KR20170035336A - Apparatus for producing hypochlorous acid - Google Patents

Abstract

To provide an apparatus for producing hypochlorous acid, capable of securing stability, the present invention provides the apparatus for producing hypochlorous acid, which includes an electrolytic unit which receives an electrolyte from an electrolyte supply unit, receives raw water from a raw water supply unit, and generates the hypochlorous acid by electrolyzing the electrolyte mixed with the raw water, a power supply unit for applying a voltage to the electrolytic unit, and a control unit which increases the supply amount of the electrolytes to a set supply amount step by step for a plurality of sections divided according to the elapsed time after the voltage is applied to the electrolytic unit, and raises the voltage up to a predetermined voltage step by step.

Description

[0001] APPARATUS FOR PRODUCING HYPOCHLOROUS ACID [0002]

The present invention relates to an apparatus for producing hypochlorous acid.

Generally, it is desirable to sterilize dishes, food processing equipment, cooking utensils, food factory manufacturing equipment, and group feeding facilities using sterilized water because hygienic conditions are very important.

General disinfection method is chlorine disinfection method, disinfection method using chlorine disinfection method can generate substances that can cause cancer induction, and it is very harmful to the human body, and there is a problem that the work environment is poor due to the characteristic odor of chlorine have.

As a method for replacing chlorine disinfection method, there is a disinfection method using ozone, ultraviolet ray, chlorine dioxide, hypochlorous acid, and the like.

Among them, hypochlorous acid is very excellent in sterilizing power and is harmless to the human body. Therefore, the disinfecting method using hypochlorous acid can be applied not only to disinfection of various apparatus but also to washing fruits and vegetables.

Such hypochlorous acid can be produced by electrolysis of electrolyte when supplied with electrolyte, which is hydrochloric acid diluted in an electrolytic cell, and raw water. At this time, hypochlorous acid is hypochlorous acid water. Therefore, the pH of hypochlorous acid produced in the electrolytic cell should be 5.0 to 6.5 and the effective chlorine concentration should be 10 to 80 ppm.

However, when electrolyzed between electrolytes and raw water, hydrochloric acid is produced together when dissolved chlorine reacts with water to produce hypochlorous acid, so it is difficult to maintain the pH of the hypochlorous acid aqueous solution at 5.0 to 6.5.

In addition, when raw water is supplied to dilute the hypochlorous acid water acidified by hydrochloric acid, the pH of the hypochlorous acid water can be adjusted to the range of 5.0 to 6.5, but the effective chlorine concentration is lowered. That is, it is difficult to produce a hypochlorous acid aqueous solution having a pH of 5.0 to 6.5 and an effective chlorine concentration of 10 to 80 ppm. Accordingly, there is a demand for a device capable of producing a hypochlorous acid water having a pH of 5.0 to 6.5 and an effective chlorine concentration of 10 to 80 ppm.

Korean Patent Registration No. 10-2013-0103875

An object of the present invention is to provide a hypochlorous acid generating apparatus capable of securing stability of a hypochlorous acid generating apparatus by interrupting an overcurrent generated in an electrolytic bath.

It is another object of the present invention to provide a hypochlorous acid generating apparatus capable of generating a hypochlorous acid having a desired effective chlorine concentration by a user.

The present invention relates to an electrolytic cell comprising an electrolytic unit for supplying an electrolyte from an electrolyte supply unit and receiving raw water from a raw water supply unit, electrolyzing electrolytes mixed with raw water to produce hypochlorous acid, a power supply unit for applying a voltage to the electrolytic unit, And a control unit for stepwise increasing the supply amount of the electrolytic solution to a predetermined supply amount for each of a plurality of sections divided according to the elapsed time after the application of the electrolytic solution, Lt; / RTI >

Here, the control unit raises or lowers the voltage applied to the electrolytic unit so that the electric power consumption of the electrolytic unit becomes the set consumption electric power after the voltage applied to the electrolytic unit is raised to the set voltage.

In addition, when the control unit generates hypochlorous acid having the first effective chlorine concentration and then hypochlorous acid having the second effective chlorine concentration, the control unit controls the supply amount of the electrolyte to be zero in the first period of the plurality of sections.

