KR101511335B1 - Reverse osmosis filter having alkali support cartridge - Google Patents

Abstract

The reverse osmosis filter according to the present invention comprises: a filter case (10) having a water inlet (11) at one end and a water outlet (12) at the other end; An alkali supply cartridge 150 installed to be connected to the outlet 12 and containing an alkali member 155 therein; An internal partition wall 22 is provided to connect the inlet port 11 and the alkali supply cartridge 150 so that the inlet port 11 and the alkali supply cartridge 150 are separated from each other. A flow pipe 20 in which an inlet hole 21 is formed in a side wall of the side where the inlet 11 is provided and an outlet hole 22 is formed in a side wall of the side where the alkaline supply cartridge 150 is located, A reverse osmosis filter layer (30) installed to surround the flow pipe (20) including an outflow hole (22); And a control unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a reverse osmosis filter having an alkali supply cartridge,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reverse osmosis filter, and more particularly, to a reverse osmosis filter (RO filter) that allows water filtered by a reverse osmosis membrane (RO membrane) to have alkalinity by the action of an alkali member will be.

Water is a must for life. However, it is not desirable for the human body to drink water directly because organic wastes or minerals are harmful to the human body due to environmental pollution. In recent years, even the tap water coming into the home has been consumed through the purification process. In particular, as interest in health increases, there is a growing demand for water that contains substances that are beneficial to the human body, rather than simply harmless water.

As a result, a reverse osmosis filter (RO filter) has been developed to purify water. A reverse osmosis filter is a filter that purifies water through a RO membrane. Reverse osmosis refers to a phenomenon in which water moves toward the lower concentration due to the pressure applied from the higher concentration side, contrary to the osmosis phenomenon. The water without purified water is high concentration water. When it reaches the reverse osmosis membrane, all the impurities in the water are filtered by the water pressure, and only the water passes through the reverse osmosis membrane and is cleanly filtered.

The reverse osmosis membrane has a number of ultra-fine pores of about 0.0001 μm, which is about a millionth of the thickness of the hair. Because of this very small pore size, dissolved ions such as metal ions, chlorine ions, inorganic ions, low molecular organic matter, bacteria, Almost all but dissolved gas is filtered and only pure water molecules pass through, so that the removal rate of impurities is considerably high.

The water filtered by the reverse osmosis filter is advantageous in that it is safe to drink because almost all the impurities including the heavy metal ions are completely filtered out, thus it is advantageous to use minerals such as calcium, magnesium, potassium, There is a problem that they are all filtered out.

Water suitable for humans to drink is a weakly alkaline water with a balance of minerals. It is pointed out that the water filtered by the reverse osmosis filter does not have minerals and is slightly acidic with a PH of about 6.0 to 6.5. many.

Accordingly, it is an object of the present invention to provide a reverse osmosis filter that allows an alkaline member to act on water filtered by a reverse osmosis membrane to contain alkaline minerals useful for the human body such as calcium, magnesium, potassium, and the like.

According to another aspect of the present invention, there is provided a reverse osmosis filter comprising:

A filter case having a water inlet formed at one end thereof and a water outlet formed at the other end thereof;

An alkali supply cartridge installed to be connected to the outlet and having an alkali member therein;

And an inner partition wall which is provided to connect the inlet and the alkali supply cartridge so that the side having the inlet and the side having the alkali supply cartridge are separated from each other, A flow channel in which an inflow hole is formed in a side wall of the side wall and an outlet hole is formed in a side wall of the side having the alkali supply cartridge; And

A reverse osmosis filter layer including the water outlet and installed to surround the flow pipe; And a control unit.

  It is preferable that a blocking ring is provided between the reverse osmosis filter layer and the filter case so that the side having the inlet and the side having the outlet are separated from each other.

And a wastewater port is provided in the filter case so as to be positioned on the side where the outlet port is based on the blocking ring.

The diameter of the alkali supply cartridge is preferably smaller than the diameter of the filter case so that there is a gap between the alkali supply cartridge and the filter case.

