KR20120136111A - Method for manufacturing filter and filter thereof - Google Patents

Abstract

PURPOSE: A filter manufacturing method and a filter manufactured by the method are provided to facilitate manufacturing processes and to improve the performance of water purification by using a dual filter membrane structure. CONSTITUTION: A filter manufacturing method includes the following steps: a single filter membrane(10) is folded to form a dual filter membrane(20); one side(22) and another side(24) of the dual filter membrane are fused to form a closed side; and corrugated parts are further formed on the single filter membrane or the dual filter membrane before or after the formation of the dual filter membrane. The dual filter membrane is made of nanofiber with electric charges.

Description

Filter manufacturing method and filter manufactured using the same {METHOD FOR MANUFACTURING FILTER AND FILTER THEREOF}

The present invention relates to a filter manufacturing method and a filter manufactured using the same, and more particularly, a filter manufacturing method for easily manufacturing a double filter membrane providing improved water purification performance compared to a single filter membrane and a filter manufactured using the same. It is about.

Filters used in water purifiers or water treatment pass water or other liquids containing impurities through the filter, leaving impurities and extracting pure water or other liquids.

If this action is repeatedly performed, impurities continue to adhere to and accumulate on the surface of the filter, or the filter is finely damaged, thereby degrading the filter's ability over time. Therefore, it is necessary to replace the filter periodically so that the quality of purified water or water treatment can be kept uniform.

To this end, a filter cartridge equipped with a filter is used in the filter holder, and when the filter life is over, a standardized filter cartridge is developed so that the existing filter cartridge can be removed from the filter holder and simply replaced with a new filter cartridge. Has been.

As shown in FIG. 1, the filter cartridge according to the related art is provided with a filter membrane filter 110 having a bent shape several times between the disc holders 120, and a core 130 mounted therein. Known.

In the filter cartridge 100 according to the related art, the surface area of the filtration membrane filter 110 is increased by using the filtration membrane filter 110 having a shape bent several times in order to improve the processing capacity per hour.

Specifically, referring to Figure 1, the filter membrane filter 110 of the filter cartridge 100 according to the prior art is a form of a single flat filter membrane zigzag bent several times, one end and the other side of the single filter membrane The end is fused to form a fusion part 112.

The raw water entering the filter cartridge 100 through the water supply 122 by the filter cartridge 100 flows through the core 130 and is filtered through the filter and then discharged to the outside.

By the way, according to the prior art as described above, the filter has a single filter membrane structure, there is a problem that the water purification performance may be insufficient.

Therefore, in order to improve the water purification performance of the filter, the filter is formed in a double filter membrane structure, it is necessary to develop a filter manufacturing technology that can produce a double filter membrane in a uniform form by an easy method.

The present invention has been proposed in order to solve the conventional problems as described above, the object of the present invention is to provide a double filter membrane that provides improved water purification performance compared to a single filter membrane, one side and the other side folded after folding the single filter membrane It is to provide a filter manufacturing method that can be easily produced by the method of fusion and a filter produced using the same.

As a technical aspect for achieving the above object, the present invention, the step of folding the single filter membrane to form a double filter membrane and the cross-section of the double filter membrane to form a closed end, one side and the one side of the folded portion of the double filter membrane Provided is a filter manufacturing method comprising the other side of the fusion welding step.

Preferably, the method further includes forming a pleat on the double filter membrane after the double filter membrane forming step.

More preferably, before the forming of the double filter film, the method further includes forming a pleat on the single filter film.

More preferably, in the double filter membrane fusion step, when the flow path of the filter is formed in the inner direction of the double filter membrane, one side of the double filter membrane is fused to the inner side surface of the other side.

More preferably, in the double filter membrane fusion step, when the flow path of the filter is formed in the outward direction of the double filter membrane, one side of the double filter membrane is fused to the outer side of the other side.

More preferably, in the double filter membrane fusion step, the other side is sandwiched between the pleats of one side of the double filter membrane to be fused.

More preferably, the double filter membrane is formed of charged nanofibers.

The present invention provides a double filter membrane provided in a pleated form by folding a single filter membrane and forming a closed end of the double filter membrane in a closed end shape, and fusion bonding one side of the double filter membrane and the other side opposite to the one side. It provides a filter configured to include a fusion.

Preferably, the fusion portion is formed by fusion of one side of the double filter membrane to the inner side or the outer side of the other side.

More preferably, the fusion portion is formed by fusion of the other side between the pleats of one side of the double filter membrane.

More preferably, the double filter membrane is formed of charged nanofibers.

