KR100503662B1 - Structure for interrupting contact of hot water to ion exchange membrane in water softener - Google Patents

Abstract

The present invention relates to a hot water blocking structure for protecting an ion exchange membrane of a water softener, comprising: a hollow case having an inlet and an outlet of a fluid; an ion exchange membrane disposed at a predetermined distance from an inner surface of the case to form a deionized water cell of a predetermined width; An electrode plate which is spaced apart from the ion exchange membrane at a predetermined interval to form a flow path having a predetermined width between the ion exchange membrane, a blocking film provided on the flow path to shield one surface of the ion exchange membrane, and an outer surface of the blocking membrane. Rotatingly coupled through the electrode plate and including the adjustment handle drawn out of the case, the shaft end of the adjustment handle and the connecting portion of the case is formed of a screw structure by the screw portion to each other to allow the inner and outer movement of the blocking film The blocking membrane is adapted to shield the ion exchange membrane by the rotation of the adjusting handle. It shall be. As such, the present invention prevents hot water above a predetermined temperature introduced into the water softener from directly contacting the ion exchange membrane, thereby preventing the ion exchange membrane having temperature constraints from being deformed or damaged due to heat of water.

Description

Structure for interrupting contact of hot water to ion exchange membrane in water softener

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water softener employing an electric deionization system, and more particularly, to a hot water blocking structure for protecting an ion exchange membrane for preventing deformation or damage of an ion exchange membrane by blocking access of water above a predetermined temperature to an ion exchange membrane having a temperature constraint.

In general, a softener is a device for supplying soft water by using an ion exchange resin, and regeneration of an ion exchange resin using a regenerating agent is necessary for supplying continuous soft water periodically. The regeneration time of the ion exchange resin is judged according to the amount of raw water passed.When the regeneration time is reached, the raw water is supplied with a regenerant such as salt into the soft water tank to regenerate the ion exchange resin in the soft water tank. You will be able to improve your skills.

However, the recycled waste liquid generated by such a regeneration operation causes serious environmental pollution when discharged to the outside.

In addition, the regeneration efficiency of the ion exchange resin depends on the regeneration method, the amount of regeneration agent, the accuracy of the regeneration operation, if any of these conditions is insufficient, there was a problem that the regeneration efficiency may be lowered.

In order to solve the problems of the water softener, a conventional electric deionization module installed in the water softener is shown in FIG. 1.

The electric deionization module separates and removes salts of ionic components dissolved in a fluid using direct current electricity and an ion exchange membrane, which is a conductive porous membrane. A conventional electric deionization module as shown in FIG. A cylindrical housing (10) having a fluid outlet (12) formed at a lower portion thereof; Inside the cylindrical housing 10, one side is blocked at the center and a cylindrical water collecting pipe 70 formed with a plurality of water collecting pipe holes 71 at the periphery thereof, and a carbon around the cylindrical water collecting pipe 70 is installed. It is formed of two sheets of membranes made of a membrane by mixing a cloth or a filter made of fiber and carbon black or a metal powder with a resin, and each of the two sheets of ion exchange membrane 50 having the anode and the cathode electrode 40 connected thereto. Between the two sheets of ion exchange membrane 50, a porous mesh 60 made of an insulator which is not electrically conductive is installed between the two sheets of ion exchange membrane 50 and rolled into a cylindrical shape so that the module 100 is formed in the cylindrical housing. It is comprised by inserting and installing in 10 so that it may have a predetermined space | interval.

A module upper cover 30 having two electrodes 40 is fixed to the upper portion of the ion exchange membrane 50 installed in the housing 10 by the tightening nut 20, and a water collecting tube 70 is disposed below. It has a protruding module lower cover 80, the module upper cover 30 has two O-ring grooves (not shown) so that fluid does not flow to the top when the module 100 is mounted in the housing 10 for mounting the module (100) 32) and an O-ring 31 therein.

The porous mesh 60 is a woven cloth or a non-woven fabric or a plastic mesh formed with a plurality of holes, and wraps around the module 100 inserted into the housing 10.

In the conventional module 100, fluid is supplied through the inlet 11 and introduced into the ion exchange membrane 50 to which positive (+) DC electricity is applied through the porous mesh 60 on the surface of the module 100. As the fluid passes through the ion exchange membrane 50 to which negative electricity is applied through the porous mesh 60, the cationic component of the ionic salts in the fluid adheres to the membrane to which negative electricity is applied. Then, the anion component is attached to the membrane to which positive (+) electricity is applied and separated, and the treated water is collected at the collecting pipe 70 and exits to the fluid outlet 12.

In this case, the large particle materials in the inflow fluid are filtered through the porous mesh 60 on the surface of the module 100 to reduce contamination of the ion exchange membrane 50. In addition, the O-ring 31 fitted in the upper module cover 30 prevents the fluid from flowing out during operation.