It is preferable that the alkali supply cartridge has an arm groove formed at one end thereof so as to be inserted into the channel tube while being inserted therein and a spout formed at the other end thereof to be inserted and inserted into the outlet.

And an O-ring is provided between the groove and the flow path and between the spout and the outlet.

And the alkali supply cartridge is screwed to the flow pipe and the outlet port, respectively.

An alkali member may be contained in the flow pipe.

And the alkali component may be included in the reverse osmosis filter layer itself.

Preferably, the reverse osmosis filter layer is formed by winding a reverse osmosis membrane in a plurality of layers, and the alkali component contained in the reverse osmosis filter layer itself is installed in the form of particles in a reverse osmosis membrane located closest to the flow path pipe among the plurality of reverse osmosis membranes.

And an alkali member may be installed between the reverse osmosis filter layer and the flow path tube so as to surround the flow path tube.

Wherein the reverse osmosis filter layer is formed by winding a reverse osmosis membrane in a plurality of layers and an alkali member installed between the reverse osmosis filter layer and the flow path tube so as to surround the flow path tube, Or between the reverse osmosis membrane and the reverse osmosis membrane that is located closest to the reverse osmosis membrane and closest to the reverse osmosis membrane.

It is preferable that the alkali member comprises a plurality of alkali particles.

The alkali particles include an alkali metal or an alkaline earth metal.

The alkali particles may include a plurality of magnesium particles. In this case, the surface of the magnesium particles is preferably coated with silica, carbon, or silver.

 The alkali component may be at least one selected from the group consisting of silicon oxide, aluminum oxide, iron oxide, phosphorus pentoxide, zirconium oxide, oxidized tartan, silver oxide, zinc oxide, hafnium oxide, yttrium oxide, calcium carbonate, calcium hydroxide, calcium oxide, magnesium carbonate, magnesium hydroxide, , At least one of fossil fuels, feldspar, carbon, coconut, clay, kaolin, an antimicrobial material, a resin stream, an anion material, zircon, rare earth material, and silicate or a combination thereof.

The alkali particles may be in the form of powder, granule, or ball.

The alkali particles preferably have a size of 0.1 to 10 mm.

The alkali particles may be provided in a storage pouch having a plurality of through holes having a size smaller than that of the alkali particles.

 The alkali component may be formed into a plurality of alkali particles to form a lump or a lump by casting.

It is preferable that the molded lump form further comprises carbon or resin mixed with the alkali particles.

It is preferable that the lump formed by the casting contains magnesium or magnesium itself.

The alkali member may include an alkali particle and a carbon block, and the carbon block may be formed through the hollow in the longitudinal direction of the filter case, and the alkali particles may be installed in the hollow.

It is preferable that both ends of the hollow are clogged by the water-permeable film.

The alkali particles can be molded to form a lump.

The alkali particles may be contained in the storage pouch having a plurality of through holes having a size smaller than that of the alkali particles, or the alkali particles and the carbon block may be stored together.

According to the present invention, since the function of the reverse osmosis filter can be exhibited as it is, the increase of alkaline minerals, the increase of tds (total dissolved solids), the increase of pH, the increase of hydrogen to remove active oxygen, the reduction of orp And the cleaning function can be increased.

According to the present invention, acidification of water, which is a disadvantage of the reverse osmosis filter, and mineral components are prevented by the alkali supply cartridge, and alkaline water containing various minerals can be obtained. In some cases, various functional materials other than alkali particles may be added to obtain effects such as antibacterial action, far infrared ray emission effect, anion emission effect, and water taste improvement.

Alkaline water is not merely useful as a non-alcoholic beverage but has a sterilizing function. It has an effect of reducing the use of detergents and the like because it is excellent in washing and washing functions in fruit, vegetable, machine, dishwasher, laundry, shower and the like. As described above, the reverse osmosis filter according to the present invention can be applied to household, medical, industrial

It can be applied to various fields such as a dragon and other special purpose.

