KR102309480B1 - Electrolysis unit of hypochlorous acid and the water supply system using hypochlorous acid - Google Patents

Abstract

The present invention is a hypochlorous acid water electrolysis device and hypochlorous acid water supply device that control the electrolyte temperature to obtain hypochlorous acid water to minimize the generation of chlorine gas harmful to the human body and increase the generation efficiency of hypochlorous acid water provides In particular, since the temperature of the electrolyte can be detected through the electrodes required for electrolysis, the hypochlorous acid water electrolysis device and hypochlorous acid water are used to monitor the temperature between the electrodes to further increase the generation efficiency of hypochlorous acid water. A sterile water supply is provided. In addition, since several heaters are configured to be controlled in different temperature ranges, the hypochlorous acid water electrolysis device and hypochlorous acid water are used to precisely control the electrolyte temperature to further increase the generation efficiency of hypochlorous acid water. A sterile water supply is provided.

Description

Non-acidic hypochlorous acid water electrolysis device and sterilizing water supply device using non-acidic hypochlorous acid water

The present invention relates to a non-acidic hypochlorous acid water electrolysis device and a sterilizing water supply device using non-acidic hypochlorous acid water. By checking the temperature, it is possible to increase the effect of generating non-acidic hypochlorous acid water by maintaining the optimum temperature to obtain non-acidic hypochlorous acid water of the prescribed specifications (concentration 10-80 ppm, pH 5-6.5).

Non-acidic hypochlorous acid (HClO) is obtained through the process of dissolving edible hydrochloric acid in an appropriate proportion in water and electrolyzing it. It is used as an oxidizing agent. The following (Patent Document 1) discloses a technique related to such slightly acidic hypochlorous acid water.

(Patent Document 1) Korean Patent Publication No. 10-2014-0134091

It relates to a method for storing and using sterilized water in which the content of an oxidizing agent containing hypochlorous acid is maintained as it is, comprising the steps of: preparing a solution of pH 4.0 to pH7.5 containing a salt component; a sterilizing water generating step of electrolyzing the solution to generate sterilizing water containing residual chlorine containing hypochlorous acid in the solution; a freezing step of freezing the sterilized water into ice; a transport and storage step of transporting or storing the sterilized water in the form of ice by the freezing step; It provides a storage and use method of sterilizing water that can dramatically extend the time for which sterilization power is maintained by freezing sterilizing water containing residual chlorine such as hypochlorous acid generated by electrolysis.

(Patent Document 2) Korean Patent Publication No. 10-2015-0084167

It relates to a method for manufacturing a wet tissue containing non-acidic hypochlorous acid water and a wet tissue manufactured by this method, and in particular, the method for manufacturing a wet tissue containing non-acidic hypochlorous acid water is to produce slightly acidic hypochlorous acid (HOCl) having a pH of 5.0 to 6.5 a first step; a second step of impregnating the tissue fabric with the non-acidic hypochlorous acid water; A third step of packing the tissue fabric impregnated with the non-acidic hypochlorous acid water with a wrapping paper; is composed, and has the effect of safely implementing sterilization and disinfection power.

(Patent Document 3) Korean Patent No. 1733304

Hypochlorous acid water is applied to microbubble using an impeller pump, and the microbubbled hypochlorous acid water is further activated including the activated magnetic liquid production device, and the activated microbubble hypochlorous acid water is mixed with a plurality of advection streams. It relates to a sterilization and odor removal device having an excellent effect in sterilizing and removing odors in slaughterhouses, biological treatment facilities, and various agricultural and livestock processing sites by passing through sieve nozzles and spraying them into nano bubbles.

However, there are the following problems in obtaining such hypochlorous acid water.

(1) When edible hydrochloric acid and water are mixed or salt is added to electrolyze, slightly acidic hypochlorous acid gas and hydrogen are generated. At this time, the generated hypochlorous acid water has a different generation rate depending on the temperature of the electrolyte to be electrolyzed.

