KR20230034777A - Chlorine electrolysis combined with direct cooling and indirect cooling - Google Patents

Abstract

The present invention relates to a sodium hypochlorite generating electrolyzer combined with direct cooling and indirect cooling. The present invention blocks and cools an electrolyzer from exterior air by a cooling chamber having an indirect cooling coil installed therein, where a refrigerant gas cooled in a cooling compressor moves in an outside of the electrolyzer generating sodium hypochlorite with saline water by electrolysis, has a direct cooling coil, which is connected to the indirect cooling coil, installed inside the electrolyzer to perform direction cooling and indirect cooling at the same time in the inside and outside of the electrolyzer, maintains temperatures inside and outside the electrolyzer to be similar to lead to a small temperature difference and thus, minimizes dew condensation in the cooling coil.

Description

Chlorine electrolysis combined with direct cooling and indirect cooling {Chlorine electrolysis combined with direct cooling and indirect cooling}

The present invention relates to a salt-producing electrolytic cell in which direct cooling and indirect cooling are combined, and an indirect cooling coil is installed in which refrigerant gas cooled by a cooling compressor moves outside the electrolyzer for generating sodium hypochlorite by electrolysis of brine. A cooling chamber made of a housing blocks and cools the electrolysis tank from external air, and a direct cooling coil connected to the indirect cooling coil is installed inside the electrolysis tank, so that direct cooling and cooling are performed inside and outside the electrolysis tank at the same time. Indirect cooling is performed to keep the inside and outside temperatures of the electrolysis tank similar, so that the temperature difference is small, so the direct cooling and indirect cooling are combined to minimize condensation by the cooling coil.

Sodium hypochlorite (NaOCl, Sodium Hypochlorite) is used in water treatment plants, sterilizers in sewage treatment plants, cooling water boilers in general chemical plants, desalination process water, cooling water treatment in power plants, drinking water treatment, plants and vegetables, meat processing, swimming pool washing and It is a chlorine-based disinfectant in the form of a colorless and transparent liquid with a strong chlorine odor that is used as a bleaching agent for papermaking and household use.

The electrolysis-type sodium hypochlorite generator for producing sodium hypochlorite as described above electrolyzes low-concentration salt water to safely produce sodium hypochlorite (hereinafter referred to as sodium hypochlorite), stores the sodium hypochlorite solution, and has a diaphragm for supplying sodium hypochlorite. It is an on-site, non-diaphragm electrolytic chlorine disinfection system that uses a pump to inject a fixed amount into the pipeline.

It is preferable that the internal temperature of the electrolysis tank is 15 ° C to 25 ° C in such a deionized generator, and when the internal temperature of the electrolysis tank rises by 40 ° C or more due to heat generated during the electrolysis process during the production of deionized salt, harmful substances (chlorate , perchlorate, bromate) are made, and a lot of scale is generated on the cathode, so the internal temperature of the electrolysis tank must be maintained below 40 ° C to minimize harmful substances and scale formation.

The most problematic among the harmful substances is chlorate, which is generated after 10 days at 25 ° C, but the above harmful substances can be reduced by cooling the tea salt. It is known that it reduces to /2.

Controlling the entire room temperature to keep the internal temperature of the electrolysis tank constant is costly and inefficient, but in the case of the salt generator, hydrogen gas is produced as a by-product. In winter, it is impossible to heat the room with a heater, and in the summer, it is necessary to cool it with an air conditioner.

On the other hand, in winter, the water temperature of the electrolysis tank is maintained at a level similar to the indoor temperature at around 4℃~10℃, which can cause damage to the electrodes due to the low water temperature during the initial operation of the salt generator, and in the summer season, the indoor temperature There is a problem in that harmful substances are generated due to the high temperature of 30 ℃ or more.

In order to solve this problem, the conventional deionization generator tried to maintain the temperature using a heat exchanger, but in the case of the deionization generator to which the existing heat exchanger was applied, the heat exchanger was applied only to the rise of the incoming water, that is, the heat exchanger was applied only in winter. .

In addition, the deionization generator using the conventional heat exchanger circulates the electrolyzed water during electrolysis to the outside of the heat exchanger to reduce the decomposition efficiency or cools only the surface, resulting in poor performance of the electrolyte material and low energy use efficiency.