1 is an external perspective view illustrating a reverse osmosis filter (RO filter) according to the present invention;
FIG. 2 is an exploded perspective view of FIG. 1; FIG.
Figure 3 is an internal cross-sectional view of Figure 1;
4 is an enlarged view of a portion A in Fig. 3;
5 to 7 are views for explaining the case where the alkali particles 50 are used as an example of the alkali member 155;
8 to 11 are views for explaining the case of using the carbon block 60 together with the alkali particles 50 as another example of the alkali member 155;
Figs. 12 to 14 are views for explaining another mounting position of the alkali member 155. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are merely provided to understand the contents of the present invention, and those skilled in the art will be able to make many modifications within the technical scope of the present invention. Therefore, the scope of the present invention should not be construed as being limited to these embodiments.

FIG. 1 is an external perspective view illustrating a RO filter according to the present invention, and FIG. 2 is an exploded perspective view of FIG. 3 is an internal sectional view of FIG. 1, and FIG. 4 is an enlarged view of a portion A of FIG.

1 to 4, the filter case 10 has a hollow cylindrical shape with both ends closed, a water inlet 11 at one end and a water inlet 12 and a water outlet 12 at the other end, (13).

The filter case 10 may be detachably coupled to a predetermined site for disassembly and assembly, but may be integrally formed as a whole in order to prevent leakage of water. When the filter case 10 is made of a plastic material, it is easy to integrally form the filter case 10 by heat fusion or the like.

The alkali supply cartridge 150 is installed to be connected to the outlet port 12 and the alkali member 155 is installed in the inner space of the alkali supply cartridge 150.

The flow pipe 20 is installed in a tubular shape so as to connect the inlet 11 and the alkali supply cartridge 150. It is preferable that the flow pipe 20 is formed in a straight line shape so that the inlet port 11 and the outlet port 12 are opposed to each other.

In the case of the alkali supply cartridge 150, an arm groove 151 is formed at a portion connected to the flow pipe 20 so as to be inserted into the channel pipe 20 while being coupled therewith, 12, and the spigot 152 is formed so as to be coupled. This is because when the water flows from the flow pipe 20 side toward the alkali supply cartridge 150 and then escapes to the outlet port 12, it is necessary to adopt such a configuration that the alkaline supply cartridge 150 is installed in the flow pipe 20, It is advantageous to prevent the water from leaking from the portion connected to the water pipe 12.

The spout 152 is formed in the outlet 12 so that the spout 152 is inserted into the outlet 12 and the spout 152 is inserted into the spout 14. It is preferable that O-rings 151a and 152a are formed at a portion where the flow pipe 20 is inserted and a portion where the spout 152 is inserted. It is more preferable that the insertion of the flow pipe 20 and the spout 152 is screwed like a bolt beyond merely fitting in terms of tightness and rigidity.

An inner partition wall 22 is provided in the flow pipe 20 and the inside of the flow pipe 20 is partitioned by the inner partition wall 22 into a side having the inlet 11 and a side having the alkali supply cartridge 150 .

An inlet hole 21 is formed on the side of the flow pipe 20 on the side of the inlet 11 with respect to the internal partition wall 22 and a plurality of outlet holes 23 on the side of the alkali supply cartridge 150 . It is preferable that the inflow hole 21 is formed with a groove at the end of the flow pipe 20.

The reverse osmosis filter layer 30 is installed so as to surround the side wall of the flow pipe 20 with a predetermined thickness t including the portion where the water outlet hole 23 is present without including the inlet hole 21. At this time, both ends of the flow pipe 20 are protruded on both sides, one side is connected to the inlet 11 and the other side is connected to the alkali supply cartridge 150.

The reverse osmosis filter layer 20 is formed of a composite membrane in which a RO membrane having fine pores is formed and a mesh spacer, or the like, or a spiral wound type membrane. On the outside of the reverse osmosis filter layer (30), an impermeable protective layer (31) is provided so as to surround the reverse osmosis filter layer (30). The impermeable protective layer 31 serves to tightly bind the reverse osmosis filter layer 30 so as not to be loosened and to protect the reverse osmosis filter layer 30 and also to increase the purification path of the water.