(2) In particular, if the temperature of the electrolyte is high, the amount of generated non-acidic hypochlorous acid water increases, but if this temperature is too high (40° C. or higher), on the contrary, it may generate a large amount of chlorine gas that is harmful to the human body rather than the non-acidic hypochlorous acid water.

Korean Patent Publication No. 10-2014-0134091 (published on: November 21, 2014) Korean Patent Publication No. 10-2015-0084167 (published on: July 22, 2015) Korea Patent No. 1733304 (Registration Date: 2017.04.27)

The present invention is made in consideration of this point, and it minimizes the generation of chlorine gas that is harmful to the human body by controlling the temperature of the electrolyte electrolyzed to obtain non-acidic hypochlorous acid water, and the non-acidic acidity within the prescribed standards (concentration 10-80PPM, PH5-6.5) An object of the present invention is to provide a non-acidic hypochlorous acid water electrolysis device capable of increasing the generation efficiency of hypochlorous acid water and a sterilizing water supply device using non-acidic hypochlorous acid water.

In particular, since the present invention is configured to detect the temperature of the electrolyte solution through the electrodes required for electrolysis, the non-acidic hypochlorous acid water that can further increase the generation efficiency of the non-acidic hypochlorous acid water within the specification by monitoring the temperature between the electrodes Another object of the present invention is to provide an electrolysis device and a sterilizing water supply device using non-acidic hypochlorous acid water.

In addition, the present invention configures several heaters to be turned on/off in different temperature ranges, so that the electrolytic solution temperature is precisely controlled to further increase the production efficiency of non-acidic hypochlorous acid water. Another object of the present invention is to provide a hypochlorous acid water electrolysis device and a sterilizing water supply device using non-acidic hypochlorous acid water.

The present invention is made in consideration of this point, in the electrolysis device (A) for obtaining non-acidic hypochlorous acid water by electrolysis, but installed facing each other, the reaction space 110 formed inside as they face each other, electricity from the outside At least one inlet 120 for supplying the electrolyte used for decomposition to the reaction space 110, at least one outlet 130 for discharging the reaction water electrolyzed in the reaction space 110 to the outside, and the reaction A body 100 including a first body 100 ′ and a second body 100 ″ equipped with at least one heater 140 for adjusting the temperature of the electrolyte solution in the space 110; one side of the reaction space 110 ), one or two electrodes 200 having a first temperature sensor 210 in the exposed portion, installed to face each other, and the other side exposed to the outside of the body 100; and the first temperature and a controller that detects the temperature of the electrode 200 through the sensor 210 and operates the heater 140 to maintain the predetermined temperature range when the electrode temperature is lower than a predetermined temperature range. .

In particular, the electrolyte is characterized in that edible hydrochloric acid is added to distilled water or RO water.

In addition, the temperature range is characterized in that 35 ~ 38 ℃.

On the other hand, in the non-acidic hypochlorous acid water electrolysis apparatus (A) according to the present invention, a second temperature sensor 150 for detecting the external temperature of the main body 100 is added and mounted, and the controller is the main body (100) It is characterized in that the ambient temperature is detected, and the internal temperature of the reaction space 110 is adjusted based on the ambient temperature.

And the main body 100, characterized in that it is configured by adding at least one of the insulating sheet 160 and the reinforcing plate 170 on the outer periphery. In this case, the main body 100 is characterized in that it is made of Teflon.

In addition, at least two heaters 140 are installed, and each heater 140 is characterized in that it is controlled on/off in different temperature ranges, respectively.

And DC power is applied to the electrode 200 .

On the other hand, the sterilizing water supply device using the non-acidic hypochlorous acid water electrolysis device according to the present invention is sterilizing water using the non-acidic hypochlorous acid water generated by the electrolysis device (A) for generating the above-mentioned non-acidic hypochlorous acid water. As a supply device, a raw water pipe 10 equipped with a concentration sensor 11; A tank 20 containing an electrolyte for obtaining non-acidic hypochlorous acid water; an electrolysis device (A) for supplying non-acidic hypochlorous acid water obtained by electrolyzing the electrolyte supplied from the tank (20) to the raw water pipe (10); a power supply (SMPS) for supplying power to the electrolysis device (A); And on the basis of the concentration sensor 11 and the temperature signal detected by the temperature sensor of the electrolysis device (A) to control the amount of electrolyte entering the electrolysis device (A) from the tank (20) and power supply and cutoff The controller 30; characterized in that it includes.

