KR200417036Y1 - Sodium Hypochloride Generating System Having Soft water Temperature Controller. - Google Patents

Abstract

The present invention relates to a sodium hypochlorite generation system equipped with a soft water temperature control device, the sodium hypochlorite generation system for producing sodium hypochlorite, comprising: a softener for manufacturing and supplying general water introduced from outside into soft water; A brine storage tank for storing brine and supplying it to the electrolysis device through a brine flow pipe; A brine brine flow tube through which the brine discharged from the brine storage tank flows; A flow pump installed in the brine brine flow pipe for flowing brine; A plurality of brine flowmeters installed between the brine flow pipe and the electrolysis device, for diluting the brine and the soft water flowing through the brine flow pipe to make a low concentration of brine; A soft water supply pipe connecting the water softener and the brine flow meter so that the soft water discharged from the water softener is mixed with the brine in the brine flow meter and diluted with the brine of low concentration; An electrolysis device for generating sodium hypochlorite by electrolyzing the low concentration of brine diluted in the brine flow meter with a direct current power supplied from a rectifier; A sodium hypochlorite storage tank in which sodium hypochlorite generated in the electrolysis device is flowed and stored in the discharge pipe; A heat exchanger installed in the sodium hypochlorite discharge pipe connecting the electrolysis device and the sodium hypochlorite storage tank to transfer the reaction heat generated during the electrolysis reaction to a soft water supply pipe; An electric heater installed between the soft water supply pipe through which the soft water passing through the heat exchanger flows and the electrolysis device to heat the soft water; First and second bypass pipes through which soft water flows directly without passing through the heat exchanger or electric heater; Sodium hypochlorite generation system equipped with a soft water temperature control device, characterized in that it comprises a; shut-off valve selectively available to allow the soft water to flow into the heat exchanger or electric heater or flow through the first and second bypass pipes. It is about.

Water softener, sodium hypochlorite, shutoff valve, bypass pipe, heat exchanger, electric heater

Description

Sodium Hypochloride Generating System Having Soft water Temperature Controller.

1 is a block diagram showing a conventional sodium hypochlorite generating device by electrolysis of brine,

Figure 2 is a block diagram showing another embodiment of the conventional sodium hypochlorite generator by brine electrolysis,

Figure 3 is a block diagram of a sodium hypochlorite generation system having a soft water temperature control apparatus according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10: salt water storage tank 15: electrolysis device

20: heat exchanger 25: electric heater

30: sodium hypochlorite storage tank 35: sodium hypochlorite discharge pipe

40: flow pump 45: small flow meter

47: water flow meter 50: water softener

55: training water supply pipe 56: the first bypass pipe

60: salt water flow pipe 65: shutoff valve

70: training water supply pipe 71: second bypass pipe

75: rectifier

The present invention relates to a sodium hypochlorite generation system equipped with a soft water temperature control device, the sodium hypochlorite generation system for producing sodium hypochlorite, comprising: a softener for manufacturing and supplying general water introduced from outside into soft water; A brine storage tank for storing brine and supplying it to the electrolysis device through a brine flow pipe; A brine brine flow tube through which the brine discharged from the brine storage tank flows; A flow pump installed in the brine brine flow pipe for flowing brine; A plurality of brine flowmeters installed between the brine flow pipe and the electrolysis device, for diluting the brine and the soft water flowing through the brine flow pipe to make a low concentration of brine; A soft water supply pipe connecting the water softener and the brine flow meter so that the soft water discharged from the water softener is mixed with the brine in the brine flow meter and diluted with the brine of low concentration; An electrolysis device for generating sodium hypochlorite by electrolyzing the low concentration of brine diluted in the brine flow meter with a direct current power supplied from a rectifier; A sodium hypochlorite storage tank in which sodium hypochlorite generated in the electrolysis device is flowed and stored in the discharge pipe; A heat exchanger installed in the sodium hypochlorite discharge pipe connecting the electrolysis device and the sodium hypochlorite storage tank to transfer the reaction heat generated during the electrolysis reaction to a soft water supply pipe; An electric heater installed between the soft water supply pipe through which the soft water passing through the heat exchanger flows and the electrolysis device to heat the soft water; First and second bypass pipes through which soft water flows directly without passing through the heat exchanger or electric heater; Sodium hypochlorite generation system equipped with a soft water temperature control device, characterized in that it comprises a; shut-off valve selectively available so that soft water flows into the heat exchanger or electric heater or flows through the first and second bypass pipes. It is about.

