KR20140023012A - Connection structure membrane to increase durability nano membrane filter - Google Patents

Abstract

The present invention relates to a bonding structure between a nanomembrane and a filter of a water purifier, for improving durability of the filter and for improving sterilization function by surrounding the outer periphery of the filter. The nanomembrane covers the outer periphery of the membrane filter among filters of the water purifier; the nanomembrane comprises two layers; the filter is covered by a nanomembrane pocket forming an interference layer between the two layers. Hence, the purifying ability of the filter can be effectively improved, and the replacement period for the nanomembrane can be extended.

Description

Connection structure membrane to increase durability nano membrane filter

The present invention relates to a filter and a nanomembrane coupling structure for encapsulating the outer surface of a water purifier filter to improve sterilization performance and to improve the durability of the filter. In particular, the nano membrane is wrapped around the outer circumferential surface of the membrane filter of the water purifier filter, and the nano membrane pocket is formed using two layers of nano membranes and an interference layer therebetween to filter the filter more effectively. The present invention relates to a nanomembrane bonding structure for improving the capability and increasing the durability of the water purifier filter which has increased the filter cleaning and nanomembrane replacement cycles.

Generally, a water purifier has a structure that is discharged through a filter to remove harmful components such as various heavy metals and impurities contained in general tap water or separately provided bottled water. In this case, the sediment filter, the pre-carbon filter, the reverse osmosis membrane, and the post-carbon filter are used as the filter, and water purified by the filter is supplied as it is However, it may be stored in a water tank, cooled by a cooling device, or heated by a heating device to be supplied as cold water or hot water.

The filter of the conventional water purifier has a filter housing formed with an inlet through which water to be purified flows and an outlet through which purified water flows out and raw water introduced into the filter housing And a filter for purifying it.

In this case, the sedimentation filter is used to remove the dust and other particles present in the water, which is mechanically filtered. In the case of water supplied to each home in the source, already large particles are filtered, but fine particles remain . In other words, although we can not see fine particles in the eye, they can cause problems in water purifier components, so a special sedimentation filter that can filter out fine particles is used in the first stage of purification.

In the case of carbon filters such as carbon filters, it is effective in removing organic chemicals such as insecticides, herbicides, and industrial wastes, and radon, chlorine and odor. When a high quality carbon filter is used, , Chlorine and other unpleasant taste can be removed by 80 ~ 99%.

In particular, the carbon used in water purifiers is called activated carbon, which is made of wood, coconut or coal, which is specially heat treated to form millions of fine holes, and is present in the water during millions of holes The contaminants that were used are filtered.

However, when only a sediment filter is used in a general water purifier, there are no organic chemicals such as insecticides, herbicides, and industrial wastes, and the function of removing radon, chlorine and odor. In the case of a carbon filter, However, since carbon particles fall off during use, accumulation of such dusts causes various pollution and propagation of germs.

In addition, there is an inconvenience to clean the inside in the filter replacement work for the treatment of dust and to clean the water by flowing a predetermined time to the passage of the existing water.

In order to prevent the excessive generation of dust, although the diameter is advantageous for the purified water, it is difficult to use relatively large particles of about 20 to 50 mesh.

The present invention is to provide a filter and nano-membrane coupling structure to surround the outer surface of the water purifier filter to improve sterilization performance, and improve the durability of the filter. In particular, the nano membrane is wrapped on the outer circumferential surface of the membrane filter in the water purifier filter, and the nano membrane pocket is formed by forming the nano membrane into two layers and the interference layer therebetween, so as to effectively improve the purification ability of the filter. The present invention aims to provide a nanomembrane bonding structure that can increase the durability of the water purifier filter, which increases the filter cleaning and nanomembrane replacement cycles.

The nanomembrane bonding structure for increasing the durability of the water purifier filter according to the present invention includes a nanomembrane 31 on the outer circumferential surface of the filter 10 having the hollow part 11 and the flow path hole 12. ) Wrapped around the filter 10 with the nanomembrane pocket 40 having the interference layer 32 formed between the nanomembrane 31 and the nanomembrane 31, thereby improving durability and improving transmission efficiency. .