The sterilizing water supply device using non-acidic hypochlorous acid water according to the present invention has the following effects.

(1) Since the temperature of the electrolyte can be adjusted to an appropriate temperature for generating slightly acidic hypochlorous acid in the reaction space, the effect of generating less acidic hypochlorous acid water within the prescribed specifications (concentration 10-80PPM, PH5-6.5) can be increased. can

(2) At this time, since the temperature control is performed through the heater mounted on the body based on the temperature change obtained through the temperature sensor mounted on the electrode, the additional configuration is minimized and the temperature sensing means is not installed in the body of the reaction space. It is easy to know the internal temperature.

(3) Since edible hydrochloric acid is used as the electrolyte for electrolysis, it can be used safely.

(4) Since the temperature of the electrolyte in the reaction space is maintained at 35~38℃, the effect of generating slightly acidic hypochlorous acid water within the prescribed specifications (concentration 10-80PPM, PH5-6.5) can be maximized.

(5) Since the temperature outside the main body is detected and this temperature is used to adjust the internal temperature of the reaction space, the influence of the ambient temperature on the generation of slightly acidic hypochlorous acid can be minimized.

(6) Since it is used by wrapping the outer periphery of the body with an insulating sheet, the heat generated in the reaction space is not easily radiated to the outside. It is possible to increase the production efficiency of non-acidic hypochlorous acid water by maintaining

(7) Since the main body is made of Teflon, it is not easily damaged even when exposed to chlorine, or is not easily broken even by external shocks, so durability can be improved.

(8) At least two heaters are used, but each heater is configured to receive on and off control in different temperature ranges, so the internal temperature of the reaction space is more precisely controlled and specified (concentration 10-80PPM, PH5) -6.5) can further enhance the effect of generating slightly acidic hypochlorous acid water.

(9) As it is possible to increase the production efficiency of non-acidic hypochlorous acid water within the prescribed standards (concentration 10-80 PPM, PH5-6.5), the effects of sterilization and sterilization using non-acidic hypochlorous acid water can be further enhanced.

[FIG. 1] is a cross-sectional view showing the configuration of a non-acidic hypochlorous acid water electrolysis device according to the present invention.
[FIG. 2] is a schematic diagram simply showing the configuration of a sterilizing water supply device using a non-acidic hypochlorous acid water electrolysis device according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. Prior to this, the terms or words used in the present specification and claims should not be construed as being limited to their ordinary or dictionary meanings, and the inventor may properly define the concept of the term in order to best describe his invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention in accordance with the principle that can be.

Accordingly, the embodiments described in the present specification and the configurations shown in the drawings are only one most preferred embodiment of the present invention and do not represent all the technical spirit of the present invention, so various equivalents that can be substituted for them at the time of the present application It should be understood that there may be variations and examples.

[Configuration of electrolysis device]

The non-acidic hypochlorous acid water electrolysis apparatus (A) according to the present invention, as shown in [Fig. 1], includes a main body 100, two electrodes 200, and a controller.

In particular, since a first temperature sensor 210 is mounted on the electrode 200 to detect the temperature inside the main body 100 where electrolysis is performed, at least the first temperature sensor 210 is mounted on the main body 100 through the control of the controller. Since it is configured to control the temperature of the electrolyte with one heater 140, it is possible to control the temperature of the electrolyte at a temperature at which non-acidic hypochlorous acid water within the prescribed specifications (concentration 10-80PPM, PH5-6.5) is well generated. did it

At this time, since the first temperature sensor 210 is mounted on the part of the electrode 200 protruding out of the body 100, it can be easily and conveniently mounted, and the first temperature sensor 210 is not exposed to the electrolyte. This is to increase durability.

