KR200263073Y1 - Repellent Resistor for Reverse Osmosis Water Purifier - Google Patents

Abstract

The present invention relates to a reverse osmosis water purifier that purifies tap water, while maintaining the inside of the membrane at a constant pressure without using a pressure control tube having a small inner diameter, and allowing the foreign substances in the membrane to be quickly discharged to the outside and at the same time, a repellent resistor. It is possible to disassemble and assemble so that even if scale accumulates in the resistive resistor, it can be cleaned and reused without replacing the expensive resistive resistor.

To this end, a cap 20 having a discharge inlet 22 formed therein, a housing 21 coupled with the cap and having a discharge outlet 23 formed therein, and a discharge passage 26a and 26b installed at the same time as the cap and the housing are installed. Pipe bobbin 25, which is divided into a temporary partition wall 27 and is provided with a spiral discharge groove 28 on its outer circumferential surface, and has a discharge inflow hole 29 and a discharge discharge hole 30 formed on the discharge groove, and the discharge water formed in the cap. The filter 31 is installed on the inlet side to filter foreign substances from entering the pipe bobbin side.

Description

Repellent Resistor for Reverse Osmosis Water Purifier

The present invention relates to a reverse osmosis water purifier that purifies tap water, and more specifically, to discharge water that has not passed through the membrane to the outside with a foreign substance while maintaining the inside of the membrane at a predetermined pressure when tap water is purified. Relates to a resistor.

1 is a schematic view showing the structure of a general reverse osmosis water purifier, the structure of which is as follows.

The inlet pipe 1 of the tap water is provided with a cement filter 2 for filtering out foreign substances such as sand and hair contained in the tap water, and the first connecting pipe 3 connected to the discharge side of the cement filter is connected to the tap water. A carbon filter 4 is installed to remove residual chlorine contained in the tap water due to disinfection, and a membrane 6, which is a reverse osmosis filter, is installed in the second connection pipe 5 connected to the discharge side of the carbon filter.

The membrane 6 is embedded in a state in which a fiber having a microstructure is wound in a roll shape, and is called a membrane between the fibers wound in a roll shape.

And the activated carbon filter 8 for removing odor is installed in the third connecting pipe (7) connected to the discharge side of the membrane (6), the other side of the membrane is a certain foreign matter introduced into the membrane (6) A water discharge resistor 9 for discharging to the outside while maintaining the pressure is connected to the fourth connecting pipe 10, and a discharge pipe 11 is connected to the discharge side of the activated carbon filter 8.

Therefore, when tap water is introduced into the cement filter 2 through the inlet pipe 1, the introduced tap water passes through a thread having a tissue of about 10 μm, and foreign substances such as sand or hair contained in the tap water are filtered out. Furnace flows into the carbon filter (4) side through the first connecting pipe (3).

In this way, when the filtered tap water is introduced into the carbon filter 4, the tap water is used for disinfection of the tap water. Therefore, residual chlorine contained in the tap water passes through the carbon filter 4 and reacts with the carbon to be removed. It enters into the membrane 6 through the connecting pipe 5.

Thereafter, the tap water is purified in a very clean state while passing through the membrane of the fibers embedded in the membrane 6, where the pressure inside the membrane is maintained at a very high pressure of about 5-10 kg / cm 2.

As described above, while the tap water introduced into the membrane 6 through the second connecting pipe 5 is purified, the repellent resistor 9 connected with the membrane maintains a constant pressure inside the membrane and simultaneously It will play a role to discharge foreign substances to the outside.

FIG. 2 is a longitudinal cross-sectional view showing a conventional repellent resistor, in which a pressure regulating tube 13 having a very small inner diameter (about 0.5 to 1.0 mm) is wound around the support 14 in a coil shape. It is built in and both ends of the pressure control tube 13 is fixed to both side plates 15 of the housing 12, the number of windings and the inner diameter of the pressure control tube 13 wound on the support 14 is It is set differently according to the amount of discharged water according to the amount of water produced.

In the housing 12 having the above-described structure, the epoxy 16 is filled during the assembly operation of the repellent resistor so that the pressure control tube 13 is not deformed by the high pressure applied to the inside of the membrane 6.

In addition, the caps 18a and 18b having the adapters 17a and 17b assembled therein are respectively coupled to the inflow and outflow sides of the housing 12, and the inflow of foreign substances into the adapter 17a located at the inflow and outflow sides. The strainer 19 to prevent the assembly is assembled.

However, the conventional resistive resistor having such a structure has the following problems.

