KR200366200Y1 - Filter cartridge and filter - Google Patents

Abstract

Disclosed are a filter and a filter cartridge having a high dust removal efficiency in filtration. The filter cartridge is a hollow filter housing including a raw water part which is an inlet for entering water into one end and a water purification part which is an outlet from which water flows outward from the inside, and is formed in a cylindrical shape and formed in a cylindrical shape. A filter core including a first nonwoven filter layer having a width, a membrane layer formed inside the first nonwoven filter layer, and a second nonwoven filter layer formed inside the membrane layer, mounted at one end of the filter core, and sealed at the water purification portion And a second cover mounted on the other end of the filter core and connected to the purified state to transfer purified water inside the filter core to the purified portion. In addition, the filter may be manufactured separately, including the first nonwoven filter layer, the membrane layer, and the second nonwoven filter layer. Therefore, the membrane layer is inserted between the first nonwoven filter layer and the second nonwoven filter layer to increase the efficiency of fine dust removal.

Description

Filter Cartridges and Filters {FILTER CARTRIDGE AND FILTER}

The present invention relates to a filter cartridge and a filter. More particularly, the present invention relates to a filter including a filter and a filter for filtering foreign substances present in a liquid or gas or bacteria that are harmful to a human body.

Recently, living environment has been advanced, and scientific civilization is rapidly progressing, causing many problems. Among them, environmental pollution not only degrades the quality of our lives, but also greatly affects the human body.

In particular, water pollution has emerged as a socially important problem. Therefore, purification of contaminated water and purification of general water for drinking water use have been extensively studied. To solve this problem, various types of filters have been developed.

However, the conventional filter contains various metals and chemicals even after the raw water is purified through the filter, if the fine water contains fine dust. Therefore, recently, a filter having high efficiency of removing fine dust during filtration is required.

Moreover, since various bacteria, molds, etc. may propagate in a filter, the sterilization process of the filter used for various products becomes a problem. If such a phenomenon occurs in the filter used in the water purifier, the user may drink water in which bacteria or molds are propagated, which may cause fatal harm to the human body, and if various bacteria or molds are propagated inside the filter installed in the bidet. Sensitive parts of the body are exposed to germs and are not good for health.

In addition, in order to produce a filter having a high performance that can be purified from raw water to obtain pure water, it is required to go through various complicated processes, which increases manufacturing price and takes a long time. Therefore, the unit cost of the filter cartridge and the filter is increased, and the productivity of the filter cartridge and the filter is greatly reduced.

Accordingly, one object of the present invention for solving the above-described problems of the present invention is to provide a filter and a filter cartridge having a high efficiency of removing dust during filtration.

In addition, another object of the present invention is to provide a filter and a filter cartridge having an effect of sterilizing bacteria and fungi that are harmful to the human body.

In addition, another object of the present invention is to provide a filter and a filter cartridge in which the productivity of the product is increased.

1 is a perspective view of a filter according to a first embodiment of the present invention.

2 is a partial perspective view for explaining the inside of the filter according to the first embodiment.

3 is a perspective view of a filter cartridge according to a second embodiment of the present invention.

4 is a partially exploded view for explaining the principle of operation of the filter cartridge according to the second embodiment.

5 is an exploded perspective view for explaining a filter in the filter cartridge according to the second embodiment.

<Explanation of symbols for the main parts of the drawings>

110,232: first nonwoven filter layer 120,234: membrane layer

130,236: second nonwoven filter layer 140,260: silver ion portion

210: filter housing 220: housing cover

230: Filter core 240: First cover

250: The second cover

According to a preferred embodiment of the present invention for achieving the objects of the present invention described above, the filter cartridge includes a filter housing, a filter core, a first cover and a second cover. The filter housing is formed in a hollow shape to receive the filter core therein, and includes a raw water portion and a water purification portion. The raw water part is an inlet provided at one end and water enters from the outside to the inside, and the purified water part is provided at the other end and an outlet from which the purified water goes from the inside to the outside. The filter core is located inside the filter housing and includes a first nonwoven filter layer, a membrane layer and a second nonwoven filter layer. The first nonwoven filter layer is formed in a cylindrical shape and forms a layer having a constant width inside the surface to maximize the efficiency of removing fine dust. A membrane layer is formed below the first nonwoven filter layer, and a second nonwoven filter layer is formed below the membrane layer. Therefore, the raw water provided from the outside is purified while passing in the order of the first nonwoven filter layer, the membrane layer and the second nonwoven filter layer.