In addition, since at least two heaters 140 are mounted and configured to control on/off in different temperature ranges, it is possible to precisely control the internal temperature of the reaction space 110 in which the electrolysis is performed. It is designed to produce slightly acidic hypochlorous acid water within the standard (concentration 10-80PPM, PH5-6.5) under the optimum temperature condition.

Hereinafter, such a configuration will be described in more detail with reference to the accompanying drawings.

go. main body

The body 100 includes a first body 100 ′ and a second body 100 ″ to provide a reaction space 110 that can be assembled into one and electrolyzed inside, as shown in FIG. 1 . In this case, the first body 100 ′ and the second body 100 ″ are configured to be assembled and disassembled so that an electrode 200 , which will be described later, can be mounted therein.

The main body 100 is provided with a reaction space 110 , at least one inlet 120 , at least one outlet 130 , and at least one heater 140 as shown in FIG. 1 .

1. Reaction space

The reaction space 110 is formed to receive the electrolyte required for electrolysis therein as the first body 100 ′ and the second body 100 ″ are assembled into one, as shown in FIG. 1 . It is preferable that the reaction space 110 has a width that can secure a sufficient electrolyte in consideration of the capacity for electrolysis, etc. In addition, the reaction space 110 is formed with a narrow width between them. It is preferable to configure the electrode 200 to increase the electrolysis effect.

2. Entrance

The inlet 120 is for supplying the electrolyte required for electrolysis into the reaction space 110 from the outside of the main body 100 described above, as shown in FIG. 1 . This inlet 120 constitutes at least one so as to supply sufficient electrolyte required for electrolysis into the reaction space 110 .

At this time, any electrolyte supplied to the reaction space 110 through the inlet 120 may be electrolyzed to produce non-acidic hypochlorous acid water, but most preferably, it is edible in distilled water or RO water. It is better to use the one with hydrochloric acid added. Here, distilled water refers to water purified by cooling the water vapor generated when water is heated, and RO water (Reverse Osmotic Water) refers to water that passes through a semi-permeable membrane while applying a constant pressure to the water.

3. Exit

The outlet 130 is an outlet for discharging the non-acidic hypochlorous acid water generated by electrolysis into the above-described reaction space 110 to the outside of the body 100, as shown in FIG. 1 . This outlet 130 constitutes at least one so as to sufficiently discharge the non-acidic hypochlorous acid water generated by electrolysis out of the main body 100 in the reaction space 110 .

4. Heater

Heater 140, as shown in [Fig. 1], by mounting at least one on the body 100 described above to adjust the temperature of the electrolyte supplied to the reaction space 110 to perform electrolysis, the production efficiency of non-acidic hypochlorous acid water make it possible to increase

In particular, in a preferred embodiment of the present invention, the heater 140, as shown in [Fig. 1], at least two are mounted on the body 100, and each heater 140 is turned on / off in different temperature ranges. Therefore, it is preferable to configure so that the temperature of the electrolyte can be precisely controlled. For example, the first heater is turned on/off based on 34°C, and the other heater is controlled to be on/off based on 36°C. It allows for easy and convenient control.

In addition, in a preferred embodiment of the present invention, the heater 140 controls the internal temperature of the reaction space 110 to be 35 to 38 ° C. It makes it possible to maintain the optimum temperature range to increase the effect of generating hypochlorous acid water.

It is preferable that the main body 100 made in this way is made of Teflon so as to prevent corrosion or the like from external shocks or electrolytes from being broken by external shocks. In addition, the main body 100 is configured by adding and mounting a second temperature sensor 150 that detects the surrounding external temperature, and further adding at least one of the insulating sheet 160 and the reinforcing plate 170 to the outer periphery. It is preferable to do

5. Second temperature sensor

The second temperature sensor 150, as shown in [Fig. 1], is mounted on the outside of the above-described main body 100 to detect the surrounding temperature. And the temperature signal detected in this way is used to maintain the internal temperature of the reaction space 110 through a controller to be described later at an appropriate temperature for generating non-acidic hypochlorous acid water. That is, the internal temperature of the reaction space 110 and the external temperature of the body 100 are not too different from each other, and the internal temperature of the reaction space 110 is a non-acidic difference within the prescribed standard (concentration 10-80PPM, PH5-6.5). The external temperature is used to maintain a suitable temperature for the production of chloric acid.