On the other hand, since the conventional decondensation generator is cooled by installing a cooling device inside or outside the electrolysis tank, condensation may occur in the cooling pipe depending on the temperature difference between the inside and outside, and when condensation occurs in the cooling pipe, it adversely affects the generation of decontamination. There is a problem affecting

KR 10-1998196 (registration number) 2019.07.03. KR 10-2056889 (registration number) 2019.12.11. KR 10-2120149 (registration number) 2020.06.02.

Accordingly, the present invention was made to solve the above conventional problems,

An indirect cooling coil through which the refrigerant gas cooled in the cooling compressor moves is installed at the bottom of the electrolysis tank that generates sodium hypochlorite by electrolysis of salt water, and the electrolysis tank is blocked from external air by a cooling chamber and cooled, The direct cooling coil connected to the indirect cooling coil is installed inside the electrolysis tank, and direct cooling and indirect cooling are performed inside and outside the electrolysis tank at the same time, keeping the temperature inside and outside the electrolysis tank similar, so that the temperature difference is small. An object of the present invention is to provide a salt-producing electrolytic cell in which direct cooling and indirect cooling are combined to minimize condensation of the coil.

Another object of the present invention is that the cooling chamber is provided to be able to open and close, and the indirect cooling coil and the direct cooling coil are connected and installed with a detachable valve so that the part where the indirect cooling coil and the direct cooling coil are connected can be separated. It is an object of the present invention to provide a salt generation electrolytic cell in which direct cooling and indirect cooling are combined, in which the maintenance of the electrode plate is easy and the cooling amount can be adjusted using a valve.

Another object of the present invention is to maintain the sodium hypochlorite temperature at an optimal temperature by cooling the electrolysis tank from the inside and outside, thereby increasing the production efficiency of sodium hypochlorite and suppressing the generation of harmful substances during storage of sodium hypochlorite. It is to provide a salt generating electrolytic cell in which indirect cooling is combined.

Another object of the present invention is to provide a salt generation electrolytic cell in which direct cooling and indirect cooling are coupled by providing a plurality of connecting means of different sizes to a detachable valve and capable of coupling a plurality of cooling coils.

Another object of the present invention is to provide a salt generation electrolytic cell in which direct cooling and indirect cooling are combined by providing a temperature sensor in the electrolysis tank and operating a cooling compressor when the temperature is high.

Another object of the present invention is to install the inlet through which salt water flows in and the outlet through which salt is discharged on opposite sides of each other, and make the height of the discharge part higher than that of the inlet so that the water level of the electrolysis tank is always open between the discharge parts. It is to provide a salt production electrolytic cell in which direct cooling and indirect cooling are combined that can continuously discharge the salt generated in the salt and the hydrogen generated in the process of producing the salt.

Therefore, in the salt production electrolytic cell combining direct cooling and indirect cooling of the present invention, an indirect cooling coil is installed in which the refrigerant gas cooled in the cooling compressor moves at the bottom of the electrolysis tank for generating sodium hypochlorite by electrolysis of salt water, The cooling chamber blocks the electrolysis tank from outside air and cools it, but a direct cooling coil connected to the indirect cooling coil is installed inside the electrolysis tank, so that direct cooling and indirect cooling are performed simultaneously inside and outside the electrolysis tank. It has the effect of minimizing the dew condensation of the cooling coil by keeping the temperature inside and outside the electrolysis tank similar.

In addition, in the present invention, since the cooling chamber is provided to be able to be opened and closed, and the indirect cooling coil and the direct cooling coil are connected and installed with a removable valve, a part where the indirect cooling coil and the direct cooling coil are connected can be separated, so that the electrode in the electrolysis tank The maintenance of the plate is easy and the cooling amount can be adjusted using the valve.

In addition, the present invention also has the advantage that a plurality of direct cooling coils can be coupled by providing a plurality of connecting means to the detachable valve.

On the other hand, the present invention also has the advantage of having a temperature sensor inside the electrolysis tank so that cooling is performed by operating a cooling compressor when the temperature is high.

In addition, according to the present invention, a packing and coupling means are provided at a part where the cooling chamber is opened and closed to increase an internal sealing rate.

In addition, the present invention has an effect of increasing the production efficiency of sodium hypochlorite and suppressing the generation of harmful substances during storage of sodium hypochlorite because the sodium hypochlorite temperature is optimally maintained by cooling the electrolysis tank from the inside and outside.