A conventional sodium hypochlorite generator is shown in FIGS. 1 and 2.

The conventional apparatus for generating sodium hypochlorite by brine electrolysis shown in FIGS. 1 and 2 is a brine storage tank for supplying 28% brine, a brine supply pipe, a brine metering pump, a flow meter, and a 28% salt solution with 3% dilute brine. Heat exchanger for soft water supply softener for soft water dilution, soft water supply pipe, flow meter, soft water heating electric heater for soft water supply line, or reaction heat generated when sodium hypochlorite is generated in the electric heater to maintain the soft water temperature It consists of attached soft water heater, electrolytic bath for electrolysis of brine, hypochlorous acid discharge pipe, hypochlorous acid storage tank.

The principle of the generator of sodium hypochlorite is that sodium hypochlorite is generated by supplying 3% brine of 15 ℃ ~ 18 ℃ to the electrolysis device and supplying electricity to the electrode in the electrolysis device to decompose the salt water electrically. decomposition formula NaCl + H ₂ O + 2e ^- is a → NaOCl + H ² + heat.

The operation method of the sodium hypochlorite generating device formed as described above is made by using a brine storage tank of 28% brine salt water at room temperature and supplying it through a supply pipe and making the brine 3% diluted brine at 15 ° C. to 18 ° C. For the brine dilution, the soft water supplied through the soft water supply pipe and the soft water temperature control unit is mixed using a brine flowmeter to make 3% dilute brine and supply it to the electrolysis device.

The dilute salt water supplied to the electrolysis device formed as described above is heat-exchanged with the soft water while passing through a heat exchanger in the soft water temperature control device for diluting brine by generating sodium hypochlorite by electrolysis and discharging it to a certain degree. It is discharged and stored in a sodium hypochlorite storage tank.

Sodium hypochlorite made as described above maintains the concentration of 7000 ~ 8000 ppm depending on the design of the electrolytic cell, the concentration of salt, the temperature of the brine. In particular, the salt water diluted to 3% is suitable for the temperature of 16 ℃ ~ 18 ℃, if the temperature is too low or too high, the concentration of sodium hypochlorite rapidly occurs, the current efficiency of the electrolysis device is reduced.

Such phenomena are likely to occur due to a decrease in the temperature of the brine dilution soft water due to the temperature drop in winter, and in order to prevent this phenomenon, the temperature of the brine dilution soft water is controlled by an electric heating device (FIG. 1) in the brine dilution soft water supply unit. Although the electric heating device of FIG. 1 is uneconomical due to an increase in the amount of electricity used, the electric heating device with a heat exchanger of FIG. 2 has a sodium hypochlorite leakage due to corrosion or pinhole of the internal coil constituting the heat exchanger. The temperature of the brine dilution soft water cannot be controlled, and there is a problem in that the entire sodium hypochlorite generating device needs to be temporarily stopped. In summer, the temperature of the brine dilution soft water increases so much that the current efficiency decreases.

In this regard, the present invention improves the problems of the above-described existing technology, and heats the brine dilution soft water primarily by using an independent heat exchanger equipped with a bypass tube for the reaction heat of sodium hypochlorite generated in an electrolysis device in winter. Soft water temperature for salt water dilution of hypochlorous acid generator by supplying 3% salt water to electrolysis device by adjusting electric heater device to bypass heat exchanger and by using independent electric heater device in case of breakdown of pinhole. The purpose is to provide an adjusting device.

In order to achieve the above object, the present invention is a heat exchanger and heat exchanger for heat-exchanging the reaction heat generated when sodium hypochlorite is generated in the electrolysis apparatus with soft water supplied with dilute brine in order to maintain the proper temperature of the diluted brine supplied to the electrolysis apparatus. The purpose of the present invention is to provide a soft water temperature control device for diluting salt water of a sodium hypochlorite generator by salt water electrolysis, in which soft water electroheating devices each independently control the temperature of the soft water for dilution.