According to the filter manufacturing method and the filter manufactured using the same according to the present invention, the filter water purification performance is improved by providing a filter having a double filter membrane structure using a single filter membrane.

In addition, there is an effect that the double filter membrane can be easily manufactured by a method of fusion welding one side and the other side after folding a single filter membrane.

1 is a perspective view and a cross-sectional view showing a filter of a single filter membrane according to the prior art.
Figure 2 is a block diagram showing a filter manufacturing method according to the present invention.
3 and 4 is a block diagram showing an application example of the filter manufacturing method according to the present invention.
5 to 7 are plan views showing various double filter membrane shapes of the filter according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a filter manufacturing method and a filter manufactured using the same according to the present invention.

2 shows step by step a method (S100) of manufacturing the double filter membrane 20 according to the present invention, and FIGS. 3 and 4 show wrinkles in the method (S100a) (S100b) of the double filter membrane 20 of FIG. 2. The application example of adding the forming step (S130a) (S130b) is shown.

5 to 7 illustrate a filter 1 having a double filter membrane 20 structure in which various fusion portions 30 are formed according to the method of manufacturing the double filter membrane 20.

First, referring to FIG. 2, in the filter manufacturing method S100 according to the present invention, a step of forming a double filter membrane 20 by folding a single filter membrane 10 (S110) and the double filter membrane 20 may be described. In order to form a cross-section in a closed end, it may be configured to include a step (S120) of fusing one side 22, which is a folded portion of the double filter membrane 20, and the other side 24 opposite the one side 22.

As described in the background art, the filter of a single filter membrane has a problem that the water purification performance may be insufficient, so that the filter is provided in a double filter membrane structure, and the filter membrane is wrinkled in order to increase the surface area of the filter membrane to improve the water treatment capacity. It is more preferable to form.

In the present invention, in order to provide a double filter membrane structure, a double filter membrane 20 is formed by folding a single filter membrane 10 without forming a double filter membrane by overlapping two single filter membranes.

To this end, referring to the application example of FIG. 3, the filter manufacturing method (S100a) may further include forming a pleat on the double filter membrane 20 (S130a) after the double filter membrane forming step (S110a). have.

Specifically, in FIG. 3, after the single filter membrane 10 is folded to form the double filter membrane 20 (S110a), wrinkles are formed in the double filter membrane 20 (S130a). Then, both sides of the double filter membrane 20 are fused to form a cylindrical filter 1 (S120a).

At this time, since the single filter membrane 10 is folded to form the double filter membrane 20 and then pleats are formed, as shown in the cross-sectional view of the filter of FIG. 3, the outer filter membrane 20a and the inner filter membrane 20b are formed. Wrinkles are formed to overlap approximately in the same form.

In this case, since the outer filter film 20a and the inner filter film 20b are substantially overlapped, less space is formed between the outer filter film 20a and the inner filter film 20b than in the case of FIG.

When the double filter membrane is formed, when the outer filter membrane and the inner filter membrane are in contact with each other so that there is almost no space therebetween, the double filter effect may be difficult to obtain because the double filter membrane is similar to the single filter membrane.

However, in the manufacturing process, when the double filter membrane 20 is fused on both sides to form the cylindrical filter 1, the outer filter membrane 20a and the inner filter membrane 20b are naturally separated to some extent.

Therefore, a space is formed between the outer filter membrane 20a and the inner filter membrane 20b, so that the double filter function can be sufficiently exhibited.

In addition, referring to the application example of FIG. 4, the filter manufacturing method S100b may further include forming a pleat on the single filter membrane 10 before the dual filter membrane forming step S110b (S130b). .

Specifically, in FIG. 4, before the single filter membrane 10 is folded, a pleat is first formed in the single filter membrane 10 (S130b). Then, the pleated single filter membrane 10 is folded to form a double filter membrane 20 structure (S110b), and both sides are fused to form a cylindrical filter 1 (S120b).

At this time, by forming the pleats before folding the single filter membrane 10, as shown in the cross-sectional view of the filter of FIG. 3, the pleats of the outer filter membrane 20a and the inner filter membrane 20b are formed to be symmetrical with each other. do.

As a result, between the outer filter membrane 20a and the inner filter membrane 20b, the peaks protruding in the outward direction of the outer filter membrane 20a and the mount portions protruding in the inner direction of the inner filter membrane 20b. The space is formed continuously in the shape of a rhombus.

Here, the outer filter membrane 20a and the inner filter membrane 20b of the double filter membrane 20 according to the present invention have a space in the shape of the above-mentioned rhombus spaced therebetween and are separated to some extent so that the double filter function can be sufficiently exhibited. Can be.

However, even in the case of manufacturing the filter 1 as shown in FIG. It is also possible.

