KR100683884B1 - Inoniser and ion purifier for using the same - Google Patents

Abstract

An electrolytic cell which can prevent damage of the electrolytic cell by installing a safety valve at an electrolytic cell body, thereby reducing an internal pressure of the electrolytic cell, and an ion water purifier using the same are provided. An electrolytic cell comprises: an electrolytic cell body which includes an electrode and a case for covering the electrode to produce ion water by electrolyzing water; and a safety valve installed on the electrolytic cell body to reduce an internal pressure of the electrolytic cell body. The electrolytic cell body has an inflow port, a product water discharge port and an effluent discharge port formed therein, and the safety valve is installed on the effluent discharge port. The safety valve is installed in such a way that it is branched off from the effluent discharge port, and the safety valve comprises a first housing(61) on which a pressure-reducing inflow port(65) is formed, a plunger(64) disposed within the first housing to open or close the pressure-reducing inflow port, a spring(63) for applying elasticity to the plunger, a valve connection part connected to the first housing by a screw, and a pipe-connecting part formed on the valve connection part such that a cross-sectional area of the pipe-connecting part is reduced to form a step height.

Description

Electrolyzer and ionizer using it {inoniser and ion purifier for using the same}

1 is a front view of an electrolytic cell according to a preferred embodiment of the present invention.

2 is a side view of an electrolytic cell according to a preferred embodiment of the present invention.

3 is a cross-sectional view of a safety valve according to a preferred embodiment of the present invention.

Figure 4 is a cross-sectional view of the safety valve according to another embodiment of the present invention.

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

10, 20: inlet 30: product water supply outlet

40: discharge outlet 50: housing

51: protrusion coupling portion 52: groove

53: projection 60: safety valve

60a: safety valve bracket 61: first housing

62: support portion 62a: seating groove

62b: Tool groove 63: Spring

64: plunger 65: decompression inlet

66: inside the first housing 67: the second housing

68: thread 69: jamming jaw

The present invention relates to an electrolyzer and an ionizer using the same, and in particular, the electrolyzer body is provided with a safety valve, to reduce the pressure in the electrolyzer, and to an electrolyzer and an ionizer using the same that can prevent damage to the electrolyzer.

Due to the recent environmental problems such as water quality, air, and soil caused by the recent industrial development, general households and offices purify the water by the filter as a means to provide clean drinking water, and thus select the purified water. Cooling or heating according to the cold, hot water to be supplied to the hot water is a situation that is widely used.

As such an ionizer, there is one as shown in Korean Patent Laid-Open Publication No. 2004-0110320.

The conventional ionizer includes a filter unit for filtering raw water and an electrolytic cell for generating alkaline water and acidic water by electrolyzing the filtered purified water.

Such a conventional electrolyzer has a problem in that the electrolyzer is damaged due to an increase in the pressure inside the electrolyzer due to an influence on the pressure of raw water obtained during operation of the ionizer, a blockage or malfunction of the outlet solenoid valve, or a blockage by the electrolyzer scale.

The present invention has been made to solve the above-mentioned problems, the electrolytic cell body is provided with a safety valve, the purpose of providing an electrolytic cell and an ionizer using the same to reduce the pressure of the electrolytic cell by reducing the pressure inside the electrolytic cell. .

The electrolytic cell of the present invention for achieving the above object is characterized in that it comprises an electrolytic cell body for generating ionized water by electrolysis of water, and a safety valve provided in the electrolytic cell body.

According to this configuration, it is possible to prevent the pressure inside the electrolytic cell from rising and prevent damage to the electrolytic cell.

In the above configuration, the electrolytic cell main body is formed with an inlet, a product water outlet and a discharge outlet, the safety valve is installed in the discharge outlet, the discharge of the discharge to reduce the pressure in the electrolytic cell to reduce the product water, etc. Can be prevented.

The safety valve is installed branched to the discharge outlet, the safety valve is a first housing having a pressure reducing inlet, a plunger disposed in the first housing to open and close the pressure reducing inlet, a spring for applying elasticity to the plunger And a second housing including a valve connecting portion screwed to the first housing and a pipe connecting portion formed stepwise so that the cross-sectional area of the valve connecting portion is reduced, the structure has a simple advantage.

The safety valve is branched downward in the discharge outlet, the safety valve bracket for mounting the safety valve is formed in the electrolytic cell body, it is possible to keep the electrolytic cell compact.

The plunger includes a main body, a fixing protrusion formed at one end of the main body and fitted into the spring, and a guide part formed at the other end of the main body to guide the movement of the plunger, thereby preventing the spring from being detached, and when the plunger is pressurized. If the pressure is released after retreating, it is possible to return to the initial position.