In addition, the present invention installs the inlet into which brine flows in and the outlet into which salt is discharged on opposite sides of each other, and makes the water level of the electrolysis tank between the discharge parts while making the height of the discharge part higher than that of the inlet part, so that it is always generated in the open discharge part. It has the effect of continuously discharging hydrogen generated in the process of producing tea salt and tea salt.

1 is a cross-sectional view from the front of a salt-producing electrolytic cell in which direct cooling and indirect cooling are combined according to the present invention;
2 is a cross-sectional view from the side of a salt-producing electrolytic cell in which direct cooling and indirect cooling are combined according to the present invention;
3 is a side view of a detachable valve in a salt generation electrolytic cell in which direct cooling and indirect cooling are combined according to the present invention;
4 is a cross-sectional view of a cooling chamber in an open state in a salt-producing electrolytic cell in which direct cooling and indirect cooling are combined according to the present invention;
5 is a cross-sectional view of a state in which a discharge pipe is coupled in a salt generation electrolytic cell in which direct cooling and indirect cooling are combined according to the present invention.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the present invention will be described so that those skilled in the art can easily implement it.

The present invention is an electrolysis tank for generating sodium hypochlorite in which direct cooling and indirect cooling are simultaneously performed inside and outside the electrolysis tank 100, as shown in FIGS. 1 to 5,

An inlet 101 through which brine flows in is formed on one side, and sodium hypochlorite is generated by electrolysis on an electrode plate inserted therein, and the generated sodium hypochlorite and hydrogen are discharged through an outlet formed on the opposite side of the inlet 101. An electrolysis tank 100 for discharging to 102;

An indirect cooling coil 220, through which the refrigerant gas cooled by the cooling compressor 210 moves, extends from the bottom of the electrolysis tank 100 to the top, and is a cooling chamber composed of a housing surrounding the outside of the electrolysis tank 100. (200); including;

The electrolysis tank 100 is provided with a direct cooling coil 110 connected to the indirect cooling coil 220 and detachably installed by a detachable valve 230 therein.

The electrolysis tank 100 is made of a cylindrical shape, and the electrode plates (not shown) of the anode and the cathode are installed at regular intervals, and the inlet water is supplied to a pipeline line to which saturated brine generated from a brine supply unit (not shown) is supplied. When diluted brine (salt water with a concentration of 3%) generated by mixing in a ratio is supplied from the inlet 101 on one side, it is passed through and electrolyzed on the electrode plate to sodium hypochlorite (in the present invention, 'sodium hypochlorite' and briefly 'Black salt' is mixed and used) is produced, and chlorine disinfection water is created by mixing the produced tea salt with inlet water in a desired ratio.

The electrolysis tank 100 is made of a non-diaphragm type electrode plate having an anode and a cathode in one electrolysis tank, and a gap maintaining member is provided to separate the electrode plates from each other.

The electrode plate may be coupled to a gap maintaining member to maintain a predetermined distance, and a titanium plate may be used as a negative electrode plate, and a plate obtained by plating ruthenium on the negative titanium plate may be used as a positive electrode plate.

On the other hand, the electrolysis tank 100 is provided with an inlet 101 through which brine flows in and an outlet 102 through which salt is discharged, and a discharge formed on the opposite side of the inlet 101 formed on one side. Part 102 is formed at a high position.

The inlet 101 and the outlet 102 are usually provided in a circular shape, and the amount of brine supplied to the inlet 101 is controlled differently according to the electrolysis rate, the temperature inside the electrolysis tank 100, and the water level. can do. However, in the present invention, the discharge part 102 is always open, and the salt water introduced into the inlet part 101 passes through the inside of the electrolysis tank 100 and is electrolyzed so that when it enters the discharge part 102, it becomes a salt shield. The length of the decomposition tank 100 and the electrode plate are provided.

The inlet portion 101 and the outlet portion 102 protrude outward from the metal housings 104 and 105 to which cables (not shown) for supplying electricity to the electrode plates are attached. The metal housings 104 and 105 are formed by the inlet part 101 and the outlet part 102, and are combined with the cable to receive electricity and supply electricity to the electrode plate inside the electrolysis tank 100.

The metal housings 104 and 105 correspond to a component disposed at the edge of the electrolyzer 100, and the cooling chamber 200 is disposed to contact the inside of the metal housings 104 and 105. In the metal housings 104 and 105, the side where the inlet portion 101 is formed is called the inlet side metal housing 104, and the side where the discharge portion 102 is formed is called the discharge side metal housing 105, and together they are called metal housings. do. Between the metal housings 104 and 105, a circular tank 107 in which an electrode plate is disposed is provided, and electrolysis occurs by the electrode plate in the circular cylinder 107.