A blocking ring 40 is installed between the reverse osmosis filter layer 30 and the filter case 10 so as to divide the reverse osmosis filter layer 30 into a side having the inlet 11 and a side having the outlet 12, . Water between the reverse osmosis filter layer 30 and the filter case 10 on the side of the inlet 21 and the outlet 22 can not pass through the blocking ring 40 as a reference. It is preferable to use a rubber ring because the blocking ring 40 is for sealing and it is preferable to fix the blocking ring 40 with the Teflon tape 41 so that the blocking ring 40 can not move.

The wastewater port 13 is not necessarily located at the end of the filter case 10 but may be provided on the side of the filter case 10 as long as it is located on the side of the outlet 12 with respect to the blocking ring 40.

The operation principle of the reverse osmosis filter according to the present invention will be described with reference to FIGS. 3 and 4. FIG.

The raw water flowing into the filter case 10 through the inlet 11 flows into the flow pipe 20 and at this time the flow pipe 20 is blocked by the internal partition 22, (30) through the end of the reverse osmosis filter layer (30) having a predetermined thickness (t) by being swirled in the inlet port (20) or immediately passing through the inlet hole (21) And flows along the longitudinal direction of the filter case 10. At this time, since the reverse osmosis filter layer 30 and the filter case 10 are blocked by the blocking ring 40, the raw water can not go beyond the blocking ring 40 to the side where the outlet port 12 is located.

The raw water flowing into the reverse osmosis filter layer 30 is purified by the reverse osmosis filter layer 30 and flows into the flow pipe 20 through the outlet hole 23 of the flow pipe 20. Since the reverse osmosis membrane 30 is formed by surrounding the flow pipe 20 by a plurality of layers, the reverse osmosis membrane 30 is purified in the process of passing the raw water through the reverse osmosis membrane and flowing into the flow pipe 20.

In this process, nearly all of the metal ions, chlorine ions, inorganic ions, low molecular organic substances, bacteria, bacteria and the like in the raw water are filtered, so that water flowing into the flow pipe 20 is composed of almost pure water molecules. The water suitable for humans to drink is a weakly alkaline water in which the minerals balance. Since the purified water flowing into the flow pipe 20 through the reverse osmosis filter layer 30 has no mineral and is slightly acidic with a PH of about 6.0 to 6.5, It is not desirable to drink it.

Therefore, in order to obtain alkaline water, it is necessary to artificially introduce a mineral component. This is the alkali member 155 in the alkali supply cartridge 150. The alkaline member 155 contains minerals that are in contact with water to generate hydrogen and convert water to alkaline. Minerals such as magnesium (Mg), calcium (Ca), sodium (Na), and potassium (K), which are highly ionized, are examples.

Magnesium reacts with water as shown in Reaction 1 below.

[Reaction Scheme 1]

M + 2H 2 O - > M ²⁺ + 2OH ^- + H 2, where M = alkali or alkaline earth metal

The hydroxide (OH ^- ) formed in this way makes the water alkaline, properly attached to the surface of magnesium and the like. At the same time, hydrogen (active hydrogen) formed at the same time gives water the ability to eliminate active oxygen, the source of all diseases. Water from ordinary tap water or water purifier has a redox potential of +200 mV to +500 mV, but the water with active hydrogen produced in this way has a negative redox potential.

Water introduced into the alkali supply cartridge 150 through the flow pipe 20 is discharged to the outside through the water outlet 13 while being supplied with the mineral component by the alkali member 155. Therefore, the water externally discharged through the water outlet 13 is reduced and becomes alkaline in the process of passing through the alkali member 155. At this time, the specific PH will vary depending on the ability of the alkali member 155, but it is preferable that the pH is 7.5 to 8.5 similar to the body fluids. Of course, when it is desired to use it as medical antioxidant water, it is preferable that PH is higher than this.