The ionizer of the present invention is characterized by comprising an electrolytic cell comprising a filter portion for filtering raw water, an electrolytic cell body for generating ionized water by electrolyzing the filtered purified water, and a safety valve provided in the electrolytic cell body.

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

For reference, among the configurations of the present invention to be described below, the same configuration as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

1 is a front view of an electrolytic cell according to a preferred embodiment of the present invention, Figure 2 is a side view of the electrolytic cell of Figure 1, Figure 3 is a cross-sectional view of the safety valve of FIG. 4 is a cross-sectional view of a safety valve according to another embodiment of the present invention.

1 to 3, the ionizer of the present embodiment includes a filter unit for filtering raw water and an electrolytic cell 100 for generating alkaline water and acidic water by electrolyzing the filtered purified water.

The filter unit filters the introduced raw water to provide purified water.

The electrolytic cell 100 is disposed at the rear end of the filter unit to generate acidic and alkaline water by electrolyzing the filtered purified water.

The electrolyzer 100 comprises an electrolyzer body in which an outlet opening is formed, and a safety valve 60 installed in the electrolyzer body.

The electrolyzer body includes an electrode and a case 50 surrounding the electrode.

The case 50 has inlets 10 and 20 and outlets 30 and 40, two inlets 10 and 20 are formed below the case 50, and outlets 30 and 40 are case 50. It is formed on the top.

The outlets 30 and 40 may include a product water outlet 30 through which the product water is discharged and a discharge water outlet 40 through which the water is discharged.

The drain outlet 40 is provided with a drain valve (not shown) for adjusting the amount of drainage.

In addition, the case 50 is formed with a protrusion coupling portion 51 formed with a perforation so that the electrolytic cell 50 can be fixed in the ionizer near the inlets 10 and 20 and the outlets 30 and 40. Protruding coupling portion 51 may be formed in this way one by one in the upper center and left and right, one in the lower left and right.

A groove 52 is formed in a honeycomb shape on the front surface of the case 50, and a protrusion 53 is formed in the width direction on the side surface of the case 50.

The safety valve 60 is branched to the discharge outlet 40 so as to communicate with the discharge outlet 40.

In this way, the safety valve 60 is branched to the discharge water outlet 40, and the loss of product water can be prevented by distilling the discharge water to reduce the pressure.

The safety valve 60 is disposed in the first housing 61 and the first housing 61 in which the pressure reducing inlet 65 communicates with the discharge outlet 40, and the plunger opening and closing the pressure reducing inlet 65. (64), a spring (63) disposed inside the first housing (61) to apply an elastic force to the plunger (64), a valve connection portion screwed to the first housing (61), and a cross-sectional area of the valve connection portion to be small. It comprises a second housing (67) made of a pipe connection formed stepped.

When the pressure inside the electrolyzer 100 increases, the pressure of the product water outlet 30 and the discharge outlet 40 formed in the electrolyzer 100 naturally increases, and the safety valve 60 mounted to communicate with the discharge outlet 40. When pressure is transmitted to the plunger 64, the plunger 64 overcomes the elastic force of the spring 63 and retracts, so that the plunger 64 is discharged into the interior 66 of the first housing 61 to reduce the pressure inside the electrolytic cell 100. do.

The plunger 64 has a conical shape and a main body is caught by the locking jaw 69 formed in the first housing 61, and one end of the main body has a long rod shape to face the pressure reducing inlet 65 ( Guide rod), and a fixing protrusion is formed at the other end to face the spring 63.

Due to the guide rods as described above, even when the plunger 64 is retracted by the pressure in the electrolytic cell 100, the guide rods are hung on the pressure reducing inlet 65 so that the applied pressure is eliminated and the plunger 64 is separated by the guide rods. It will be placed in the initial position.

One end of the spring 63 is seated in the seating groove 62a of the support portion 62, and the other end is fitted to the fixing protrusion of the plunger 64, so that the spring 63 is not easily detached.

The support portion 62 is fitted to the opposite end of the connection portion with the discharge outlet 40 in the first housing 61, and the thread 68 is formed and screwed to the inner circumferential surface of the first housing 61 and the outer circumferential surface of the support portion 62. .

As such, the support 62 and the first housing 61 are screwed together to freely adjust the position of the support 62 to adjust the pressure at which the plunger 64 can be retracted.

That is, when the support 62 is rotated a lot and disposed on the pressure reducing inlet 65 side, the spring 63 exerts great elasticity on the plunger 64, and the support 62 is rotated less so that the pressure reducing oil chip opening 65 side. Placed away from the spring 63 exerts a small elasticity on the plunger 64.