In the conventional electric deionization module having such a configuration, a direct current is applied to the ion exchange membrane 50, which is a conductive material, and salt ions of cationic components such as calcium ions (Ca ++), magnesium ions (Mg ++), and sodium ions (Na +) The negative electrode is attached to and separated from the cationic membrane to which the negative electrode is applied, and the salt ions of anion such as chlorine ion (Cl-) and sulfate ion (SO4--) are attached to and separated from the negative electrode to which the positive electrode is applied by the positive electrode. Thus, the salt component in the fluid is desalted by using the principle of separating ions of the salt component.

As described above, the electric deionization module is a method of purifying or softening the raw water by deionizing raw water using an ion exchange membrane, an ion exchange resin, and an electrode. The electric deionization module applied to the water softener is deionized and regenerated without regenerating agents. The process will be carried out.

However, when the electric deionization module of the conventional structure as described above is applied to a water softener, the ion exchange membrane generally has temperature constraints, and thus, when hot water is introduced at a predetermined temperature or more, the ion exchange membrane is damaged. When using hot water of more than 45 ℃ there was a problem that the application is limited.

The present invention has been made to solve the conventional problems as described above, the hot water blocking structure for protecting the ion exchange membrane to prevent deformation or damage of the ion exchange membrane by blocking the access of water above a certain temperature to the temperature-exchange ion exchange membrane. The purpose is to provide.

The present invention for achieving the above object is a softening system for softening the raw water through the ion exchange treatment and discharge, the hollow case having the inlet and outlet of the fluid, and a predetermined interval spaced from the inner surface of the case An ion exchange membrane for forming a deionized water cell having a width; an electrode plate spaced apart from the outside of the ion exchange membrane at a predetermined interval to form a predetermined width flow path between the ion exchange membrane; And a blocking film for shielding one surface, and an adjusting handle rotatably coupled to an outer surface of the blocking film and drawn out of the case through the electrode plate, wherein the shaft ends of the adjusting handle and the connection portion of the case are formed inside and outside of the blocking film. It is made of a screwed structure by the screw portion to each other so that the movement by the rotation of the adjustment handle Provided is a hot water blocking structure for protecting the ion exchange membrane of the softener, characterized in that the single membrane is to shield the ion exchange membrane.

A cover member spaced apart from an inner surface of the case is provided at both ends of the ion exchange membrane, and a stepped portion is formed at both ends of the cover member to be in close contact with each other. When the fluid introduced through the inlet is below a predetermined temperature, Direction while the blocking membrane is kept spaced apart from the stepped portion, the introduced fluid is introduced into the deionized water cell through the ion exchange membrane and discharged to the outlet, and when the fluid introduced through the inlet is above a predetermined temperature, the adjustment is performed. The handle is rotated in the other direction to shield the ion exchange membrane while the blocking membrane is in close contact with the stepped portion so that the inflowed fluid is discharged through the flow path to the outlet.

As such, the present invention prevents hot water above a predetermined temperature introduced into the water softener from directly contacting the ion exchange membrane, thereby preventing the ion exchange membrane having temperature constraints from being deformed or damaged due to heat of water.

Hereinafter, with reference to the accompanying drawings illustrating a preferred embodiment of the door sliding structure for the front drain of the water purifier of the present invention.

2 is a front sectional view showing a hot water blocking structure for protecting an ion exchange membrane of a water softener according to the present invention, showing an example of its operation. Figure 3 is a front sectional view showing another example of operation of the hot water blocking structure for protecting the ion exchange membrane of the water softener according to the present invention.

As shown, the water softener 200 according to the present invention includes a plurality of ion exchange membranes 221 and 222 inside the hollow case 210 forming an outer portion. According to one embodiment of the present invention according to FIG. 1, an inlet 211 through which raw water is supplied is formed at a lower end of the case 210, and an outlet 212 through which ion-exchanged soft water exits is formed at an upper end thereof.

The ion exchange membranes 221 and 222 are disposed to correspond to each other at positions spaced a predetermined distance from the inner surface of the case 210 to form cells 220 (hereinafter referred to as 'deionized water cells') having a predetermined width therebetween. do. In addition, inside the case 210, the electrode plates 231 and 232 are provided at positions spaced apart from the ion exchange membranes 221 and 222 by a predetermined distance therebetween, that is, between the ion exchange membranes 221 and 222. A flow path 240 having a predetermined width is formed between the electrode plates 231 and 232. The electrode plates 231 and 232 are divided into a positive electrode (+) and a negative electrode (−) to correspond to each other.

Blocking membranes 241 and 242 are provided on the flow path 240 formed between the ion exchange membranes 221 and 222 and the electrode plates 231 and 232 to shield one surface of the ion exchange membranes 221 and 222. . Referring to the drawings, the blocking films 241 and 242 are disposed at positions adjacent to the electrode plates 231 and 232 in order to secure the channel 240 having a predetermined width, but the present invention is not limited thereto. .