The first cover is mounted at one end of the filter core and is connected in a sealed state to the purified water part to transfer purified water inside the filter core to the purified water part. Thus, purified water purified by the filter core is transferred from the second nonwoven filter layer to the purified water portion. The second cover is attached to the other end of the filter core to block the other end of the filter core so that the purified water flows in one direction.

Conventional filter cartridges may be included in the case of fine fine dust without passing through the filter to the purified water of various metals and chemicals. However, the filter cartridge of the present invention is a filter having a multilayer structure of the first nonwoven filter layer, the membrane layer and the second nonwoven filter layer. Therefore, various metals, chemicals and the like can be filtered through several water purification steps, thereby increasing the efficiency of removing fine dust. In particular, in the membrane layer interposed between the first nonwoven filter layer and the second nonwoven filter layer, only pure water may be moved into the filter core by the principle of membrane separation, thereby maximizing the fine dust removal efficiency. Here, the principle of membrane separation means that a high concentration of liquid moves to a low concentration region to obtain a pure liquid using an osmotic phenomenon.

In addition, the first nonwoven filter layer and the second nonwoven filter layer may be composed of one nonwoven fabric, and the nonwoven fabric may be wound to form the first nonwoven filter layer and the second nonwoven filter layer. The membrane layer is composed of a membrane fabric inserted between the wound nonwoven fabric and may be divided into a first nonwoven filter layer and a second nonwoven filter layer by the membrane fabric.

In order to produce a filter having high performance in a conventional filter cartridge, it is required to go through various complicated processes, which is not easy to manufacture, and thus productivity is low. However, the filter cartridge of the present invention can produce a filter by inserting a membrane layer in the middle of winding one nonwoven fabric and then winding the nonwoven fabric again. Therefore, since no plastic injection molding is required, various complicated processes can be omitted, and the product can be produced only by an optimal process step, thereby improving the productivity of the filter cartridge.

According to a preferred embodiment of the present invention for achieving the above objects of the present invention, the filter includes a first nonwoven filter layer, a membrane layer and a second nonwoven filter layer.

The first nonwoven filter layer is formed in a cylindrical shape and forms a layer having a constant width inside the surface to maximize the efficiency of removing fine dust. A membrane layer is formed below the first nonwoven filter layer, and a second nonwoven filter layer is formed below the membrane layer. Therefore, the raw water provided from the outside is purified while passing in the order of the first nonwoven filter layer, the membrane layer and the second nonwoven filter layer.

In addition, the first nonwoven filter layer and the second nonwoven filter layer may be composed of one nonwoven fabric, and the nonwoven fabric may be wound to form the first nonwoven filter layer and the second nonwoven filter layer. The membrane layer is composed of a membrane fabric inserted between the wound nonwoven fabric and can be divided into a first nonwoven filter layer and a second nonwoven filter layer by the membrane fabric. The second nonwoven filter layer may further include a silver ion unit providing a plurality of silver ions to assist sterilization.

In the conventional filter, various bacteria, molds and the like may grow inside. Thus, not only water purifiers but also products used in connection with human activities such as bidets can cause serious problems. However, the filter of the present invention is provided with silver ions therein, so that various bacteria, fungi, and E. coli can be killed and cleaned, so that there is no harm to the human body. Therefore, it can be directly used in water purifiers, bidets, various electronic products or industrial sites.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the present invention is not limited or limited by the embodiments.

Example 1

1 is a perspective view of a filter according to a first embodiment of the present invention, Figure 2 is a partial perspective view for explaining the interior of the filter according to the first embodiment.

1 and 2, the filter includes a first nonwoven filter layer 110, a membrane layer 120, a second nonwoven filter layer 130, and a silver ion unit 140.