The diameter of the circular tank 107 in which the electrode plate is embedded is smaller than the diameter of the metal housing and is placed in close contact with the end of the cooling chamber 102.

In this way, in the electrolysis tank 100, the discharge portion 102 through which the salt generated by electrolysis and the hydrogen gas generated during generation of the salt are discharged together is formed at a higher position than the inlet portion 101, and the air layer and the salt A discharge part 102 is disposed between the air layer and the salted supernatant so that the supernatant is discharged together, and the discharge pipe 120 connected to the discharge part 102 separates the hydrogen discharge part 121 and the salt discharge part 122. It is provided so that hydrogen gas and cold salt can be easily separated and discharged.

In the electrolysis tank 100, hydrogen gas and salt are naturally mixed and discharged through the discharge part 102, and from the discharge pipe 120 through the hydrogen discharge part 121 and the salt discharge part 122 to both sides. will be discharged separately.

The salt water level inside the circular tank 107 inside the electrolysis tank 100 is controlled by the brine flowing into the inlet 101, and at this time, the desalted supernatant and hydrogen gas discharged to the outlet 102 are discharged at the same time. Control the inflow of salt water. To this end, a water level sensor (not shown) may be provided inside the circular tank 107.

As such, the present invention forms a hydrogen gas movement passage and discharges the hydrogen gas to the outside of the electrolysis tank 100, thereby preventing safety accidents in which hydrogen gas is trapped inside the electrolysis tank 100 and causes explosion or equipment failure. .

In addition, the electrolysis tank 100 is made of a transparent material, and it is possible to check whether the electrolysis is well performed, how much the electrode plate is worn or whether scale is present, and determine the replacement time, and to form an air layer outside. A cooling chamber 200 is provided to surround the outer circumferential surface, and the cooling chamber 200 is installed to be openable and open so that the inside of the electrolysis tank 100 can be easily checked and maintenance work such as electrode plate replacement is facilitated. will lose

The electrolysis tank 100 has a cooling chamber 200 on the outer circumferential surface of the circular tank 107 to cool the air outside the circular tank 107. The cooling chamber 200 is made of a hollow housing, a cooling compressor 210 is provided therein to cool the refrigerant gas, and cooling is performed through an indirect cooling coil 220 disposed inside the housing of the cooling chamber 200. By cooling the air inside the chamber 200, that is, the air outside the electrolysis tank 100, the heat generated during the electrolysis of the diluted brine is cooled to maintain the temperature inside the circular tank 107 at an appropriate temperature. And, it is possible to produce secondary salt by electrolysis with less harmful substances.

In addition, the electrolytic bath 100 is provided with a temperature sensor on the inner edge so that, when the temperature is higher than a set temperature, the cooling compressor 210 operates so that the internal and external temperatures can be simultaneously controlled.

Meanwhile, the indirect cooling coil 220 extending from the bottom to the top of the cooling chamber 200 is connected to the cooling compressor 210 through a first connection pipe 211, and the second indirect cooling coil 220 extends. Directly connected to the cooling coil 110 by the connection pipe 222, the direct cooling coil 110 is connected to the second connection pipe 222 and the detachable valve 230 outside the electrolysis tank 100 and It is connected to the indirect cooling coil 220 and the cooling compressor 210 by the 3 connection pipe 212 and is inserted into the electrolysis tank 100 to cool the inside of the electrolysis tank 100. At this time, as shown in FIG. 5, the direct cooling coil 110 has irregularities so that it can make contact with a wider area within the electrolysis tank.

As such, the cooling compressor 210 and the indirect cooling coil 220 are connected through a first connection pipe 211, and the indirect cooling coil 220 and the direct cooling coil 110 are connected through a second connection pipe 222. The direct cooling coil 110 and the cooling compressor 210 are connected through a third connection pipe 212.

The indirect cooling coil 220 is mainly disposed in the lower part of the cooling chamber 200, and may be additionally disposed to surround the outside of the circular tank 107. However, the second connector 222, which is inserted into the circular tank 107 and connected to the direct cooling coil 110 that directly cools the internal temperature of the circular tank 107 and delivers the refrigerant, is located above the outside of the circular tank 107. , and directly supplies refrigerant to the cooling coil 110 .