In a preferred embodiment of the present invention, the second temperature sensor 150 is mounted by inserting one end into the main body 100 or a terminal lug fixed by inserting a fastening bolt for fixing the main body 100 to the other end. Therefore, it is preferable to easily and conveniently mount it so that the temperature can be detected. Here, the terminal lug means a terminal manufactured by a conventional technique used to easily connect the terminal to the end of an electric wire or the like.

6. Insulation sheet

The heat insulating sheet 160 is attached to the outer periphery of the main body 100, as shown in FIG. 1 . The thermal insulation sheet 160 maintains an optimal temperature for generating non-acidic hypochlorous acid water through the thermal insulation and thermal insulation effect of the reaction space 110 .

7. Reinforcement plate

The reinforcing plate 170 is attached to the outer periphery of the main body 100 described above, as shown in FIG. 1 . At this time, the reinforcing plate 170 can be used any one that can reinforce the structural rigidity of the main body (100).

In a preferred embodiment of the present invention, the reinforcing plate 170 is most preferably a metal plate capable of reinforcing structural rigidity. In this way, when using a metal plate, power flows to the main body 100 or the heat insulating sheet 160 by using the insulating layer 171 so that the reinforcing plate 170 does not contact the electrode 200 as shown in FIG. 1 . The present invention must be configured to cut off the power or, in the case of the main body 100 through which electricity passes, the electrode 200 must be configured not to conduct electricity through the main body 100 to the reinforcing plate 170 or the heat insulating sheet 160, etc. Anyone in the technical field to which this belongs will easily know.

me. electrode

Two electrodes 200 are mounted to electrolyze the electrolyte, as shown in FIG. 1 .

At this time, the two electrodes 200 are installed to face each other in the reaction space 110 on one side where the electrolysis is substantially performed, and the other side is mounted to protrude out of the main body 100, as shown in FIG. 1 . It is installed so that power can be supplied from the outside.

In particular, the electrode 200 is configured to receive direct current from the outside to undergo electrolysis, so that ions having a polarity different from the polarity applied to each electrode 200 are gathered, so that non-acidic hypochlorous acid water is well generated. it is for

When these electrodes 200 are mounted in the main body 100, the configuration to be installed around them and the need to be wrapped with an insulating material or the like to prevent electrical conduction or form an insulating layer to be mounted so that they can be safely used is of the technical field to which the present invention pertains. Anyone in the industry can easily figure it out. In the drawing, the insulating material 220

Meanwhile, a first temperature sensor 210 is mounted on the electrode 200 as shown in FIG. 1 .

1. first temperature sensor

The first temperature sensor 210 is mounted on the electrode 200 exposed to the outside of the body 100 as shown in FIG. 1 .

In particular, the first temperature sensor 210, as shown in [Fig. 1], as the temperature of the electrode 200 is detected, ultimately detects the temperature of the electrolyte solution, so that the electrolyte temperature is optimal for generating non-acidic hypochlorous acid water used to maintain the temperature of The temperature signal of the first temperature sensor 210 is output to the controller to be utilized to control the above-described heater 140 .

In a preferred embodiment of the present invention, since the first temperature sensor 210 is mounted by inserting one side into the other side of a terminal lug fixed by inserting one side into the electrode 200, it can be mounted easily and conveniently to detect the temperature. It is preferable to configure it so that Here, the terminal lug means a terminal manufactured by a conventional technique used to easily connect the terminal to the end of an electric wire or the like.

all. controller

The controller controls the overall non-acidic hypochlorous acid water electrolysis apparatus (A) according to the present invention. That is, the controller detects the temperature of the electrode 200 through the first temperature sensor 210 described above, detects the temperature of the electrolyte solution through this temperature signal, and operates the heater 140 based on the detected temperature. This ensures that the electrolyte in the reaction space 110 maintains the optimum temperature for generating non-acidic hypochlorous acid water within the prescribed specifications (concentration 10-80PPM, PH5-6.5).