In addition, the nanomembrane pocket 40 according to the nanomembrane bonding structure for increasing the durability of the water purifier filter of the present invention forms a nanomembrane 31 above and below, and a nonwoven fabric layer (interference layer 32) therebetween ( Combining non-woven fabrics; The nanomembrane pocket 40 has a nonwoven fabric layer 32 formed between the nanomembrane 31 and the nanomembrane 31 and seals the edge portion of the sealing portion 33 and four sides. Only one side is implemented in the shape of a pocket formed with an opening 34 which is not sealed.

According to the present invention, there is an advantage in that the use of the membrane filter solves the inconvenience of having to frequently clean the air gaps.

In addition, according to the present invention, the interference layer is formed of a non-woven material such as a non-woven fabric between the nano-membrane and the nano-membrane, thereby forming a space where water flows in and out, thereby inducing purification more effectively and improving the qualitative efficiency of the purification.

In addition, according to the present invention, since the use of a known nano-membrane is manufactured and utilized separately in the form of a pocket, it is possible to increase the purification efficiency while improving the durability of the nano-membrane itself, and to be applied to a membrane filter that has been commonly used in the past. As a result, there is an advantage that the possibility of utilization is high.

1 is a view illustrating a method of wrapping a nano-membrane in a conventional membrane filter.
FIG. 2 is a view illustrating a purified working relationship between a conventional membrane filter and a nano membrane.
Figure 3 is a more detailed view of a conventional membrane filter.
Figure 4 is an exploded perspective view illustrating the manufacturing method of the nanomembrane pocket of the present invention.
5 is a view illustrating a method of manufacturing the heat-sealed nano-membrane pocket of the present invention.
6 is a diagram illustrating a method of wrapping the outer peripheral surface of the filter using the nano-membrane pocket of the present invention.
7 is a view showing a state in which the nano-membrane filter of the present invention to purify the water.

The present invention is an invention to wrap the nanomembrane in the outer periphery of the filter to improve the sterilization performance of the purification, and to improve the durability of the filter. Therefore, the construction and operation of the present invention will be described in detail with reference to FIGS. 4 to 7. FIG.

1 to 3 illustrate a filter 10 having a nano membrane 20 wrapped around an outer circumferential surface of a conventional membrane filter 10 to improve sterilization performance. Conventionally, the membrane filter 10 forms a first filter layer A (see FIG. 3) from a resin such as a nonwoven fabric in which pores are formed, and a second filter layer B manufactured using activated carbon as an outer portion thereof. The excitation filter 10 was implemented. Of course, the third filter layer (B) has a separate third filter layer (C). However, in order to improve the sterilization performance of the membrane filter 10, a water purifier for purifying the nano membrane 20 on the outer circumferential surface of the membrane filter 10 has been introduced. They have achieved the purpose of improving the sterilization performance and the ability to purify the fine particles, but the residue is quickly caught in the filter 10, the pores of the nano-membrane 20 is clogged, the production of purified water is reduced after some use. Is generated.

That is, the filter 10 has a hollow portion 11 on the inner side in the form of a pipe. And a plurality of channel holes 12 communicating with the hollow portion 11 are formed in the hollow portion 11. Water purified through the channel hole 12 flows into the hollow portion 11, . That is, the water purifier is a state in which a plurality of filters 10 are built in, and through the filter 10 installed at each stage, purifying water according to the purpose of the filter is achieved. As in the above-described conventional technique, the cleaning operation is performed through a number of steps such as dust and impurities are first applied and sterilized. At this time, the nano-membrane 20 performs the operation of filtering fine dust at the same time with the operation of sterilization. When the water is purified and sterilized while passing between the thin nano-membrane 20, the sterilized water flows into the flow path and becomes hollow. It enters the part 11, falls to one side, and flows into the next filter 10.