In addition, one side 22, which is a folded portion of the double filter membrane 20, and the other side 24 opposite to the one side 22 may be fused to form a cross section of the double filter membrane 20 in a closed end shape. Here, the cross section of the double filter membrane 20 is formed in a closed end shape, it is preferable to form in a circular shape as in the present invention so that the filtration is uniform in the filter membrane.

2 to 4, the outer filter membrane 20a and the inner filter membrane 20b are connected at one side 22, which is a folded portion of the double filter membrane 20, and are opposite to the one side 22. On the other side 24, the end part of the outer filter membrane 20a and the end part of the inner filter membrane 20b do not connect.

In this way, one side 22 and the other side 24 of the double filter membrane 20 are overlapped and fused to form a fusion unit 30, thereby forming a substantially cylindrical filter 1. Here, the raw water is filtered while passing in the inner or outer direction of the cylindrical filter 1.

On the other hand, in the process of manufacturing the cylindrical filter 1 by fusing both sides of the double filter membrane 20, fine dust or foreign matter is generated at the fusion unit 30 or the end of the filter membrane. In particular, at the end, a lot of fine dust is generated during the cutting of the filter membrane.

Therefore, it is preferable to form a fusion unit 30 configured such that such fine dust or foreign matter is not leaked out and supplied to the user.

To this end, in the present invention, as shown in Figures 5 to 7 can provide a double filter membrane 20 is formed in the fusion unit 30 of various forms according to the flow path of the raw water. 5 and 6 may be manufactured by the filter manufacturing method illustrated in FIGS. 3 and 4, respectively.

First, in the double filter membrane fusion step (S120), when the flow path of the filter 1 is formed in the inward direction of the double filter membrane 20, one side 22 of the double filter membrane 20 is formed on the other side ( It is preferable to fuse to the inner side of 24, and the filter having such a weld is shown in Figs. 5A and 6A.

That is, the other side 24 is overlapped and fused on the outer filter membrane 20a of one side 22 which is a folded portion of the double filter membrane 20.

In this case, although not shown, raw water is introduced from the lower inlet of the filter housing, and the introduced raw water is filtered while being introduced into the interior through the double filter membrane 20, and then the upper portion of the filter housing from the inside of the double filter membrane 20. Out through the outlet.

At this time, fine dust or foreign substances generated at the end of the fusion unit 30 and the filter membrane should be prevented from flowing into the double filter membrane 20 together with the raw water.

However, in the present invention, since one side 22 of the double filter membrane 20 is folded, almost no fine dust or foreign matter is generated, while the other side 24 is an end formed by cutting, so that a lot of fine dust or foreign matter may occur. have.

Therefore, when the flow path is formed from the outside of the double filter membrane 20 to the inside, the fine dust or foreign matter generated on the other side 24 of the double filter membrane 20 does not flow into the double filter membrane 20. The other side 24 of the double filter membrane 20 is preferably disposed outside the one side 22.

That is, as shown in FIGS. 5A and 6A, when the flow path is formed from the outside to the inside of the double filter membrane 20, the other side 24 of the double filter membrane 20 is formed. It is preferable to be fused to the outer side of this one side 22.

In addition, when the flow path of the filter 1 is formed in the outward direction of the double filter membrane 20 in the double filter membrane fusion step (S120), one side 22 of the double filter membrane 20 is formed on the other side ( It is preferable to fuse the outer surface of 24), and the filter having such a weld is shown in Figs. 5B and 6B.

That is, one side 22 which is a folded portion on the outer filter membrane 20a of the other side 24, which is the cut end of the double filter membrane 20, is folded and fused.

In this case, although not shown, raw water is introduced into the double filter membrane 20 through the lower inlet of the filter housing, and the introduced raw water passes through the double filter membrane 20 and is filtered out, and then filtered. Out through the upper outlet.

At this time, as described above, since the other side 24 of the double filter membrane 20 is an end portion formed by cutting, fine dust or foreign substances may be generated.

Therefore, when the flow path is formed from the inside of the double filter membrane 20 to the outside, the fine dust or foreign matter generated at the other side 24 of the double filter membrane 20 does not flow out of the double filter membrane 20. The other side 24 of the double filter membrane 20 is preferably disposed inside one side 22.

That is, as shown in FIGS. 5B and 6B, when the flow path is formed from the inside of the double filter membrane 20 to the outside, the other side 24 of the double filter membrane 20 is formed. It is preferable to be fused to the inner side of the one side 22.

Next, as shown in FIG. 7, in the double filter membrane fusion step (S120), the other side 24 is interposed between the pleats of the one side 22 of the double filter membrane 20 to weld the fusion unit 30. Can be formed.