Further, the control unit increases or decreases the set supply amount so that the chlorine concentration of hypochlorous acid becomes the set effective chlorine concentration in the last section of the plurality of sections.

Further, the number of intervals is increased as the set effective chlorine concentration of hypochlorous acid is higher.

At this time, the set supply amount, the set voltage, and the set power consumption are set so that the chlorine concentration of hypochlorous acid becomes the set effective chlorine concentration.

The control unit further includes a notification unit for generating an alarm when the power consumption of the electrolytic unit exceeds the set power consumption continuously for a predetermined period of time.

It further includes a measuring unit for measuring the chlorine concentration and pH of hypochlorous acid produced in the electrolytic unit.

The electrolytic unit includes an electrolytic cell for electrolyzing the electrolyte when the electrolyte and the raw water are supplied, and an electrolytic cell for electrolytically supplying the electrolytic solution to the electrolytic cell, wherein the electrolytic unit is provided on the first flow line connecting the electrolytic solution supply unit and the electrolytic cell, And a tubing pump to regulate.

The electrolytic unit further includes a first valve installed on the second flow line for regulating the flow rate of the raw water flowing through the second flow line, a third flow line connected to the electrolytic bath and the chlorine discharge unit on the outside, And a second valve for preventing the backflow of the electrolyte.

According to the present invention, even when a residual electrolyte exists in the electrolytic cell, a relatively small supply amount of electrolyte is supplied to the electrolytic cell for a certain period of time after the voltage is applied to the electrolytic unit, thereby allowing sufficient time for electrolysis of the remaining electrolytic solution So that the overcurrent generated in the electrolytic cell can be cut off.

According to the present invention, even if a residual electrolyte is present in the electrolytic cell, even if an overcurrent occurs due to a relatively small voltage being applied to the electrolytic bath for a certain period of time, the power consumption of the electrolytic unit exceeds the set consumption power And it is possible to generate a hypochlorous acid hypochlorous acid having a desired effective chlorine concentration by the user.

1 is a schematic view of a hypochlorous acid generating apparatus according to an embodiment of the present invention.
2 is a diagram specifically showing an electrolytic unit of the hypochlorous acid generating apparatus of FIG.
3 is a block diagram of an apparatus for generating hypochlorous acid according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

FIG. 1 is a schematic view of an apparatus for producing hypochlorous acid according to an embodiment of the present invention. FIG. 2 is a view showing an electrolytic unit of the apparatus for producing hypochlorous acid shown in FIG. 1, and FIG. 1 shows a block diagram of an apparatus for producing hypochlorous acid according to an example.

1 and 2, an apparatus 100 for generating hypochlorous acid according to an embodiment of the present invention includes an electrolytic unit 110, a measurement unit 120, a control unit 130, and a display unit 140 do.

The electrolytic unit 110 receives the electrolyte from the electrolyte supply part S1 and receives the raw water from the raw water supply part S2. When the power is applied, the electrolyte mixed with the raw water is electrolyzed to generate hypochlorous acid.

Specifically, the electrolytic unit 110 is provided with a separate housing 110a having a housing space therein. The electrolytic unit 110 includes an electrolytic bath 111, a tubing pump 112, a first valve (113) and a second valve (114).

Here, the housing 110a may be formed of a material such as aluminum. In order to prevent corrosion of the aluminum, the housing 110a may be formed by galvanizing aluminum, and then performing a powder coating treatment after zinc plating to improve the corrosion resistance of the zinc plating .

The zinc plating and powder coating process can be performed not only on the housing 110a but also on the entire enclosure accommodating the hypochlorous acid generation apparatus 100. [

In addition, when the internal temperature of the housing 110a rises, the temperature of the housing 110a can be prevented from rising by using the cooling fan F. [

The electrolytic bath 111 electrolyzes the electrolytic when the electrolytic water and the raw water are supplied. That is, when power is applied to the electrolytic cell 111 divided into the anode and the cathode, the electrolytic is electrolyzed. Here, diluted hydrochloric acid may be used as the electrolyte to be supplied to the electrolytic bath 111, and the raw water may be tap water.