Sodium, magnesium, or potassium in addition to calcium, sodium, magnesium, or potassium in the alkali member 155 for antibacterial action, far-infrared radiation effect, anion release effect, Calcium carbonate, calcium hydroxide, calcium carbonate, magnesium carbonate, magnesium hydroxide, magnesium oxide, coral, fossil feldspar, feldspar, carbon, coconut, clay, zirconium oxide, zirconium oxide, zirconium oxide, zirconium oxide, zinc oxide, hafnium oxide, yttrium oxide, , Kaolin, antimicrobial materials, resins, anionic materials, zircon, rare earth materials, and sodium silicate.

The water that has not been introduced into the reverse flow pipe 20 from the reverse osmosis filter layer 30 is acidic in the state where the impurity components are concentrated and is discharged to the waste water outlet 13 through the end of the reverse osmosis filter layer 30. At this time, by making the diameter of the alkali supply cartridge 150 smaller than the diameter of the filter case 10, there is a gap between the alkali supply cartridge 150 and the filter case 10, So as not to prevent the discharge of the exhaust gas.

Since the reverse osmosis filter layer 50 is surrounded by the impermeable protective layer 31, water flows into the flow pipe 20 during the flow of water from one end to the other end of the reverse osmosis filter layer 50, . Thus, the purification path is maximized. If there is no impermeable protective layer 31, water may flow into or out of the intermediate region of the reverse osmosis filter layer 50, and the purification may not be performed properly.

Figs. 5 to 7 are views for explaining the case where the alkali particles 50 are used as an example of the alkali member 155. Fig. Specifically, a plurality of alkali particles 50 having a shape such as powder, granule, or ball are gathered to fill the inner space of the alkali supply cartridge 150 . If there is not enough space in the alkali member 155, the water can not flow out. Therefore, it is preferable that the alkali particles 50 have a diameter of 0.01 to 10 mm in order to secure a certain porosity.

The alkali supply cartridge 150 may have a diameter smaller than that of the filter case 10 as described above. The shape of the alkali supply cartridge 150 may be various, such as a cylindrical shape, a streamlined shape, a thick elliptical shape, and the like.

The alkali particles 50 include an alkali or an alkaline earth metal such as calcium, sodium, magnesium, or potassium. In order to impart functionality such as antimicrobial action, far infrared ray emission effect, anion release effect, Calcium carbonate, calcium hydroxide, calcium oxide, magnesium carbonate, magnesium hydroxide, magnesium oxide, coral, fossil feldspar, feldspar, carbonaceous material, At least one of coconut, clay, clay, kaolin, antimicrobial material, resin, anion material, zircon, rare earth material, and sodium silicate, or a combination thereof.

When the alkali particles 50 are made of magnesium, it is preferable that the surface of the magnesium particles is coated with silica, carbon, silver (Ag) or the like. Since magnesium reacts rapidly with water, it is necessary to delay such a sudden reaction to form a coating layer like this. In addition, magnesium is water and when the reaction when this MgOH ₂ to be MgOH ₂ is created, formed a film on the surface of the magnesium particles, the magnesium particles and water, the reaction was further as described above to the surface of the magnesium particles in order to avoid this because it is not in progress Thereby forming a coating layer. Carbon is for improving the water taste, and silver (Ag) is for imparting an antimicrobial function.

If the alkali particles 50 are simply gathered, the alkali particles 50 may be disturbed and the filter performance may be deteriorated. To prevent this, the plurality of alkali particles 50 are formed into the lumps 50 'as shown in FIG. Or the alkali particles 50 may be contained in the accommodating pouch 55 having a plurality of through holes 55a having a size smaller than that of the alkali particles 50 as shown in Fig.

When the alkali particles 50 are molded to form the lump 50 ', the shape thereof may vary according to the internal shape of the alkali supply cartridge 150. In the case of molding in the form of lumps 50 ', it is preferable to mix carbon or resin or the like with the alkali particles 50 so as to help the molding or to exert a unique effect (for example, improvement in water taste) such as carbon.

Of course, the alkali member 150 can be formed into a rod or a bullet-shaped bulk by casting or the like without depending on the molding of the alkali particles 50. In this case, it is preferable that the alkali member 150 is installed in a small size so that there is a slight gap rather than being filled in the alkali supply cartridge 150 so that the purified water can flow. Even in the case of a lump by casting or the like, the above-mentioned advantage can be obtained when the alkali member 150 contains magnesium.