The present invention has the following features to achieve the above object.

A sodium hypochlorite generation system for producing sodium hypochlorite, comprising: a water softener for producing and supplying general water introduced from outside into soft water; A brine storage tank for storing brine and supplying the electrolysis device through a salt water flow pipe; A brine brine flow tube through which the brine discharged from the brine storage tank flows; A flow pump installed in the brine brine flow pipe for flowing brine; A plurality of brine flowmeters installed between the brine flow pipe and the electrolysis device, for diluting the brine and the soft water flowing through the brine flow pipe to make a low concentration of brine; A soft water supply pipe connecting the water softener and the brine flow meter so that the soft water discharged from the water softener is mixed with the brine in the brine flow meter and diluted with the brine of low concentration; An electrolysis device for generating sodium hypochlorite by electrolyzing the low concentration of brine diluted in the brine flow meter with a direct current power supplied from a rectifier; A sodium hypochlorite storage tank in which sodium hypochlorite generated in the electrolysis device is flowed and stored in the discharge pipe; A heat exchanger installed in the sodium hypochlorite discharge pipe connecting the electrolysis device and the sodium hypochlorite storage tank to transfer the reaction heat generated during the electrolysis reaction to a soft water supply pipe; An electric heater installed between the soft water supply pipe through which the soft water passing through the heat exchanger flows and the electrolysis device to heat the soft water; First and second bypass pipes through which soft water flows directly without passing through the heat exchanger or electric heater; And a shutoff valve selectively usable to allow the soft water to flow into the heat exchanger or the electric heater, or to flow through the first and second bypass pipes.

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

The generation of sodium hypochlorite by conventional brine electrolysis shown in Figures 1 and 2 is brine storage tank for supplying saturated brine (110), brine supply pipe (111), brine metering pump (115), brine flow meter ( 116), water softener (145), soft water supply pipe (141), soft water flow meter (135), soft water for soft water dilution to maintain the brine dilution soft water to make salt salt diluted 2.5 to 3% Attached soft water heating attached to the heat exchanger 150 and the heat exchanger 150 to be used alone or to the heat exchanger 150 to use the reaction heat generated when the sodium hypochlorite is generated in the electric heater 130 or the electric heater 130 in the supply line Apparatus 130, electrolytic bath 120 for brine electrolysis, hypochlorous acid discharge pipe 121, hypochlorous acid storage tank 125 is configured to include.

The principle of the sodium hypochlorite generating device is to supply 2.5 ~ 3% brine of 15 ℃ ~ 18 ℃ to the electrolysis device 120 and by supplying a direct current power supply electricity to the electrode in the electrolysis device 120 to decompose the salt water electrically generating the sodium hypochlorite and reaction schemes are NaCl + H ₂ O + 2e ^- is a → NaOCl + H ₂ + heat.

Operation method of the sodium hypochlorite generating device formed as described above is made by using a brine storage tank 110, saturated salt water 28% salt water at room temperature and supplied through the brine supply pipe 111 and the salt water of 15 ℃ ~ 18 ℃ To make 2.5% ~ 3% dilute brine, the brine dilution is mixed with soft water supplied through soft water supply pipe (141) and soft water temperature controller using brine flow meter (116) to make 3% dilute brine to produce electrolysis device ( 120).

The dilute salt water supplied to the electrolysis device 120 formed as described above is discharged by generating sodium hypochlorite by electrolysis, and the heat exchanger 150 in the soft water temperature control device for diluting brine in the process of discharging sodium hypochlorite. Heat exchange with the soft water while passing through raises the temperature of the soft water to some extent and is discharged and stored in the sodium hypochlorite storage tank (125).

Sodium hypochlorite made as described above maintains the concentration of 7000 ~ 9000 ppm according to the design of the electrolytic cell 120, the concentration of salt, the temperature of the brine. In particular, the salt water diluted to 2.5% ~ 3% is suitable for 16 ℃ ~ 18 ℃, if the temperature is low or too high below 10 ℃, the concentration of sodium hypochlorite is rapidly lowered, the electrolysis device (120 ) Current efficiency is reduced.