The first nonwoven filter layer 110 is formed to have a predetermined thickness from the surface of the filter toward the inside, wherein the first nonwoven filter layer 110 is manufactured to a thickness capable of effectively removing the desired fine dust size. The material of the first nonwoven filter layer 110 is composed of a nonwoven fabric. The first nonwoven filter layer 110 is formed by winding in a cylindrical shape from the inside to the surface. Therefore, the first nonwoven filter layer 110 overlaps a plurality of layers of the nonwoven fabric as the inner portion of the first nonwoven filter layer 110 is reduced, so that the size of the fine dust that can pass from the surface toward the inner portion is reduced. Therefore, raw water moving from the outside to the inside of the filter first filters the impurities toward the inside of the first nonwoven filter layer 110 (ⓐ).

The membrane layer 120 has a predetermined thickness inside the first nonwoven filter layer 110, and is composed of a membrane fabric having pores of about 0.3 μm to 0.5 μm. The membrane layer 120 is formed while the membrane fabric is wound between the nonwoven fabrics, and the first nonwoven filter layer 110 and the second nonwoven filter layer 130 are divided by the membrane layer 120. However, in other embodiments of the present invention, membranes having pores of various sizes may be used according to the intention of the designer. Membrane layer 120 is the water passing through the first non-woven filter layer 110 by using a membrane separation method, only the pure water is passed through the membrane layer 120 due to the difference in concentration.

The second nonwoven filter layer 130 forms a layer in the membrane layer 120, and includes a space for providing the silver ion unit 140 in the second nonwoven filter layer 130. The second nonwoven filter layer 130 is manufactured using the first nonwoven filter layer 110 and a single nonwoven fabric. Therefore, the membrane layer 120 is inserted between the second nonwoven filter layer 130 and the first nonwoven filter layer 110 to form a boundary of the nonwoven fabric. Therefore, a single nonwoven fabric is wound in a roll form to form a layer having a predetermined width and a membrane fabric is inserted therebetween (ⓑ). The filter can then be rolled up again in the form of a roll. The filter manufactured as described above does not require a plastic injection molding, and thus, a simple manufacturing process can omit many complicated processes, and the product can be produced only by an optimal process step, thereby improving the productivity of the filter cartridge. In addition, the scroll form has an advantage that the surface area per unit volume can be widened and the surface turbulence can be good for the cleaning effect on the contaminants on the membrane surface, thereby extending the life.

The silver ion unit 140 is provided in a space inside the second nonwoven filter layer 130. The silver ion unit 140 is composed of a plurality of silver ion ceramic balls 142. The silver ion ceramic ball 142 places a seed made of a ceramic material into silver ions made of powder or liquid and applies heat and pressure. Then, one surface of the ceramic seed 142 is manufactured by sintering so that silver ions are coated on the surface of the ceramic seed. Thus, the plurality of silver ion ceramic balls 142 are provided in the inner space of the second nonwoven filter layer 130. However, in another embodiment of the present invention, although the silver ion ceramic ball 142 may be located outside the first nonwoven filter layer 110 according to the intention of the designer, since the dust may occur in the ceramic ball itself, the inside of the filter may be More preferably located in space. In another embodiment of the present invention, other types of silver ion units, such as silver ion plates, may be used according to a designer's intention. Silver ions have a very strong bactericidal power and can eliminate microorganisms such as bacteria, fungi or Escherichia coli. Therefore, it can be effectively used for water purifiers and bidets because it removes the harmful elements.

The filter according to the present invention is a filter having a multilayer structure of the first nonwoven filter layer 110, the membrane layer 120, and the second nonwoven filter layer 130. Therefore, various metals, chemicals, etc. can be filtered through several steps. In addition, the first nonwoven filter layer 110 and the second nonwoven filter layer 130 are wound using a nonwoven fabric, and toward the inside of the layer, fine dust removal efficiency is increased. In particular, in the membrane layer 120 interposed between the first nonwoven filter layer 110 and the second nonwoven filter layer 130, only pure water moves to the inside of the filter core by the principle of membrane separation to maximize fine dust removal efficiency. Can be.