First, since the discharge amount is determined by the diameter and length of the pressure regulating tube 13, it is necessary to provide several kinds of pressure regulating tubes having different diameters according to the capacity of the water purifier. When broken or deformed, there was a fatal defect that prevented it from playing the role of a drainage resistor.

Second, since the inner diameter of the pressure control tube 13 is very small and currently cannot be produced in Korea, it relies on all imports, resulting in waste of foreign currency.

Third, when the strainer 19 in the adapter 17a located on the inflow side is damaged, and the carbon in the carbon filter 4 flows into the membrane 6, the pressure control tube 13 having a small inner diameter is transferred to the carbon or the like. It was blocked by the pressure inside the membrane 6 can not control the pressure in the membrane resulting in a sharp rise, so that the expensive membrane bursts showed a fatal defect.

Fourth, since the pressure control tube 13 assembled in the housing 12 is not deformed, the epoxy 12 must be filled in the housing 12 during the assembly operation of the repellent resistor. It became.

Fifth, since the pressure control tube 13 is filled with epoxy in the housing 12 and cannot be decomposed, the scale is generated inside the pressure control tube by calcium contained in the water having high hardness when repeated use, so that expensive discharge The resistors had to be replaced periodically (about 2 to 3 years).

The present invention has been made to solve such a problem in the prior art, a repellent resistor that can quickly discharge the foreign matter in the membrane to the outside while maintaining the inside of the membrane at a constant pressure without using a pressure control tube with a small inner diameter The purpose is to provide.

Another object of the present invention is to disassemble and assemble the resistive resistor so that even if the scale is accumulated in the resistive resistor can be cleaned and reused without replacing the expensive resistive resistor.

According to a form of the present invention for achieving the above object, the cap is formed with a discharge inlet, a housing coupled to the cap and the discharge outlet is formed, and the discharge passage is partitioned into a partition wall and spirally formed on the outer peripheral surface while being installed in the cap and the housing. Reverse osmosis water purifier, characterized in that it is provided with a dewatering groove of the pipe bobbin is formed in the inlet and the discharge outlet hole, and the filter is installed on the inlet side formed in the cap to filter foreign matter into the pipe bobbin side Repellent resistors are provided.

1 is a schematic view showing the structure of a general reverse osmosis water purifier

Figure 2 is a longitudinal cross-sectional view showing the structure of a conventional resistive resistor

Figure 3 is an exploded perspective view showing the resistive resistor of the present invention

Figure 4 is a longitudinal cross-sectional view showing the resistive resistor of the present invention

5 is an enlarged longitudinal sectional view showing a pipe bobbin which is a main part of the present invention;

Explanation of symbols for main parts in the drawings

20: cap 21: housing

22: discharge inlet 23: discharge outlet

25: pipe bobbin 26a, 26b: discharge passage

27: bulkhead 28: draining groove

29: discharge water inlet hole 30: discharge water outlet

31: filter

Hereinafter, with reference to Figures 3 to 5 showing an embodiment of the present invention in more detail as follows.

Figure 3 is an exploded perspective view showing the water discharge resistor of the present invention, Figure 4 is a longitudinal cross-sectional view showing the water discharge resistor of the present invention, Figure 5 is a longitudinal cross-sectional view showing an enlarged pipe bobbin that is the main part of the invention, the present invention is a discharge water inlet ( 22 and the cap 20 and the housing 21 in which the discharge outlet 23 is formed are dividedly formed to be disassembled and assembled, and they are screwed together.

Connectors 24a and 24b for connecting the fourth connection pipe 10 and the discharge pipe 11 are respectively coupled to the water discharge inlet 22 and the water discharge outlet 23 formed in the cap 20 and the housing 21. It is.

In the cap 20 and the housing 21, a pipe bobbin 25 as shown in FIG. 5, which is a main part of the present invention, is installed to be disassembled and coupled, and the pipe bobbin 25 has a discharge passage 26a formed at both sides thereof. (26b) is partitioned into the partition wall 27, the outer peripheral surface is provided with a spiral discharge groove 28, the discharge water inlet 29 and the discharge water discharge hole 30 is formed on the discharge groove.

The cross-sectional area of the water discharge groove 28 formed on the outer circumferential surface of the pipe bobbin 25 can be arbitrarily set according to the water discharge capacity, and the water discharge inlet 29 and the water discharge hole formed on the water discharge groove 28 are also provided. The position of 30 can be arbitrarily adjusted according to the capacity of the water purifier.