The diameter of the cooling chamber 200 is larger than the diameter of the metal housings 104 and 105, which is larger than the circular tank 107, and indirect cooling that supplies cold air from the outside of the circular tank 107 in a shape wrapped around the circular tank 107. The coil 220 and the second connection pipe 222 for supplying refrigerant to the direct cooling coil 110 that supplies cold air inside the circular tank 107 are arranged on the outer upper side of the circular tank 107. have

The detachable valve 230 is disposed on the top of the circular tank 107 and is directly connected to the cooling coil 110 so that the direct cooling coil 110 can pass through the top of the circular tank 107, and the salt water can pass through the circular tank ( 107) does not leak from the through hole. Since the salt water level of the circular tank 107 of the present invention is between the upper and lower parts of the discharge part 102, the upper part of the circular tank 107 is higher than the highest water level of the salt water, so that it does not meet the salt water during the electrolysis process, so there is a risk of leakage. there is no

The detachable valve 230 is coupled to the second connection pipe 222 of the indirect cooling coil 220 at one side at the top of the circular tank 107 by direct fixation to the inner wall surface of the cooling chamber 200 or indirectly by another configuration. and is coupled with the direct cooling coil 110 on the other side.

When the cooling chamber 200 is opened by the detachable valve 230 to repair or replace the internal components of the cooling chamber 200 or the electrolyzer 100, the direct cooling coil 110 or the indirect cooling coil 220 is removed. It can be separated from the removable valve 230.

The direct cooling coil 110 installed inside the electrolyzer 100 is made of titanium to prevent corrosion and puncture.

Also, in the direct cooling coil 110, condensation may occur when there is a large temperature difference between the outside and the inside of the electrolysis tank 100. In the present invention, the air layer is cooled in the external cooling chamber 200, Since cooling is also performed in the internal electrolysis tank 100, the temperature difference is small and the occurrence of condensation is minimized. Since the condensation of the direct cooling coil 110 affects the salt water and the salt inside the electrolysis tank 100, even a small amount affects the concentration of the salt.

The indirect cooling coil 220 is fixedly installed in the cooling chamber 200, and the direct cooling coil 110 is connected to the indirect cooling coil 220 and has a structure inserted into the electrolyzer 100. The indirect cooling coil 220 and the cooling compressor 210, that is, the cooling chamber 200 and the electrolysis tank 100 are formed by the detachable valve 230 coupled to the second connection pipe 222 and the third connection pipe 212. ) is installed detachably from.

The direct cooling coil 110 receives refrigerant gas from the indirect cooling coil 220 on one side, and the received refrigerant gas moves inside the direct cooling coil 110 and forms a circular bath 107 of the electrolysis bath 100. The internal temperature of the circular tank 107 is lowered while passing through the circular tank 107, and the refrigerant gas warmed by passing through the circular tank 107 is again transferred to the indirect cooling coil and transferred to the cooling compressor 210 to be cooled to the established temperature.

The direct cooling coil 110, the second connection pipe 222, and the third connection pipe 212 are coupled to each other, but are formed in a detachable form by a detachable valve 230. And, in the state where the direct cooling coil 110 and the indirect cooling coil 220 are coupled, the refrigerant gas cooled by the cooling compressor 210 through the second connection pipe 222 and the third connection pipe 212 ( Freon gas) is circulated and cooled again through the cooling compressor 210, and is provided so that the indirect cooling coil 220 and the direct cooling coil 110 can move.

The second connection pipe 222 is a part of the indirect cooling coil 220 connected to the cooling compressor 210, and is directly connected to the cooling coil 110 by the detachable valve 230, and the indirect cooling coil 220 ) can be said.

In addition, a first connection pipe 211 connecting the cooling compressor 210 and the indirect cooling coil 220 and a third connection pipe 212 connecting the cooling compressor 210 and the direct cooling coil 110 In addition, the electrolysis tank 100 may be referred to as a part of the indirect cooling coil 220 for cooling the outside air.

Meanwhile, the direct cooling coils 110 may be provided in plural, and may be connected and installed to a plurality of connecting means 231 formed in the detachable valve 230 . Since the direct cooling coil 110 directly cools salt water or salt water inside the circular tank 107, it must be placed lower than the discharge part 102 because it must be in salt water or salt water.

The detachable valve 230 has a first coupling portion 111 of the direct cooling coil 110 screwed into the connection means 231 and a second coupling portion 221 extending from the indirect cooling coil 220 at both sides. It is attached and detachable easily.