Example 2

Figure 3 is a perspective view of a filter cartridge according to a second embodiment of the present invention, Figure 4 is a partial exploded view for explaining the operating principle of the filter cartridge according to the second embodiment, Figure 5 is a filter according to the second embodiment An exploded perspective view illustrating the filter in the cartridge. The filter cartridge according to the present invention is suitable to be mounted inside the bidet.

3 to 5, the filter cartridge may include a filter housing 210, a housing cover 220, a filter core 230, a first cover 240, a second cover 250, and a silver ion unit 260. ).

The filter housing 210 is formed in a hollow shape and is formed in a cylindrical shape. However, in another embodiment of the present invention can be formed in various forms. The housing cover 220 is formed at both ends of the filter housing 210 and covers both ends of the filter housing 210. The housing cover 220 includes a raw water part 222 and a water purification part 224. The raw water part 222 is formed at one end of the housing cover 220, and unpurified raw water passes through the raw water part 222 to be transferred from the outside of the filter housing 210 to the inside. However, in another embodiment of the present invention, the housing cover is omitted according to the intention of the designer, and the raw water and the purified water may be formed directly at both ends of the filter housing.

The filter core 220 includes a first nonwoven filter layer 232, a membrane layer 234, and a second nonwoven filter layer 236. The first nonwoven filter layer 232 forms a layer having a predetermined width inward from the surface of the filter. Here, the predetermined width means a width capable of effectively removing the desired fine dust size. The material of the first nonwoven filter layer 232 is made of a nonwoven fabric. The first nonwoven filter layer 232 is formed by winding in a cylindrical shape from the inside to the surface. The membrane layer 234 has a predetermined width inside the first nonwoven filter layer 232, and distinguishes the first nonwoven filter layer 232 and the second nonwoven filter layer 236. In the present invention, the filter is manufactured to be suitable for use in the bidet, the membrane layer 234 is composed of a membrane fabric having a pore of about 0.3 ~ 0.5㎛. However, in other embodiments of the present invention, membranes having pores of various sizes may be used according to the intention of the designer. The second nonwoven filter layer 236 forms a layer in the membrane layer 234, and includes a space for providing the silver ion unit 260 in the second nonwoven filter layer 236. The second nonwoven filter layer 236 is manufactured using the first nonwoven filter layer 232 and a single nonwoven fabric. Accordingly, the membrane layer 234 is inserted between the second nonwoven filter layer 236 and the first nonwoven filter layer 232. Therefore, a sheet of nonwoven fabric is wound in a roll to form a layer having a predetermined width, and a membrane fabric is inserted therebetween to define a boundary. Then, the filter core 230 is manufactured by winding again in a roll form.

The first cover 240 is mounted to one end of the filter core 230 and connected in a sealed state to the water purification unit 224. Therefore, the purified water passes from the outside of the filter core 230 to the inside of the water purification unit 224. The filter core 230 and the first cover and the second cover 240 and 250 are completely adhered to each other using a hot-melt adhesive. The hot-melt adhesive is a hot melt adhesive, which can be bonded at high speed, and has a wide range of adhesive properties. Therefore, it is a suitable method for high speed mass production and automated production. In the present invention, such a hot-melt adhesive is used to bond both ends of the filter core 230 to the first cover 240 and the second cover 250. Accordingly, the productivity of the product is increased because the manufacturing time and the manufacturing process can be reduced by high-speed adhesion using hot-melt adhesive to both side ends of the filter core 230 formed by winding the nonwoven fabric and the membrane. However, in another embodiment of the present invention can be bonded using a variety of adhesives according to the designer's intention. The protruding connecting pipe 242 is formed at the center of the first cover 240. At this time, a groove is formed in the outer surface of the connection pipe 242, the O-ring 244 is mounted in this groove to be fixed to be in close contact with the inside of the water purification unit 224, and thus the connection pipe 242 inside the water purification unit 224 Can be sealed to.

The second cover 250 is mounted to the other end of the filter core 230 and is likewise bonded using a hot-melt adhesive. Since the inside of the second cover 250 is completely blocked, the purified water of the filter core 230 is induced to diffuse toward the first cover 240. Thus, naturally purified water is delivered to the purified water unit 224.