At this time, when the controller receives a temperature signal from the second temperature sensor, the heater ( 140) is controlled. That is, if there is a large difference between indoor and outdoor temperature, the temperature is controlled so that the internal temperature of the reaction space 110 does not drop rapidly, or the heater 140 is continuously operated weakly to maintain the internal temperature of the reaction space 110 constant. Control.

If necessary, the controller may control an additionally installed cooling fan to control the internal temperature of the reaction space 110 .

The present invention made in this way allows the electrolyte supplied to the reaction space where the electrolysis is performed to maintain an appropriate temperature for generating non-acidic hypochlorous acid water, so It is possible to increase the production efficiency.

[ sterilizing water supply]

The sterilizing water supply device using non-acidic hypochlorous acid water according to the present invention is used for sterilization and sterilization by mixing the non-acidic hypochlorous acid water produced in the electrolysis device (A) described above with raw water as shown in [Fig. 2]. configured to be able to.

The sterilizing water supply device according to the present invention includes a raw water pipe 10, a tank 20, an electrolysis device (A), a power supply device (SMPS), and a controller 30, as shown in FIG. 2 . do.

go. foe coffin

The raw water pipe 10, as shown in [Fig. 2], is water for use by mixing non-acidic hypochlorous acid water, for example, tap water may be cited as an example.

In particular, the raw water pipe 10, as shown in [Fig. 2], a concentration sensor 11 is mounted, and the concentration signal detected by the temperature sensor 11 is output to the controller 30 to be described later. This is to detect the concentration of the sterilizing water flowing out through the raw water pipe 10 to adjust the content of the non-acidic hypochlorous acid water accordingly.

me. Tank

The tank 20 is a tank for storing an electrolyte solution for electrolysis to obtain slightly acidic hypochlorous acid water, as shown in FIG. 2 .

The tank 20 is equipped with a pump (P), as shown in [Fig. 2], and an electrolyte is supplied so that it can be electrolyzed in the electrolysis device (A). At this time, the pump (P) is controlled by the controller (30) and supplies an appropriate amount of the electrolyte to the electrolysis device (A) according to the concentration of water discharged from the raw water pipe (10).

all. electrolysis device

The electrolysis device (A), as shown in [Fig. 2], receives an electrolyte solution through the above-described pump (P), receives power from a power supply device (SMPS) to be described later, and electrolyzes the electrolyte to electrolyze the non-acidic hypochlorous acid A device that generates numbers. Since the electrolysis device (A) uses the same device as the above-described configuration, a detailed description thereof will be omitted here.

This electrolysis device (A) supplies the non-acidic hypochlorous acid water obtained by electrolyzing the electrolyte to the raw water pipe 10 described above to obtain sterilization water.

La. power supply

The power supply device (SMPS), as shown in [Fig. 2], supplies power to the electrode of the above-described electrolysis device (A) to electrolyze the electrolyte to generate slightly acidic hypochlorous acid water.

At this time, the power supply (SMPS), as shown in [Fig. 2], is controlled by the controller 30, which will be described later, and the electrolyte along with the electric power required for electrolysis is within the prescribed standard (concentration 10-80PPM, PH5-6.5). It will provide power to operate a heater that maintains a suitable temperature for generation of non-acidic hypochlorous acid water.

mind. controller

The controller 30 controls the amount of electrolyte to be electrolyzed by driving the pump P, as described above, as shown in FIG. 2 , or when power is applied or cut off to the electrodes and heaters. In particular, this control is made based on the temperature signal detected by the above-described concentration sensor 11 and the temperature sensor of the electrolysis device (A).