That is, after entering into a carbon filter or the like described in the related art.

At this time, the conventional filter 10 has the following problems. The nano membrane 20 (shown in FIG. 1) is wound around the outer circumferential surface of the filter 10 a plurality of times, and the purification operation is performed. The gap between the nano membrane 20 and the nano membrane 20 is narrow, so that water is difficult to flow. As shown in FIG. 1, in fact, the space S between the nanomembrane and the nanomembrane is so narrow that there is no movement of water (the enlarged view of FIG. 1 exaggerates the space for explanatory purposes). It is difficult to supply purified water because the operation of sterilization purification is delayed. It is difficult to supply purified water to the passage hole 12 by sterilizing and purifying water between the nano-film 20 and the nano-film 20 having virtually no space S due to a close interview. 1 and 2 exaggerately enlarge the space thereof. In order to artificially form the space between the nano-membrane 20 and the nano-membrane 20 in the process of repeatedly wrapping one long nanomembrane 20, it is difficult to wind the filter 10 and uniform disinfection is impossible. Do.

Therefore, the nano membranes 20 are bonded in such a manner as to be wound around the outer circumferential surface of the filter 10 to be in close contact with each other. Since there is no space between the nano membranes 20 and the nano membranes 20, the nano membranes ( Many voids formed in 20) are easily clogged. After some use, since there is no space between the nanofilm 20 and the nanofilm 20, this phenomenon is further deepened. As a result, the filter 10 used in the conventional nanomembrane 20 needs to be frequently cleaned, and there is also the inconvenience of having to replace the nanomembrane 20 entirely. 2 is a view showing how the amount of water to be purified by repetitively passing through the nano-membrane wound closely adhered to the water.

The present invention for solving this problem is a method to improve the durability, while utilizing the high effect of the conventional nano-membrane (20) sterilization. That is, all the conventional problems are solved by winding two sheets of the nanomembrane 31 (hereinafter described with reference to FIGS. 4 to 6) to the outer peripheral surface of the filter 10. That is, in the present invention, the nano film 31 is wrapped around the outer circumferential surface of the filter 10 having the hollow part 11 and the flow path hole 12, and an interference layer () between the nano film 31 and the nano film 31. The filter 10 is wrapped with the nanomembrane pocket 40 formed with 32 to improve durability and improve transmission efficiency.

If the nano film 31 and the nano film 31 are in close contact with each other, the plurality of voids formed in the nano film 31 may be quickly blocked. In order to solve this problem, the present invention forms a separate interference layer 32 between the nanofilm 31 and the nanofilm 31 as shown in FIG. 4. The interference layer 32 is a layer in which the nanofilm 31 and the nanofilm 31 do not adhere to each other and a certain amount of space can be formed. It is preferable that the material has a somewhat higher water absorption rate, and more preferably a certain degree of cushion or elasticity.

In the present invention, the structure in which the nanomembrane 31 is overlapped is referred to as a nanomembrane pocket 40. That is, the nano-membrane 31 is pre-processed to form the nano-membrane pocket 40, and wound around the filter 10 to improve sterilization performance, as well as to solve the durability and hassle of cleaning. The nanomembrane pocket 40 of the present invention will now be described in more detail.

The nanomembrane pocket 40 forms the nanomembrane 31 on top and bottom, and couple | bonds the nonwoven fabric layer which is the interference layer 32 between them. In other words, the nonwoven fabric is formed of the interference layer 32. This nonwoven fabric is a resin fiber layer having a plurality of voids therein. There is a lot of pores to allow easy passage of water, and water can be passed through the pores to purify dust or debris. Furthermore, since it has a certain degree of elasticity, the nano film 31 and the nano film 31 are effective as an interference layer that can be in close contact with each other at regular intervals.