The detachable valve 230 is a two-touch fitting that firmly fixes the tube with a nut and a sleeve, and inserts are inserted into the inner diameters of the direct cooling coil 110 and the indirect cooling coil 220, so that the direct cooling coil ( 110) and the indirect cooling coil 220 can be securely and firmly fixed.

And, when the sizes of the first coupling part 111 and the second coupling part 221 are provided differently, they are coupled by the second connecting means 231b and the first connecting means 231a provided in corresponding sizes. You can do it.

The second connection pipe 222 may be connected to each other by a first connection part 223 to be fixedly coupled to the cooling chamber 200 between the second connection part 221 and the second connection part 221 .

And, the third connection pipe 212 is a detachable valve by a second connection part 213 fixedly coupled to the cooling chamber 200 in the same way as the first connection part 223 to which the second connection pipe 222 is coupled. It may be provided to be connected to (230).

On the other hand, the detachable valve 230 is provided on both sides of the direct cooling coil 110, and the first coupling part 111 coupled to the second connection means 231b is the second connection connected to the second coupling part 221. It may consist of a part through which the refrigerant gas is introduced from the pipe 222 and a part through which the refrigerant gas is discharged by being connected to the third connection pipe 212 connected to the second connection part 213, and thus directly cooling the coil 110. The refrigerant gas introduced through the cooling compressor 210 can circulate inside and outside the electrolysis tank 100.

The first coupling portion 111 of the direct cooling coil 110 and the second coupling portion 221 of the indirect cooling coil 220 have a diameter of Ø5 to 6, and the second connecting means 231b and the second coupling portion 231b The first connection unit 231a has a corresponding size and is provided so that the cooling coil 110, the second connection pipe 222, and the third connection pipe 212 can be directly connected.

The detachable valve 230 is provided in an open state so that the refrigerant gas moves in a state in which the direct cooling coil 110 and the indirect cooling coil 220 are coupled, and the direct cooling coil 110 and the indirect cooling coil 110 and the indirect cooling coil 230 are replaced due to electrode plate replacement. When the cooling coil 220 is separated, it is provided in a closed state so that the refrigerant gas is blocked.

In addition, the detachable valve 230 can control the amount of moving refrigerant gas by adjusting the degree of opening of the valve.

On the other hand, the cooling chamber 200 is formed with a hinge 201 so that the upper part can be opened and closed, a packing 202 is provided for airtightness in the opening and closing part, and a handle 203 is mounted on the outside so that it can be easily opened and closed is composed of In addition, the cooling chamber 200 is also packed at the edges in contact with the metal housings 104 and 105 .

The cooling chamber 200 has a cylindrical shape or a shape in which a semicircular upper portion is combined with a rectangular lower portion, and only a part of the cooling chamber 200 is opened from the upper portion. It is closely coupled to form a hollow housing.

As described above, the present invention prevents the direct cooling coil 110, the indirect cooling coil 220, and the electrolyzer 100 from being exposed to the outside by the cooling chamber 200, so that the inside and outside temperatures are controlled by blocking them from the outside air. It stays the same so there is no condensation.

In addition, since dew condensation does not occur in the direct cooling coil 110, it is possible to generate shielded salt having an effective chlorine concentration suitable for use conditions.

Therefore, in the salt production electrolytic cell in which direct cooling and indirect cooling are combined according to the present invention, the refrigerant gas cooled in the cooling compressor 210 moves in the lower part of the electrolysis tank 100, which generates salt water by electrolysis, indirect cooling. The coil 220 is installed, and the electrolysis tank 100 is blocked from external air by the cooling chamber 200 and cooled, and the direct cooling coil 110 connected to the indirect cooling coil 220 conducts electrolysis. It is installed inside the tank 100, and direct cooling and indirect cooling are performed inside and outside the electrolysis tank 100 at the same time to keep the inside and outside temperatures of the electrolysis tank 100 similar to make the air temperature the same, thereby minimizing condensation. has the effect of

In addition, in the present invention, the cooling chamber 200 is provided to open and close, and the indirect cooling coil 220 and the direct cooling coil 110 are connected and installed by a detachable valve 230, so that the indirect cooling coil 220 and the direct cooling coil 220 are connected directly. Since the part connected to the cooling coil 110 can be separated, maintenance of the electrode plate in the electrolysis tank 100 is easy, and the cooling amount can be adjusted using the detachable valve 230.