The silver ion unit 260 is provided in a space inside the second nonwoven filter layer 236. The silver ion unit 260 is composed of a plurality of silver ion ceramic balls 262. Silver ions have a very strong bactericidal power and can eliminate microorganisms such as bacteria, fungi or Escherichia coli. Therefore, it can be effectively used for water purifiers and bidets because it removes the harmful elements.

Accordingly, in the filter cartridge according to the present invention, impurities are filtered while raw water delivered through the raw water part 222 passes through the outer surface of the filter core 230 and proceeds inside. And the water purified by the filter core 230 is passed through the connection pipe 242 to the outside again through the water purification unit 224, the raw water is changed to clean water.

Therefore, since the filter cartridge and the filter according to the present invention are a multilayer structure filter having a membrane layer formed between the first nonwoven filter layer and the second nonwoven filter layer, it is possible to filter various metals and chemicals and the like, thereby effectively removing fine dust.

In addition, a silver ion portion is formed inside the second nonwoven filter layer to obtain a bactericidal effect of killing various bacteria, fungi, and E. coli. In addition, since the filter is manufactured by winding the nonwoven fabric, the productivity can be increased, the surface area per unit volume can be increased, and the surface turbulence can be formed to improve the cleaning effect on contaminants on the surface of the membrane, thereby extending the life.

As described above, the present invention has been described with reference to a preferred embodiment of the present invention, but those skilled in the art various modifications and changes of the present invention without departing from the spirit and scope of the present invention described in the claims below I can understand that you can.

Claims (12)

A hollow filter housing including a raw water part that is an inlet for water to enter therein and a water purification part that is an outlet for outgoing water; A first nonwoven filter layer disposed inside the filter housing and formed in a cylindrical shape and having a predetermined width from a surface thereof, a membrane layer formed inside the first nonwoven filter layer, and a second formed inside the membrane layer A filter core comprising a nonwoven filter layer; A first cover mounted at one end of the filter core and connected in a sealed state to the purified water part to transfer purified water inside the filter core to the purified water part; And A second cover mounted to the other end of the filter core; A filter cartridge comprising a. The method of claim 1, The first and second nonwoven filter layers are composed of one nonwoven fabric, the nonwoven fabric is wound to form the first and second nonwoven fabric layers, and the membrane layer is a membrane fabric inserted between the wound nonwoven fabrics. And the first and second nonwoven filter layers are separated by the inserted membrane fabric. The method of claim 1, The second non-woven filter layer further comprises a silver ion portion including silver ions to enhance the sterilization function inside the filter core. The method of claim 3, The silver ion unit includes a plurality of silver ion ceramic balls filled in the inside of the filter core, and the silver ion ceramic ball includes a ceramic ball and silver ion powder sintered on the surface of the ceramic ball as a nucleus. Filter cartridge. The method of claim 1, And an end portion of the filter core is adhered to the first cover and the second cover using a hot-melt adhesive. The method of claim 1, And the first cover includes a connection tube protruding from the first cover, and connects the first cover and the water purification unit in a state in which the connection tube is inserted and sealed in the water purification unit. The method of claim 6, Filter cartridge, characterized in that the O-ring is mounted on the outer surface of the connecting pipe. The method of claim 1, The filter housing includes a housing cover covering at least one end, wherein the housing cover is formed with the raw water portion or the water purification portion. A first nonwoven filter layer formed in a cylindrical shape and having a predetermined width from the surface to the inside; A membrane layer formed inside the first nonwoven filter layer; And A second nonwoven filter layer formed inside the membrane layer and having a predetermined width; A filter having a. The method of claim 9, The first and second nonwoven filter layers are composed of one nonwoven fabric, the nonwoven fabric is wound to form the first and second nonwoven fabric layers, and the membrane layer is a membrane fabric inserted between the wound nonwoven fabrics. And the first and second nonwoven filter layers are separated by the inserted membrane fabric. The method of claim 9, And a silver ion portion provided with a plurality of silver ions in the second nonwoven filter layer to enhance sterilization function in the filter. The method of claim 11, The silver ion unit includes a plurality of silver ion ceramic balls filled in the inside of the filter core, and the silver ion ceramic ball includes a ceramic ball and silver ion powder sintered on the surface of the ceramic ball as a nucleus. Filter.