As described above, in the present invention, a large amount of fine dust or foreign matter is generated on the other side 24 of the double filter membrane 20. Thus, the embodiments of the double filter membrane 20 of FIGS. 5 and 6, one side 22 and the other side 24 of the double filter membrane 20 according to the direction of the flow path so that the fine dust or foreign matter does not flow out. ) Is placed.

That is, the flow path may be formed in various ways according to the configuration of the filter. In the embodiments of the dual filter membrane 20 of FIGS. 5 and 6, the flow path may not correspond to all the flow paths. It is preferred only if it is formed in the inward or outward direction.

On the other hand, in the embodiment of the double filter membrane 20 illustrated in FIG. 7, the fusion unit 30 is fused by arranging the other side 24 between the first pleats of one side 22 of the double filter membrane 20. It is formed.

Accordingly, the other end 24 is not exposed to the inside or the outside of the double filter membrane 20, and fine dust or foreign matter generated from the other end 24 is trapped between the pleats of the one side 22. Dust or foreign matter can be prevented from flowing out of the filter 1 and supplied to the user.

Next, the filter 1 formed of the double filter membrane 20 according to the present invention may be formed of charged nanofibers.

Specifically, the nanofiber filter is made of nano fiber as an addressing material, and has a charge on the surface, and is capable of filtering minerals, organic materials, metals, bacteria, DNA, or viruses. Even nano-sized particles can be processed.

In particular, the nanofiber filter not only has a small pore of the film itself but also has a charge, and thus has excellent performance in removing bacteria and viruses.

Furthermore, in addition to the superior water purification capability described above, the nanofiber filter has the advantage that the processing flow rate is larger than that of the reverse osmosis membrane filter, so that a large amount can be processed in a short time and there is no water that is thrown into the concentrated water.

Further, in the present invention, the filter 1 is preferably a nano alumina fiber filter having high electrical conductivity among the nanofiber filters having such a charge, but is not limited thereto.

While the invention has been shown and described in connection with specific embodiments so far, it will be appreciated that the invention can be variously modified and varied without departing from the spirit or scope of the invention as set forth in the claims below. It will be appreciated that those skilled in the art can easily know.

1 ... filter 10 ... single filter membrane
20 ... double filter membrane 20a ... outer filter membrane
20b ... inner filter membrane 22 ... double filter membrane
24 ... other side of double filter membrane 30 ... welded part

Claims (11)

Folding the single filter membrane 10 to form a double filter membrane 20 (S110); And
Fusing one side 22, which is a folded portion of the double filter membrane, and the other side 24 opposite to the one side to form a cross-section of the double filter membrane 20 in a closed end (S120);
Filter production method comprising a.
The method of claim 1,
After the double filter film forming step (S120), the filter manufacturing method characterized in that it further comprises the step of forming a pleat (S130a) in the double filter film (20).
The method of claim 1,
Before the double filter film forming step (S120), the filter manufacturing method, characterized in that it further comprises the step of forming a pleat (S130b) in the single filter film (10).
4. The method according to any one of claims 1 to 3,
In the double filter membrane fusion step (S120), the filter manufacturing method, characterized in that one side (22) of the double filter membrane is fused to the inner surface of the other side (24).
4. The method according to any one of claims 1 to 3,
In the double filter membrane fusion step (S120), the filter manufacturing method, characterized in that one side (22) of the double filter membrane is fused to the outer surface of the other side (24).
The method according to claim 2 or 3,
In the double filter membrane fusion step (S120), the filter manufacturing method, characterized in that the other side (24) is sandwiched between the pleats of one side (22) of the double filter membrane (20).
4. The method according to any one of claims 1 to 3,
The double filter membrane (20) is a filter manufacturing method, characterized in that the nanofibers are charged as the address material.
A double filter membrane 20 in which a single filter membrane 10 is folded and provided in a pleated form; And
Fusion part 30 provided by fusing one side 22, which is a folded portion of the double filter membrane 20, and the other side 24 opposite to the one side, to form the double filter membrane 20 in a closed end shape. ;
Configured filters, including.
9. The method of claim 8,
The fusion unit (30) is a filter, characterized in that one side (22) of the double filter membrane (20) is formed by fusion to the inner side or the outer side of the other side (24).
9. The method of claim 8,
The fusion unit 30 is a filter, characterized in that the other side (24) is sandwiched between the pleats of one side (22) of the double filter membrane (20) is formed by fusion.
11. The method according to any one of claims 8 to 10,
The double filter membrane (20) is characterized in that the nanofibers having a charge as an address material.

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