As shown in FIG. 3, the present invention relates to a hypochlorous acid generating system that generates sodium hypochlorite by electrolysis in an electrolysis apparatus by diluting with brine by controlling the temperature of soft water.

Referring to FIG. 3 in detail, the brine discharged from the brine storage tank 10 in which 28% of the brine is stored is flowed through the brine flow tube 60 and is installed in the brine flow tube 60 to continuously maintain the brine. A flow pump 40 for flowing is installed, and a brine flowmeter 45 for diluting the brine flowing through the flow pump 40 with low concentration brine is installed in the flow tube, and the brine flow tube 60 supplies the brine. It is connected to the electrolysis device 15 for decomposing to electrolyze a low concentration of brine.

And, the brine with the brine flow meter 40 is mixed with the brine to generate a soft water to generate a soft water to dilute the brine to a low concentration, and the soft water discharged from the water softener 50 through a soft water supply pipe 55 The brine flow pipe (60) is connected to dilute the concentration of brine, the soft water is measured by adjusting the level of the brine by measuring the water level through the soft water flow meter (47), the low concentration of brine in the rectifier (75) Sodium hypochlorite generated by electrolysis through the electrolysis device 15 receiving a DC power is discharged through the discharge pipe 35, the discharged sodium hypochlorite is stored in the storage tank (30).

In this structure, when the temperature of the soft water lowering the concentration of the brine is low, the concentration of the brine is not diluted to 3% when mixed with the brine, so that the temperature of 15 ℃ ~ 18 ℃ when diluted with brine by heating a certain temperature in the soft water. Heat exchanger for supplying the heat of 25 ℃ ~ 30 ℃ to the soft water discharged from the water softener 50 and flows to the electrolysis device 15 by using the reaction heat generated during the electrolysis reaction in the electrolysis device 15 to maintain (20) is installed between the sodium hypochlorite storage tank (30) and the electrolysis device (15), and an abnormality occurs in the heat exchanger (20) or an abnormality in the soft water supply pipe (55) passing through the heat exchanger (20). When connecting the first bypass pipe 56 so that soft water can be supplied without passing through the heat exchanger 20, the shutoff valve 65 to the soft water supply pipe 55 passing through the heat exchanger (20). To pass through the first bypass pipe 56 or to To be selectively used so as to pass through (20).

In addition, the electric heater 25 installed between the heat exchanger 20 and the electrolysis device 15 and the soft water supply pipe 55 passes through the heat exchanger 20 may lower the temperature of the soft water heated or heat exchange. When flowing to the first bypass pipe 56 without passing through the gas 20, the soft water is heated to supply heat, and in the summer season, heat obtained by passing through the heat exchanger 20 as the external air temperature rises. When the water is 25 ℃ ~ 30 ℃ salt water that is directly mixed with the brine without passing through the electric heater 25 so that the soft water is heated in the electric heater 25 and the soft water is not heated to a higher temperature than necessary than the electric heater 25 A second bypass pipe 71 for flowing to the flowmeter 45 is connected, and a shutoff valve 65 for selectively using the electric heater 25 and the second bypass pipe 71 is an electric heater 25. Installed on the second side of the soft water supply pipe (55) and the second bypass pipe (71) .

Thus, the soft water supplied through the first bypass pipe 56 is heated through the electric heater 25 and then mixed with the brine, and when the soft water passing through the heat exchanger 20 is summer, a higher temperature than necessary. In order to prevent the heating by the second bypass pipe 71 is connected directly without passing through the electric heater 25 so that the soft water is supplied directly to the salt water flow meter (45).

Therefore, the first bypass pipe 56 is attached to the reaction heat of sodium hypochlorite generated in the electrolysis device 15 during the winter, and the soft water for diluting the brine is primarily heated by using an independent heat exchanger 20. By supplying 3% salt water to the electrolysis device 15 by adjusting the temperature to an appropriate temperature with the electric heater 25, supplying soft water by using a bypass and an independent electric heater 25 in case of failure of a pinhole to the heat exchanger 20. By doing so, the temperature of the salt water can be controlled constantly.