The temperature of the electrolytic bath 111 can be measured by attaching a temperature sensor for measuring the temperature of the electrolytic bath 111 when the power is applied and the raw water and the electrolyte react with each other.

The electrolytic bath 111 may be divided into two upper and lower frames, and two chambers may be vertically arranged therein.

The tubing pump 112 is disposed on the first flow line L1 connecting the electrolyte supply unit S1 and the electrolytic bath 111 and regulating the supply amount of the electrolyte supplied to the electrolytic bath 111. [ That is, a predetermined amount of the electrolyte is discharged to the electrolytic bath 111 by the tubing pump 112, and the supply amount of the electrolytic solution can be precisely supplied to the electrolytic bath 111 by the tubing pump 112.

The first valve 113 is installed on the second flow line L2 and regulates the flow rate of the raw water flowing through the second flow line L2.

The second valve 114 is installed on the third flow line L3 connected to the electrolytic bath 111 and the chlorine discharge unit (not shown), and prevents the backflow of the electrolyte.

On the other hand, chlorine gas may be generated during the electrolysis of the electrolyte. When the chlorine gas generated in the electrolytic cell 111 is present in the electrolytic cell 111, the electrolytic cell 111 may explode with an increase in pressure. Accordingly, the chlorine gas generated at this time can be discharged to an external gas collector (not shown).

By discharging the chlorine gas generated in the process of electrolysis of the electrolyte to the outside, it is possible to prevent an accident such as explosion of the electrolytic bath 111 and improve the stability.

As described above, the electrolytic unit 110 according to the embodiment of the present invention electrolytes the electrolytic when the electrolyte is supplied to the electrolytic bath 111 from the electrolytic supply unit S1 and the raw water is supplied from the raw water supply unit S2, And the generated hypochlorous acid is discharged to the hypochlorous acid collecting unit S3 through the fourth line L4.

3, the measuring unit 120 includes a pH measuring unit 121 for measuring the pH of hypochlorous acid, a concentration measuring unit 122 for measuring the chlorine concentration of hypochlorous acid, and a flow rate measuring unit 122 for measuring the flow rate of the raw water. (123).

On the other hand, hypochlorous acid produced in the electrolytic bath 111 must be produced as hypochlorous acid which is slightly acidic. The measuring unit 120 determines whether the pH of the hypochlorous acid generated in the electrolytic cell 111 and collected by the collecting unit S3 is in the range of 5.0 to 6.5 and the chlorine concentration is in the range of 10 to 80 ppm Can be measured.

To this end, the pH measuring unit 121 according to an embodiment of the present invention measures pH of hypochlorous acid generated in the electrolytic bath 111 and collected by the collecting unit S3, and the concentration measuring unit 122 measures the pH of the hypochlorous acid And the chlorine concentration of the hypochlorous acid generated in the collecting section (111) and collected by the collecting section (S3) is measured.

The flow rate measuring unit 123 measures the flow rate of the water supplied into the electrolytic bath 111 through the second flow line L2 through which the raw water flows.

The control unit 130 controls the electrolytic unit 110 so that the acidic hypochlorous acid having an effective chlorine concentration can be produced in the electrolytic bath 111. [

On the other hand, if the electrolyte is continuously supplied to the electrolytic unit 110 at a constant supply amount, an overcurrent may be generated in the electrolytic bath 111, and the stability of the hypochlorous acid generating apparatus 100 may be hindered by the overcurrent. That is, once the hypochlorous acid has been generated, residual electrolytes may be present inside the electrolytic cell 111. As more electrolytes are present in the electrolytic cell 111 than the voltage applied to the electrolytic unit 110 due to the residual electrolytic solution Therefore, an overcurrent may occur.

Therefore, the control unit 130 according to the embodiment of the present invention controls the supply amount of the electrolytic solution to the set supply amount step by step in a plurality of sections divided according to the elapsed time after the voltage is applied to the electrolytic unit 110 through the power supply part 150 . Here, the set supply amount is set in advance by the user, and is set such that the pH of hypochlorous acid is sparse and the chlorine concentration of hypochlorous acid is the effective chlorine concentration.