The storage pouch 55 may be formed by piercing a through hole 55a with a plastic or by using a nonwoven fabric or mesh net.

Figs. 8 to 11 are views for explaining a case where the carbon block 60 is used together with the alkali particles 50 as another example of the alkali member 155. Fig. The carbon block 60 not only removes iron, rust, etc., but also improves the water taste. The alkali particles 50 are for artificially introducing mineral components to obtain alkaline water.

8, the hollow 69 may be formed in the carbon block 60 in the lengthwise direction of the filter case 10, and the alkali particles 50 may be provided in the hollow 69. As shown in FIG. At this time, both ends of the hollow 69 are preferably blocked with the water-permeable film 65 so that the alkali particles 50 can not escape.

The alkali particles 50 and the carbon block 60 are formed in the accommodating pouches (not shown) having a plurality of through holes 55a smaller in size than the alkali particles 50, as shown in Fig. 9, so that the alkali particles 50 do not escape from the hollow 69 55, or the alkali particles 50 can be accommodated in the accommodating pouch 55 alone as shown in Fig. Alternatively, as shown in FIG. 11, a plurality of alkali particles 50 may be formed to form a mass 50 '.

Figs. 12 to 14 are views for explaining another mounting position of the alkali member 155. Fig. The alkali member 155 may include a plurality of alkali particles 50 installed in the flow pipe 20 as shown in FIG. In this case as well, the alkali particles 50 may be formed into a lump 50 ', a lump that is shaped into a rod or a block by casting (FIG. 13), or an alkali It is possible to use the one containing the particles 50 (Fig. 14).

  In addition, the alkali member 155 may be installed in the reverse osmosis filter layer 30 itself. At this time, it is preferable that the alkali component 155 is inserted into the reverse osmosis membrane closest to the flow pipe 20 among the plurality of reverse osmosis membranes in the form of particles.

The alkali member 155 may be installed between the reverse osmosis filter layer 30 and the flow pipe 20 in a tube shape surrounding the flow pipe 20. At this time, the alkali component 155 is installed between the reverse osmosis membrane closest to the flow pipe 20 and the flow pipe 20 among the plurality of reverse osmosis membranes, or between the reverse osmosis membrane 20 located closest to the flow pipe 20 among the plurality of reverse osmosis membranes And a reverse osmosis membrane located next to the reverse osmosis membrane.

As described above, according to the present invention, acidification of water and a mineral component, which is a disadvantage of the reverse osmosis filter, are prevented by the alkali member 155, and alkaline water containing various minerals can be obtained. In some cases, a functional material may be added to the alkali member 155 to obtain an antimicrobial action, a far infrared ray emission effect, an anion emission effect, and a water taste improvement effect.

10: filter case 11: inlet
12: Outlet 13: Waste water
14: stone organs 20: flow tube
21: inflow hole 22: internal partition
23: Outgoing hole 30: Reverse osmosis filter layer
31: impermeable protective layer 40: blocking ring
41: Teflon tape 50: Alkali particles
50 ': bulk 55: storage pouch
55a: Through hole 60: Carbon block
65: water-permeable membrane 69: hollow
150: alkali supply cartridge 151:
151a, 152a: O-ring 152:
155: alkali component

Claims (26)