In addition, when the nonwoven fabric is pressurized by applying a temperature, the nonwoven fabric is easily bonded to the nanomembrane 31 because the phenomenon occurs that the thickness of the nonwoven fabric is reduced, and in particular, the nanomembrane 31 and the nanomembrane are partially fused. It is induced to prevent (31) from being separated from each other unintentionally.

Looking at the manufacturing method of the nano-membrane pocket 40 in detail as follows. That is, the nanomembrane pocket 40 overlaps two nanomembrane 31 with each other, and sandwiches the nonwoven fabric of the same size between them. The nano membrane 31 and the nano membrane 31 are pressurized to a high temperature to be fused. The fused region is limited to four side regions. Fusion in this manner also serves to prevent the nano-film 31 and the nano-film 31 to be separated from each other, but to keep the parts other than the sides apart from each other in order to prevent inferior utilization of the sterilization ability. . A portion of the nanomembrane 31 that is fused and perfectly adhered to the nonwoven fabric is blocked in the pores therein. For this reason, sealing is performed by fusing only the edge portion of the nanomembrane 31. At this time, three side portions of four sides are fused, and one side portion is left as the opening portion 34 without fusing. The reason is as follows.

When the interference layer 32 made of a nonwoven fabric is bonded between the two nanofilms 31, they have a constant thickness. When the nano-membrane pocket 40 having this thickness is wound around the outer circumferential surface of the filter 10, the diameters of the nano-membrane of the inner layer and the nano-membrane of the outer layer are different from each other. Because it has a certain thickness. When the nano-membrane pocket 40 is wound in this state, one side may be stretched or crying. If the pocket is formed in such a manner that all four sides are fused, it cannot be wound around the filter 10 uniformly. One side should be left open to the opening 34 to compensate for this difference in length. As a result, the present invention preferably winds up the filter 10 by forming pockets as shown in FIGS. 5 and 6.

That is, in the nanomembrane pocket 40 of the present invention, the nonwoven fabric layer 32 is formed between the nanomembrane 31 and the nanomembrane 31, and the sealing portion 33 which seals the edge portion and one side of the four sides. Most preferably, only the shape of the pocket in which the opening 34 is not formed is formed.

As described above, according to the present invention, when the membrane filter is used, it is possible to solve the problem that the pores are clogged and frequent cleaning is required.

In addition, according to the present invention, by forming an interference layer made of a material such as a nonwoven fabric between the nano-membrane and the nano-membrane, it is possible to improve the qualitative efficiency of the purification while inducing purification more effectively by forming a space in which water enters.

In addition, according to the present invention, since the use of a known nano-membrane is manufactured and utilized separately in the form of a pocket, it is possible to increase the purification efficiency while improving the durability of the nano-membrane itself, and to be applied to a membrane filter that has been commonly used in the past. As it can, utilization is high.

10; Filter 11; Hollow portion
12; Euro ball 31; Nanomembrane
32; An interference layer 33; The sealing portion
34; An opening 40; Nanomembrane pocket
S; space

Claims (3)

The nano membrane 31 is wrapped around the outer circumferential surface of the filter 10 having the hollow portion 11 and the flow path hole 12.
The nano membrane pocket 40 formed with the interference layer 32 between the nano membrane 31 and the nano membrane 31 wrapped the filter 10 to improve durability and improve transmission efficiency. A nanomembrane bonding structure for increasing durability of a water filter.
The method of claim 1,
The nano-membrane pocket 40 is formed by forming a nano-membrane 31 on the upper and lower sides, and a non-woven fabric, which is an interference layer 32, is bonded therebetween. Nanomembrane bonding structure for increased durability.
3. The method of claim 2,
The nanomembrane pocket 40 has a nonwoven fabric layer 32 formed between the nanomembrane 31 and the nanomembrane 31, and a sealing portion 33 sealing a corner portion thereof and one of four sides. Nano-bonded structure for increasing the durability of the water purifier filter, characterized in that implemented only in the shape of a pocket formed with an opening 34 is not sealed.

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