Accordingly, even when a residual electrolyte is present in the electrolytic bath 111, a relatively small supply amount of electrolyte is supplied to the electrolytic bath 111 for a certain period of time after a voltage is applied to the electrolytic unit 110, It is possible to ensure a sufficient time for disassembly, so that the overcurrent generated in the electrolytic bath 111 can be cut off.

When the control unit 130 generates the hypochlorous acid having the second effective chlorine concentration after generating the hypochlorous acid having the first effective chlorine concentration, the supply amount of the electrolytic solution is set to 0 in the first period of the plurality of the sections Can be controlled.

That is, the electrolytic solution is not supplied into the electrolytic cell 111 in the first section, thereby electrolyzing the remaining electrolytic solution remaining in the electrolytic cell 111 during the process of producing the hypochlorous acid having the first effective chlorine concentration, By gradually increasing the supply amount of the electrolyte from the second period to the set supply amount, it is possible to efficiently produce the hypochlorous acid having a second effective chlorine concentration desired by the user.

In addition, the control unit 130 may increase or decrease the set supply amount of the electrolyte so that the chlorine concentration of hypochlorous acid becomes the set effective chlorine concentration in the last section of the plurality of sections. Here, the set effective chlorine concentration is preset by the user within the range of 10 to 80 ppm which is the effective chlorine concentration.

That is, the set supply amount of the electrolyte in accordance with the set effective chlorine concentration may be varied depending on variables such as the physical properties of the raw water and the temperature inside the electrolysis unit 110. At this time, the control unit 130 determines, , If the effective chlorine concentration of hypochlorous acid in the remaining section is less than the preset effective chlorine concentration, the set supply amount of the electrolyte is increased in the last section. On the contrary, if the effective chlorine concentration of chloric acid is set in the remaining section excluding the last section If it is larger than the effective chlorine concentration, the set supply amount of the electrolyte is decreased in the last section.

As a result, the user can efficiently produce hypochlorous acid having a desired effective chlorine concentration.

In addition, the number of intervals increases as the set effective chlorine concentration of hypochlorous acid is higher. That is, since the set supply amount of the electrolyte increases as the set effective chlorine concentration of hypochlorous acid is higher and the supply amount of the electrolytic solution is increased step by step for each section, The number of the plurality of intervals to be increased also increases.

When the electrolytic unit 110 receives the electrolytic water and the raw water while the power supply unit 150 continuously applies a constant voltage to the electrolytic unit 110, if an overcurrent is generated in the electrolytic bath 111, ) May exceed the set power consumption. Here, the set power consumption is set in advance by the user, and is set such that the pH of hypochlorous acid is negligible and the chlorine concentration of hypochlorous acid is the effective chlorine concentration. The set power consumption is increased as the set effective chlorine concentration is higher. For example, when the set effective chlorine concentration of hypochlorous acid is 20 ppm, 30 ppm, and 40 ppm, the set power consumption can be set to 60W, 100W, and 115W, respectively.

In other words, residual electrolytes may exist in the electrolytic cell 111 in which hypochlorous acid has been generated. Since there is more electrolyte than the set voltage applied to the electrolytic unit 110 due to the residual electrolytic solution, ), An overcurrent may be generated. When the electric power consumption of the electrolytic unit 110 exceeds the set consumption power due to the overcurrent, it is impossible to generate the hypochlorous acid having the effective chlorine concentration.

Accordingly, the control unit 130 according to the embodiment of the present invention raises the voltage applied to the electrolytic unit 110 stepwise to the set voltage. For example, it can be increased by 0.07 V every 0.3 second to reach the set voltage. Here, the set voltage is set in advance by the user, and the pH of the hypochlorous acid is set to be negligible and the chlorine concentration of the hypochlorous acid is set to be the effective chlorine concentration. Then, the set voltage increases as the set effective chlorine concentration becomes higher. For example, when the effective chlorine concentration of hypochlorous acid is 20 ppm, 30 ppm, and 40 ppm, respectively, the set voltage may be set to 7 V, 10 V, and 12.5 V, respectively.