The support 62 has a seating groove 62a through which the spring 63 can be seated, and a tool groove 62b is provided on the rear surface thereof so that the support 62 can be easily detached from the first housing 61. Formed.

In addition, the support part 62 is formed with an outlet hole so that the inflow of the introduced water can flow out.

A connection part is formed at one end of the first housing 61 so as to be connected to the discharge water discharge pipe 40, and a thread is formed at an outer circumferential surface of the first housing 61 so as to be connected to the valve connection part of the second housing 67.

In addition, the second housing 67 is formed in the pipe connecting portion formed stepped so that the cross-sectional area of the valve connecting portion is small, the pipe connected to the discharge port side is connected to the pipe connecting portion.

A pressure reducing outlet is formed in the second housing 67 so as to communicate with the pressure reducing inlet 65.

Unlike the above, as shown in Figure 4, the safety valve 60, the support and the second housing is integrated, the spring 63 is supported on the supporting jaw formed in the second housing 67, A thread is formed on the inner circumferential surface of the second housing 67 and the outer circumferential surface of the first housing 61 to be screwed together.

As a result, when the decompression flows into the first housing 61, the discharged water is discharged through the second housing 67, thereby reducing the pressure in the electrolytic cell 100.

The safety valve 60 is installed branched downward to the discharge outlet 40, the safety valve bracket (60a) for mounting the safety valve 60 is formed in the electrolytic cell body.

The safety valve bracket 60a is preferably formed in the shape of a snap groove having a cylindrical shape having a cutout at one side thereof, so that the safety valve 60 can be easily detached.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or variations of the present invention without departing from the spirit and scope of the invention described in the claims below Can be carried out.

According to the electrolytic cell of the present invention as described above and the ionizer using the same, there are the following effects.

A safety valve is provided in the electrolytic cell body, so that damage to the electrolytic cell can be prevented by reducing the pressure inside the electrolytic cell.

The electrolyzer body has an inlet, a product water outlet, and a discharge outlet, and the safety valve is installed at the outlet, and discharges the discharge to reduce the pressure in the electrolyzer to effectively reduce the pressure inside the electrolyzer. The loss of the number of products can be prevented.

The safety valve is installed branched to the discharge outlet, the safety valve is a first housing having a pressure reducing inlet, a plunger disposed in the first housing to open and close the pressure reducing inlet, a spring for applying elasticity to the plunger And a second housing including a valve connecting portion screwed to the first housing and a pipe connecting portion formed stepwise so that the cross-sectional area of the valve connecting portion is reduced, the structure has a simple advantage.

The safety valve is branched downward in the discharge outlet, the safety valve bracket for mounting the safety valve is formed in the electrolytic cell body, it is possible to keep the electrolytic cell compact.

The plunger includes a main body, a fixing protrusion formed at one end of the main body and fitted into the spring, and a guide part formed at the other end of the main body to guide the movement of the plunger, so that the pressure applied to the plunger is removed. The plunger is placed in the initial position by the rod, and the spring is not easily released from the plunger by the fixing protrusion.

Claims (7)

An electrolyzer body including an electrode and a case surrounding the electrode to generate ionized water by electrolyzing water; And an safety valve installed on the electrolyzer body to reduce pressure in the electrolyzer body. The method of claim 1, The electrolyzer body is formed with an inlet, a product water outlet and a discharge outlet, the safety valve is characterized in that installed in the discharge outlet. The method of claim 2, The safety valve is installed branched to the discharge outlet, The safety valve may include a first housing having a pressure reducing inlet, a plunger disposed inside the first housing to open and close the pressure reducing inlet, a spring for elastically applying the plunger, and a valve connecting portion screwed to the first housing; Electrolytic cell comprising a second housing made of a pipe connecting portion formed stepped so that the cross-sectional area of the valve connecting portion is small. The method of claim 3, The safety valve is branched downwardly installed in the discharge outlet, the electrolytic cell, characterized in that the electrolytic cell body is formed with a safety valve bracket for mounting the safety valve. The method according to claim 3 or 4, The plunger includes a main body, a fixing protrusion formed at one end of the main body and fitted into the spring, and a guide part formed at the other end of the main body to guide the movement of the plunger. A filter unit disposed at the front of the electrolytic cell to filter raw water; An electrolyzer body including an electrode and a case surrounding the electrode to electrolyze the filtered purified water to generate ionized water, and an electrolyzer formed on the electrolyzer body to reduce pressure inside the electrolyzer body. Ionizer. The method of claim 6, The electrolytic cell main body is formed with an inlet, a product water outlet and a discharge outlet, the safety valve is characterized in that installed in the discharge outlet.

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