The blocking films 241 and 242 are integrally provided with protrusions 243 extending out of the case 210 while passing through the electrode plates 231 and 232 at one side of the outer surface thereof, preferably at the center of the outer surface thereof. At the end of the protrusion 243 is provided a steering wheel 244 rotatably coupled. An end of the protrusion 243 to which the steering wheel 244 is coupled is formed with a screw portion 243a along its outer circumference, and a screw groove 244b is formed on one surface of the body 244a of the adjustment handle 244. The screw groove 244b is fixed in a screwed state in which the end of the protrusion 243 is inserted.

On the other hand, the upper and lower ends of the ion exchange membrane (221, 222) are provided with cover members 251, 252 spaced apart from the inner surface of the case 210, respectively, on both ends of each cover member (251, 252) Stepped portions 251a and 252a are formed to contact the blocking layers 241 and 242. Although not shown in the drawing, the cover member 251 is provided in a structure penetrated at the center so that the ion-exchanged water can exit the deionized water cell 220.

The water softener 200 of the present invention from such a coupling structure to hold the handle 244c of the steering wheel 244 to rotate the steering wheel 244 in either of the left and right directions, the rotation of the steering wheel 244 The movement results in a linear movement of the protrusion 243 joined together. As a result, the projections 243 formed in the blocking films 241 and 242 by the rotation of the steering wheel 244 slide in and out of the screw grooves 244b formed in the body 244a along the axial direction thereof. 242 is moved.

2, when the water introduced through the inlet 211 in the water softener 200 of the present invention is below a predetermined temperature (eg, 45 ° C.), the blocking handle 241 is rotated in one direction. ) 242 is to be kept spaced apart from the step portion (251a) (252a). In this case, the introduced water is introduced into the deionized water cell 220 through the ion exchange membranes 221 and 222 in a deionized state by the electrode plates 231 and 232, and then the deionized water cell 220 of the deionized water cell 220. The hardness component is removed by the ion exchange resin 201 filled therein to soften and discharge to the outside through the outlet 212.

Referring to FIG. 3, when the water introduced through the inlet 211 is above a predetermined temperature (eg, 45 ° C.), the steering wheel 244 is rotated in another direction to block the barrier membranes 241 and 242. The ion exchange membranes 221 and 222 are shielded in close contact with the portions 251a and 252a. The ion exchange membranes 221 and 222 in which access of water is blocked by the blocking membranes 241 and 242 can overcome problems such as appearance damage due to heat of water. On the other hand, the introduced water is discharged to the outside through the outlet 212 in a deionized state while flowing along the flow path 240 positioned outside the blocking membranes 241 and 242.

In the above, the present invention shows and describes the protection of the ion exchange membrane by the coupling structure of the blocking membrane, the protrusion and the steering wheel, which is a preferred embodiment shown in the accompanying drawings, but is not limited thereto. It is apparent that the invention can be modified in various forms within the scope of the technical idea described in the claims below.

As described above, the present invention prevents the hot water of a predetermined temperature or more introduced into the water softener from being in direct contact with the ion exchange membrane, thereby preventing the ion exchange membrane having temperature constraints from being deformed or damaged due to the heat of the water. .

1 is a front sectional view showing a conventional electric deionization module

Figure 2 is a front cross-sectional view showing an example of operation of the hot water blocking structure for protecting the ion exchange membrane of the water softener according to the present invention.

Figure 3 is a front sectional view showing another example of operation of the hot water blocking structure for protecting the ion exchange membrane of the water softener according to the present invention.

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

200: water softener 210: case

211: inlet 212: outlet

220 cell 221 222 ion exchange membrane

231,232 electrode plate 240 flow path

241,242: barrier 243: protrusion

244: steering wheel 244a: body

244b: Screw groove 251,252: Cover member

251a, 252a: stepped portion

Claims (2)

In the softening system that discharges the raw water by ion exchange treatment, A hollow case having a fluid inlet and an outlet, an ion exchange membrane spaced apart from an inner surface of the case to form a deionized water cell, and an electrode spaced apart from the outside of the ion exchange membrane to form a flow path between the ion exchange membrane A plate, a blocking film provided on the flow path to shield one surface of the ion exchange membrane, and an adjustment handle rotatably coupled to an outer surface of the blocking film and drawn out of the case through the electrode plate. The shaft end of the adjusting handle and the connecting portion of the case are formed in a screwed structure by the screw portion to allow the inner and outer movement of the blocking membrane so that the blocking membrane shields the ion exchange membrane by the rotation of the adjusting handle. Hot water shutoff structure. The method of claim 1, A cover member spaced apart from an inner surface of the case is provided at both ends of the ion exchange membrane, and a stepped portion is formed at both ends of the cover member to be in close contact with each other. When the temperature of the fluid introduced through the inlet is lower than a set value, the adjustment handle When the blocking membrane is rotated in one direction and kept in a state spaced apart from the stepped portion, the introduced fluid is introduced into the deionized water cell through the ion exchange membrane and discharged to the outlet, and when the temperature of the fluid introduced through the inlet is higher than a set value, Rotating the adjusting handle in the other direction to shield the ion exchange membrane in a state in which the blocking membrane is in close contact with the stepped portion so that the introduced fluid is discharged through the flow path to the outlet through the water heater. rescue.