This allows a relatively small voltage to be applied to the electrolytic cell 111 for a certain period of time in the electrolytic unit 110 even when an electrolytic cell is present in the electrolytic cell 111, The set consumption power can be prevented from exceeding and the user can generate the hypochlorous acid having the desired effective chlorine concentration.

The control unit 130 also increases or decreases the voltage applied to the electrolytic unit 110 so that the electric power consumption of the electrolytic unit 110 becomes the set consumption electric power after the voltage applied to the electrolytic unit 110 is raised to the set voltage Can be lowered.

That is, the power consumption of the electrolytic unit 110 may be varied depending on variables such as the physical properties of the raw water and the temperature inside the electrolytic unit 110 after the voltage applied to the electrolytic unit 110 rises to the set voltage, , The control unit 130 monitors the power consumption of the electrolytic unit 110 to raise or lower the voltage applied to the electrolytic unit 110 so that the power consumption of the electrolytic unit 110 becomes the set consumption power, It is possible to produce a hypochlorous acid having an effective chlorine concentration.

The apparatus for generating hypochlorous acid 100 according to the embodiment of the present invention further includes a notification unit 141. [ Here, when the power consumption of the electrolytic unit 110 exceeds the set power consumption continuously for a predetermined time, the notification unit 141 determines that the control unit 130 is abnormal and generates an alarm.

The control unit 130 may include a storage unit 131, a supply control unit 132, a valve control unit 133, and a notification control unit 134.

Here, the supply amount of the different electrolytes may be set and stored in the storage unit 131 for each of a plurality of sections divided according to the elapsed time. Here, the supply amount of the electrolyte may be increased stepwise up to the set supply amount for each of a plurality of sections. The supply controller 132 may adjust the supply amount of the electrolyte according to the supply amount of the electrolyte stored in the storage part 131. [

For example, if the elapsed time is divided into a plurality of sections with the elapsed time being divided into a plurality of sections, the supply amount of the electrolyte set in each section may be gradually increased to the set supply amount and supplied to the electrolytic bath 111 every one minute.

The valve control unit 133 controls the second valve 114 to open or close the first valve 113 to flow the raw water through the second flow line L2 or to prevent the reverse flow of the electrolyte through the third flow line L3. ).

Further, the valve control unit 133 regulates the flow rate of the raw water when the flow rate of the raw water supplied to the electrolytic bath 111 is more or less than necessary. That is, the valve control unit 133 controls the amount of flow of the raw water flowing into the electrolytic cell 111 by opening or closing the first valve 113 or the second valve 114 to prevent the reverse flow of the electrolyte flowing backward from the electrolytic cell 111 can do.

The notification control unit 134 can control the notification unit 141. [ More specifically, the notification control unit 134 operates the notification unit 141 to enable an operator to detect an abnormality of the electrolytic unit 110 and the control unit 130. [

The indicating unit 140 can display the state of the electrolytic unit 110 or the chlorine concentration and pH of hypochlorous acid.

Specifically, the display unit 140 may include a notification unit 141 and a display unit 142. [

The notification unit 141 causes the operator to inform the operator of the states of the electrolytic unit 110 and the control unit 130. In particular, when an abnormality occurs in the operation of the control unit 130, the operator can be notified so that it can be confirmed.

At this time, the notification unit 141 may select at least one of a sound, a light source, a vibration, and the like. In the embodiment of the present invention, the notification unit 141 may include a light emitting diode device as a light source and a buzzer Is used.

Also, in the notification unit 141 according to the embodiment of the present invention, the number of the LED elements to be flashed varies depending on the state of the electrolytic unit 110.