That is, in the case of the pipe bobbin 25 formed with the drainage groove 28 having the same cross-sectional area, the drainage inflow hole 29 and the drainage discharge formed on the drainage groove 28 to adjust the amount of drainage according to the capacity of the water purifier. If the distance of the ball 30 is set farther as shown by the solid line in FIG. 5, the amount of discharged water is minimized, and on the contrary, the distance between the discharged water inlet 29 and the discharged water outlet 30 is set close as shown by the dotted line. This will maximize the discharge.

The pipe bobbin 25 may be injection molded using a synthetic resin, so that mass production is possible, and assembling work is also facilitated.

In addition, it is understood that the amount of discharged water can be adjusted by adjusting the size of the discharged water inlet 29 and the discharged water discharge hole 30 formed on the discharged water groove 28.

On the other hand, the water discharge inlet 22 formed in the cap 20 is provided with a filter 31 for filtering foreign matter flowing into the pipe bobbin 25 side.

Referring to the operation of the present invention configured as described above are as follows.

The length and the cross-sectional area of the drain groove 28 formed in the pipe bobbin 25 are determined according to the set pressure and the capacity of the membrane 6, and at the same time, the drain inflow hole 29 and the drain water formed on the drain groove 28 are formed. The position and size of the discharge hole 30 is determined, and the pipe bobbin 25 having the above structure places the filter 31 on the upper side while being inserted into the housing 21 as shown in FIG. 4 and the cap 20. Assemble the screws to complete the assembly of the resistive resistor.

As a result, it is not necessary to fill the inside of the cap 20 and the housing 21 like the conventional repellent resistor 9.

When the inflow of the membrane 6 into the inside of the ingress resister, that is, through the fourth connecting pipe 10 and the inflow inlet 22, the inflow of the ingress is the inflow passage 26a. (26b) is partitioned into the partition 27 so that the pressure decreases while moving through the discharge passage (26a)-discharge inlet (29)-discharge groove (28)-discharge discharge hole (30)-discharge passage (26b) As the water is discharged in the same state, water is purified through the membrane.

When foreign matter such as carbon in the carbon filter 4 is introduced into the water discharge resistor through the membrane 6 while the water is discharged while adjusting the internal pressure of the membrane 6 by the above-described operation, the pipe bobbin 25 Since the filter 31 installed at the inlet side filters foreign matters, foreign matters do not flow into the drainage grooves 28, and thus, the drainage grooves formed on the pipe bobbin 25 by foreign matters introduced into the water discharge resistors ( 28) There is no fear of clogging.

On the other hand, when a scale is formed on the water discharge groove 28 or the water discharge inlet 29 or the water discharge hole 30 formed in the pipe bobbin 25 by the calcium component contained in the tap water due to long-term use of the water purifier, the screw is coupled. By disassembling the cap 20 and the housing 21, the pipe bobbin 25 is taken out of the housing, the scale is removed, and then recombined, so that the repellent resistor can be used repeatedly.

As described above, the present invention has the following advantages as compared to the conventional water discharge resistor.

First, it is possible to produce a dewatering resistor without using a pressure control pipe that was dependent on imports, thereby saving foreign currency.

Second, according to the pressure in the membrane 6, instead of using a pressure control tube having a different internal diameter, the cross-sectional area of the water repellent groove 28 formed on the outer circumferential surface of the pipe bobbin 25 embedded in the housing 21 may be adjusted. Not only is the number significantly reduced, but the management of parts becomes easier.

Third, when assembling the repellent resistor, it is necessary to wind the pressure control pipe to the support or insert the pipe bobbin 25 and the filter 31 without filling the epoxy, thereby maximizing productivity as well as maximizing productivity. You can do it.

Fourth, since the filter 31 for filtering foreign matters is installed at the inlet 22, the blockage of the drainage groove 28 due to this material is prevented in advance, so that the expensive membrane 6 is damaged. Will be prevented.

Fifth, even if the scale is generated on the water discharge groove 28 formed in a spiral form by the long-term use of the water purifier, the pipe bobbin 25 can be decomposed, so that reuse is possible.

Claims (1)

A cap formed with a discharge inlet, a housing coupled with the cap, and a discharge outlet formed therein, the discharge passage is partitioned into a partition wall and provided with a spiral discharge groove on the outer circumferential surface and installed on the discharge groove. A discharge bobbin for a reverse osmosis water purifier, comprising: a pipe bobbin having a discharge hole formed therein; and a filter installed at a discharge water inlet side formed in the cap to filter foreign matter into the pipe bobbin side.