A filter case having a water inlet formed at one end thereof and a water outlet formed at the other end thereof;
An alkali supply cartridge installed to be connected to the outlet and having an alkali member therein;
And an inner partition wall which is provided to connect the inlet and the alkali supply cartridge so that the side having the inlet and the side having the alkali supply cartridge are separated from each other, A flow channel in which an inflow hole is formed in a side wall of the side wall and an outlet hole is formed in a side wall of the side having the alkali supply cartridge; And
A reverse osmosis filter layer including the water outlet and installed to surround the flow pipe; And,
Wherein the alkaline member is formed by coating silica, carbon, or silver on the surface of magnesium. The reverse osmosis filter according to claim 1, wherein a blocking ring is provided between the reverse osmosis filter layer and the filter case so that the inlet port and the outlet port are separated from each other. The reverse osmosis filter according to claim 2, wherein a wastewater port is provided in the filter case so that the filter ring is positioned on the side where the outlet port is located with respect to the blocking ring. The reverse osmosis filter according to claim 1, wherein the diameter of the alkali supply cartridge is smaller than the diameter of the filter case so that there is a gap between the alkali supply cartridge and the filter case. [2] The apparatus according to claim 1, wherein the alkali supply cartridge has an arm groove formed at one end thereof to be inserted into the channel tube while being inserted into the outlet, Reverse Osmosis Filter. 6. The reverse osmosis filter according to claim 5, wherein an O-ring is provided between the groove and the flow path, and between the spout and the outlet. 6. The reverse osmosis filter according to claim 5, wherein the alkali supply cartridge is screwed to the flow pipe and the outlet. The reverse osmosis filter according to claim 1, wherein an alkali member is contained in the flow pipe. The reverse osmosis filter according to claim 1, wherein the reverse osmosis filter layer itself comprises an alkali component. The reverse osmosis membrane filter according to claim 9, wherein the reverse osmosis filter layer is formed by winding a reverse osmosis membrane in a plurality of layers, and the alkali component contained in the reverse osmosis filter layer itself is formed in a reverse osmosis membrane Wherein the filter is installed on the filter. The reverse osmosis filter according to claim 1, wherein an alkali member is provided between the reverse osmosis filter layer and the flow path tube so as to surround the flow path tube. 12. The method of claim 11, wherein the reverse osmosis filter layer is formed by winding a reverse osmosis membrane in a plurality of layers, and an alkali member installed between the reverse osmosis filter layer and the flow path tube so as to surround the flow path tube, And a reverse osmosis membrane disposed between the reverse osmosis membrane and the reverse osmosis membrane closest to the reverse osmosis membrane. The reverse osmosis filter according to any one of claims 1, 8, 9, and 11, wherein the alkali member has a plurality of particles. delete delete 14. The method of claim 13, wherein the alkali component is selected from the group consisting of silicon oxide, aluminum oxide, iron oxide, phosphorus pentoxide, zirconium oxide, oxidized tartan, silver oxide, zinc oxide, hafnium oxide, yttrium oxide, calcium carbonate, calcium oxide, At least one of magnesium, magnesium oxide, coral, fossil feldspar, feldspar, carbon, cobalt, clay, kaolin, antimicrobial material, resin stream, anion material, zircon, rare earth material, Wherein the reverse osmosis filter is a reverse osmosis filter. The reverse osmosis filter according to claim 13, wherein the particles are in the form of a powder, granule, or ball. The reverse osmosis filter according to claim 13, wherein the particles have a size of 0.1 to 10 mm. 9. The reverse osmosis membrane according to any one of claims 1 to 8, wherein the alkali member is in the form of a plurality of particles, and the particles are provided in a receiving pouch having a plurality of through holes having a size smaller than that of the particles filter. 9. The reverse osmosis filter according to any one of claims 1 to 8, wherein the alkaline member is formed into a plurality of particles in the form of a lump or a lump by casting. The reverse osmosis filter according to claim 20, wherein the molded lump shape is formed by mixing carbon or resin with the particles. delete The filter according to any one of claims 1 to 8, characterized in that the alkali member is in the form of a plurality of particles and the alkali member is provided in the hollow of the carbon block in which the hollow is penetrated in the longitudinal direction of the filter case Reverse osmosis filter. 24. The reverse osmosis filter according to claim 23, wherein both ends of the hollow are plugged by the water permeable membrane. 24. The reverse osmosis filter according to claim 23, wherein the plurality of particles are molded to form a lump. 24. The reverse osmosis filter according to claim 23, wherein the particles are contained in the storage pouch having a plurality of through holes having a size smaller than the size of the particles, or the particles and the carbon block are stored together.

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