In addition, in order to maintain the proper temperature of the dilute brine supplied to the electrolysis device 15, the heat exchanger 20 for heat-exchanging the reaction heat generated when sodium hypochlorite is generated in the electrolysis device 15 with the soft water supplied with the dilution water of the brine; Since the electric heater 25 to properly control the temperature of the soft water for dilution after heat exchange is formed independently of each other, there is an effect that does not become a higher temperature than necessary or reduces unnecessary power consumption.

As described above, the present invention primarily heats the brine dilution soft water using an independent heat exchanger equipped with a bypass tube to heat the reaction heat of sodium hypochlorite generated in the electrolysis device in winter, and then, it is appropriate to use an independent electric heater device. By supplying 3% salt water to the electrolysis device by controlling the temperature, the temperature of the salt water can be controlled constantly by supplying soft water by bypass and an independent electric heater device when a pinhole or the like occurs in the heat exchanger.

In addition, in order to maintain the proper temperature of the dilute brine supplied to the electrolysis device, the heat exchanger for heat-exchanging the reaction heat generated when sodium hypochlorite is generated in the electrolysis device with the brine dilution water and the temperature of the dilution soft water after heat exchange are properly controlled. Each soft electric heating device is formed independently so that it does not become too hot or reduces unnecessary power consumption.

Claims (3)

In a sodium hypochlorite generation system that produces sodium hypochlorite, A water softener 50 for manufacturing and supplying general water introduced from the outside into soft water; A brine storage tank 10 for storing brine and supplying the electrolysis device 15 through the brine flow tube 60; A brine brine flow pipe (60) through which the brine discharged from the brine storage tank (10) flows; A flow pump 40 installed in the brine brine flow tube 60 for flowing brine; A plurality of brine flowmeters 45 installed between the brine flow pipe 60 and the electrolysis device 15 to dilute the brine and the soft water flowing through the brine flow pipe 60 to make a low concentration of brine; Soft water supply pipe 55 for connecting the water softener and the brine flow meter (45) so that the soft water discharged from the water softener (50) is mixed with the brine in the brine flow meter (45) and diluted with low concentration of brine; An electrolysis device (15) for generating sodium hypochlorite by electrolyzing a low concentration of brine diluted in the brine flow meter (45) with a direct current power supplied from the rectifier (75); Sodium hypochlorite storage tank 30, the sodium hypochlorite generated in the electrolysis device 15 flows to the discharge pipe 35 and is stored; A heat exchanger 20 installed in the sodium hypochlorite discharge pipe 35 connecting the electrolysis device 15 and the sodium hypochlorite storage tank 30 to transfer the reaction heat generated during the electrolysis reaction to the soft water supply pipe 55. Wow; An electric heater 25 installed between the soft water supply pipe 55 through which the soft water passing through the heat exchanger 20 flows and the electrolysis device 15 to heat the soft water; First and second bypass pipes 56 and 71 through which soft water flows directly without passing through the heat exchanger 20 or the electric heater 25; A shutoff valve (65) selectively available to allow soft water to flow into the heat exchanger (20) or the electric heater (25) or to flow through the first and second bypass pipes (56, 71); Sodium hypochlorite generation system with soft water temperature control device characterized in that configured to include. The method of claim 1, The first and second bypass pipes 56 and 71 are installed at different positions, respectively, and the first bypass pipe 56 is connected to the soft water supply pipe 55 passing through the heat exchanger 20 so that the heat exchanger ( 20) Installed outside, the second bypass pipe 71 is installed in the soft water supply pipe 55 passing through the electric heater 25, the soft water temperature control device, characterized in that it is installed outside the electric heater 25 Sodium hypochlorite generation system equipped with. The method of claim 1, The shut-off shutoff valve 65 is installed at both sides of the soft water supply pipe 55 passing through the heat exchanger 20 and the electric heater 25, and at any one of the first and second bypass pipes 56, 71. Sodium hypochlorite generation system with soft water temperature control device characterized in that it is installed.

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