In addition, the present invention has the advantage that a plurality of direct cooling coils 110 of different sizes can be coupled by providing a plurality of connecting means 231 of different sizes to the detachable valve 230.

On the other hand, the present invention also has the advantage that the cooling compressor 210 is operated by providing a temperature sensor inside the electrolysis tank 100 when the temperature is high, thereby performing cooling.

In addition, according to the present invention, a packing 202 and a coupling means are provided at a part where the cooling chamber 200 is opened and closed to increase the sealing rate of the inside.

In addition, since the present invention maintains the temperature of the deionized salt optimally by cooling the electrolysis tank 100 from the inside and outside, there is an effect of increasing the production efficiency of the desalination and suppressing the generation of harmful substances during the storage of the desalination.

The present invention installs the inlet through which brine flows in and the outlet through which salt is discharged on opposite sides of each other, and maintains the height of the discharge part higher than that of the inlet so that the water level of the electrolysis tank is between the discharge parts so that the salt is always generated in the open discharge part. It has the effect of continuously discharging hydrogen generated in the process of generating superchlorite.

100: electrolysis tank 101: inlet
102: discharge unit 104: inlet side metal housing
105: discharge side metal housing
107: prototype
110: direct cooling coil
111: first coupling part 120: discharge pipe
121: hydrogen discharge unit 122: salt discharge unit
200: cooling chamber 201: hinge
202: packing 203: handle
210: cooling compressor 211: first connector
212: third connector 213: second connector
220: indirect cooling coil 221: second coupling part
222: second connector 223: first connector
230: removable valve 231: connection means

Claims (8)

An inlet 101 through which brine flows in is formed on one side, and sodium hypochlorite is generated by electrolysis on an electrode plate inserted therein, and the generated sodium hypochlorite and hydrogen are discharged through an outlet formed on the opposite side of the inlet 101. An electrolysis tank 100 for discharging to 102;
An indirect cooling coil 220, through which the refrigerant gas cooled by the cooling compressor 210 moves, extends from the bottom of the electrolysis tank 100 to the top, and is a cooling chamber composed of a housing surrounding the outside of the electrolysis tank 100. (200); including;
In the electrolysis tank 100, a direct cooling coil 110 connected to the indirect cooling coil 220 and detachably installed by a detachable valve 230 is provided therein, and direct cooling and indirect cooling are combined. generating electrolyzer.
According to claim 1,
The direct cooling coil 110 is made of titanium,
The detachable valve 230 is disposed outside the electrolysis tank 100, and the indirect cooling coil 220 and the direct cooling coil 110 are coupled to the direct cooling provided with a connection means 231 at both sides. Salt-producing electrolytic cell combined with indirect cooling.
According to claim 1,
The electrolysis tank 100 is provided with a temperature sensor on the inner edge so that the cooling compressor 210 operates when the temperature is higher than the set value.
According to claim 2,
One side of the detachable valve 230 is coupled to the inner wall surface of the cooling chamber 200,
Direct cooling and indirect cooling in which the first coupling part 111 to which the cooling coil 110 is directly coupled to the connecting means 231 and the second coupling part 221 to which the indirect cooling coil 220 is coupled are coupled Combined hypochlorite-producing electrolyzer.
According to claim 1,
The cooling chamber 200 has a hinge 201 formed to open and close the upper part, and a handle 203 is mounted. Direct cooling and indirect cooling are combined.
According to claim 1,
In the electrolysis tank 100, the discharge part 102 through which generated sodium hypochlorite is discharged is higher than the inlet part 101 into which salt water flows, and the discharge part 102 always maintains an open state. A salt-producing electrolytic cell that combines direct cooling and indirect cooling to maintain
According to claim 6,
The water level by the salt water or the generated sodium hypochlorite in the electrolysis tank 100 is disposed between the upper and lower parts of the open discharge part 102,
A hypochlorite generating electrolytic cell in which direct cooling and indirect cooling are combined in which sodium hypochlorite and hydrogen gas generated when sodium hypochlorite are generated are simultaneously discharged through the discharge unit 102.
According to claim 6,
The direct cooling coil 110 installed in the electrolysis tank 100 in the longitudinal direction of the electrolysis tank 100 is disposed at a lower position than the discharge unit 102, and is a salt farm combining direct cooling and indirect cooling. seabird.

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