For example, when the flow rate of the raw water is out of the set error range of the reference flow rate (for example, 2L), one light emitting diode element flickers, and when a voltage exceeding a prescribed level is applied to the electrolytic unit 110, When the element is flickered and operates at a predetermined current or more, three light emitting diode elements flicker. When the temperature of the electrolytic bath 111 is measured to a predetermined temperature or higher, four light emitting diode elements flicker. That is, the notification unit 141 can detect an abnormal state of the electrolytic unit 110 according to the number of the light-emitting diode elements to be flickered. If no electrolyte is supplied from the electrolyte supplying unit S1, the separate light emitting diode element flashes. At this time, the buzzer repeatedly generates a warning sound simultaneously with the flashing of one to four light emitting diode elements and another light emitting diode element.

The display unit 142 allows the operator to visually confirm the pH and chlorine concentration of hypochlorous acid generated in the electrolytic bath 111 and collected by the collecting unit S3. The display unit 142 can also display the supply amount of the electrolyte supplied to the electrolytic bath 111 and the supply amount of the raw water.

For example, when the pH and the chlorine concentration of hypochlorous acid do not reach a certain range or exceed a certain range, they can be displayed on the display unit 142 so as to set the concentration of hypochlorous acid appropriately.

The operator can visually confirm whether or not hypochlorous acid is generated by the use of hypochlorous acid water.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Modifications, deletions, additions and the like may easily suggest other embodiments, but these are also within the scope of the present invention.

100: hypochlorous acid generating device 110: electrolytic unit
111: electrolytic bath 112: tubing pump
113: first valve 114: second valve
120: Measurement unit 121: pH measurement unit
122: concentration measuring unit 123: flow measuring unit
130: control unit 131:
132: supply controller 133: valve controller
134: Notification control unit 140: Display unit
141: notification unit 142: display unit

Claims (10)

An electrolytic unit which receives an electrolyte from an electrolyte supply unit and receives raw water from a raw water supply unit, and electrolyzes the electrolyte mixed with the raw water to produce hypochlorous acid;
A power supply unit for applying a voltage to the electrolytic unit; And
A control unit for gradually increasing the supply amount of the electrolyte to a predetermined supply amount and raising the voltage applied to the electrolytic unit stepwise to a set voltage for each of a plurality of sections divided according to the elapsed time after a voltage is applied to the electrolytic unit,
Wherein the hypochlorous acid producing device comprises:
The method according to claim 1,
The control unit
Wherein the voltage applied to the electrolytic unit is raised or lowered so that the electric power consumption of the electrolytic unit becomes the set consumption electric power after the voltage applied to the electrolytic unit is raised to the set voltage.
The method according to claim 1,
The control unit
Wherein when the hypochlorous acid having the second effective chlorine concentration is generated after the hypochlorous acid having the first effective chlorine concentration is generated, the supply amount of the electrolyte is controlled to be zero in the first section of the plurality of sections.
The method according to claim 1,
The control unit
Wherein the set supply amount is increased or decreased such that the chlorine concentration of the hypochlorous acid becomes the set effective chlorine concentration in the last section of the plurality of sections.
The method according to claim 1,
Wherein the number of sections is increased as the set effective chlorine concentration of the hypochlorous acid is higher.
3. The method of claim 2,
The set supply amount, the set voltage, and the set power consumption
Wherein the chlorine concentration of the hypochlorous acid is set to a predetermined effective chlorine concentration.
3. The method of claim 2,
When the power consumption of the electrolytic unit continuously exceeds the set power consumption for a predetermined period of time,
Further comprising a hypochlorous acid generator.
The method according to claim 1,
A measuring unit for measuring the chlorine concentration and pH of the hypochlorous acid produced in the electrolytic unit
Wherein the hypochlorous acid production apparatus further comprises:
The method according to claim 1,
The electrolytic unit includes:
An electrolytic cell for electrolyzing the electrolyte when the electrolyte and the raw water are supplied; And
A tubing pump installed on a first flow line connecting the electrolyte supply unit and the electrolytic cell to flow the electrolyte and regulating a supply amount of the electrolyte supplied to the electrolytic bath,
/ RTI >
10. The method of claim 9,
The electrolytic unit includes:
A first valve installed on the second flow line for adjusting a flow rate of raw water flowing through the second flow line; And
A second valve disposed on the third flow line connected to the electrolytic bath and the chlorine discharge portion of the outside, for preventing the backflow of the electrolyte,
/ RTI >

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