On the other hand, in a preferred embodiment of the present invention, the controller 30 is described as a control means used in the sterilizing water supply device using non-acidic hypochlorous acid water, but the controller described in the electrolysis device (A) is the same as it is. It is preferable to use

As described above, the present invention regulates the temperature of the electrolyte supplied to the reaction space through the electrode to maintain an appropriate temperature for the generation of non-acidic hypochlorous acid water, so that the non-acidic hypochlorous acid within the prescribed specifications (concentration 10-80 PPM, PH5-6.5) It becomes possible to increase the production efficiency of chloric acid water.

A: Electrolyzer
10 : raw water tube
20 : tank
30: controller
100: body
100': first body
100": second body
110: reaction space
120: entrance
130: exit
140: heater
150: second temperature sensor
160: heat insulation sheet
200: electrode
210: first temperature sensor

Claims (9)

In the electrolysis apparatus (A) for obtaining slightly acidic hypochlorous acid water by electrolysis,
Installed facing each other, the reaction space 110 formed inside as they face each other, at least one inlet 120 for supplying the electrolyte used for electrolysis from the outside to the reaction space 110, the reaction space 110 ) at least one outlet 130 for discharging the electrolyzed reaction water to the outside, and at least one heater 140 for controlling the temperature of the electrolyte in the reaction space 110 first body 100 ') and a body 100 including a second body 100 ″;
One side is installed to face each other in the reaction space 110, the other side is mounted to be exposed outside the main body 100, and the temperature of the electrode 200 is ultimately detected in the exposed portion to the outside. One or two electrodes 200 equipped with a first temperature sensor 210 to detect; and
A controller that detects the temperature of the electrode 200 through the first temperature sensor 210 and operates the heater 140 to maintain the predetermined temperature range when the electrode temperature is lower than a predetermined temperature range; Non-acidic hypochlorous acid water electrolysis device (A), characterized in that.
In claim 1,
The electrolyte is
A non-acidic hypochlorous acid water electrolysis device (A), characterized in that edible hydrochloric acid is added to distilled water or RO water (Reverse Osmotic Water).
In claim 1,
The temperature range is
Non-acidic hypochlorous acid water electrolysis device (A), characterized in that 35 ~ 38 ℃.
In claim 1,
A second temperature sensor 150 for detecting an external temperature around the main body 100 is added and mounted,
The controller detects the ambient temperature of the main body 100, and the non-acidic hypochlorous acid water electrolysis device (A), characterized in that it adjusts the internal temperature of the reaction space 110 based on the ambient temperature.
In claim 1,
In the main body 100,
Non-acidic hypochlorous acid water electrolysis device (A), characterized in that it is configured by adding at least one of the insulating sheet 160 and the reinforcing plate 170 to the outer periphery.
In claim 1,
The main body 100,
A non-acidic hypochlorous acid water electrolysis device (A), characterized in that it is made of Teflon.
In claim 1,
At least two heaters 140 are installed,
Each heater 140 is a non-acidic hypochlorous acid water electrolysis device (A), characterized in that the on / off control in different temperature ranges, respectively.
In claim 1,
In the electrode 200,
A non-acidic hypochlorous acid water electrolysis device (A), characterized in that DC power is applied.
A sterilizing water supply device using the non-acidic hypochlorous acid water generated by the electrolysis device (A) for generating the non-acidic hypochlorous acid water according to any one of claims 1 to 8,
a raw water tube (10) equipped with a concentration sensor (11);
A tank 20 containing an electrolyte for obtaining non-acidic hypochlorous acid water;
an electrolysis device (A) for supplying non-acidic hypochlorous acid water obtained by electrolyzing the electrolyte supplied from the tank (20) to the raw water pipe (10);
a power supply (SMPS) for supplying power to the electrolysis device (A); and
A controller for controlling the amount of electrolyte entering the electrolysis device (A) from the tank (20) and power supply and cut-off based on the concentration sensor (11) and the temperature signal detected by the temperature sensor of the electrolysis device (A) (30); Sterilizing water supply device using non-acidic hypochlorous acid water, characterized in that it includes.

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