parts (6, 7), the electrolyte solution return device of a storage battery, characterized in that the coupling is made by interposing. The method of claim 1, wherein the honeycomb reactor has a large cell and a low density, the electrolyte solution return device of the storage battery, characterized in that the induction path (4a) is formed alternately between the center cell and the adjacent cell up and down. .