KR20140047997A - Composit filter of water purifier - Google Patents

Abstract

Disclosed is a composite filter of a water purifier which is capable of miniaturizing a water treatment device according to an embodiment of the present invention. The composite filter of the water purifier according to the present invention comprises: a filter housing with a water inlet and a water outlet; a static filter unit located inside the filter housing, and having static electricity for attaching foreign substances contained in water inflow by the water inlet; and a carbon filter unit located inside the static filter unit, filtering the foreign substances contained in the water, including a hollow hole unit connected to the water outlet. The present invention miniaturizes a filter through the said composition, thereby miniaturizing the water treatment device, remarkably reducing the repairing and managing cost of the water treatment device, and improving filterability of the filter.

Description

Compound filter of water treatment device {COMPOSIT FILTER OF WATER PURIFIER}

The present invention relates to a composite filter of a water treatment device, which can reduce the size of the water treatment device.

In general, a water treatment apparatus is a device for filtering purified water to produce purified water. Water treatment devices include various devices such as water purifier, water heater, water cooler, ionizer, and refrigerator.

Such water treatment apparatus may be provided with a plurality of filters for filtering raw water. For example, some or all of the sediment filter, precarbon filter, reverse osmosis filter or hollow fiber membrane filter, post carbon filter, etc. may be installed in the water treatment device. For example, Korean Unexamined Patent Publication No. 2011-0060998 (published on June 9, 2011) discloses a water purifier and a circulating sterilization method of a water purifier. As described, a plurality of filters may be installed in one of the water treatment devices.

Since the water treatment apparatus is provided with a plurality of filters as described above, there is a problem in that the size of the water treatment apparatus is limited in size. In addition, since the replacement cycle of the filter is different, there is a problem that the maintenance and repair cost of the water treatment apparatus is increased.

An embodiment of the present invention is to provide a complex filter of the water treatment device to be able to downsize the water treatment device.

According to an aspect of the invention, the filter housing is formed with the inlet and outlet; An electrostatic filter unit disposed inside the filter housing and applying static electricity to adsorb foreign substances contained in water introduced by the water inlet; And a carbon filter part disposed inside the electrostatic filter part, the hollow part being formed to be connected to the outlet, and filtering the foreign substances contained in the water; It provides a complex filter of the water treatment device comprising a.

The electrostatic filter part may be bent in a zigzag and formed in a pleated form.

The electrostatic filter unit may be formed of a material having static electricity.

The electrostatic filter may be formed with a plurality of pores of a predetermined size that can filter the foreign matter contained in the water.

The electrostatic filter may include activated carbon.

The electrostatic filter unit may include a plurality of electrostatic filter layers having pores of different sizes, and the electrostatic filter layer having smaller pores toward the carbon filter unit may be disposed.

0.5-2um of voids may be formed in the outermost electrostatic filter layer.

In the innermost electrostatic filter layer, pores of 0.05-0.5 um may be formed.

The carbon filter may further include a fine dust filter unit disposed in the hollow portion and connected to the water outlet, and filtering foreign matter contained in the water passing through the carbon filter unit.

The inner surface of the carbon filter unit and the outer surface of the fine dust filter unit may be spaced apart.

According to the embodiments of the present invention, the water treatment apparatus can be miniaturized by miniaturizing the filter by embedding various filter units in one filter.

In addition, according to embodiments of the present invention, the cost of maintaining the water treatment apparatus can be significantly reduced.

In addition, according to embodiments of the present invention, it is possible to improve the filtration performance of the filter.

1 is a perspective view showing an embodiment of a composite filter of a water treatment device according to the present invention.
2 is an exploded perspective view illustrating the composite filter of FIG. 1.
3 is a longitudinal cross-sectional view illustrating the composite filter of FIG. 1.
4 is a cross-sectional view illustrating the composite filter of FIG. 1.
5 is a perspective view illustrating a dust filter unit of the composite filter of FIG. 1.
FIG. 6 is a longitudinal cross-sectional view illustrating the dust filter unit of the composite filter of FIG. 1. FIG.
FIG. 7 is a perspective view illustrating a particulate filter material constituting the particulate filter of FIG. 5.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing an embodiment of a composite filter of the water treatment device according to the present invention, Figure 2 is an exploded perspective view showing the composite filter of Figure 1, Figure 3 is a longitudinal cross-sectional view showing the composite filter of Figure 1 4 is a cross-sectional view illustrating the composite filter of FIG. 1.

1 to 4, the composite filter 100 of the water treatment device may include a filter housing 110, an electrostatic filter unit 120, and a carbon filter unit 130.

The filter housing 110 may include a housing body 111 and a sealing cap 113. The housing body 111 may be formed in a cylindrical or polygonal shape in which one side is opened and the other side is closed. The sealing cap 113 may be coupled to the opening of the housing body 111 to seal the inside of the housing body 111.

The inlet port 115 and the outlet port 116 may be formed in the sealing cap 113. The outlet 116 is formed in the center of the sealing cap 113, the inlet 115 may be formed around the outlet 116 a number. The structure of the outlet 116 and the inlet can be modified in various forms.

The water inlet 115 forms a passage through which water is introduced into the filter housing 110, and the water outlet 116 is configured to discharge water filtered from the filter housing 110 to the outside of the filter housing 110. A passage can be formed. The water discharged from the outlet 116 may flow into a purified water tank, a hot water tank, a cold water tank, or a direct water line according to the type of water treatment device.

The sealing cap 113 may be screwed into the opening of the housing body 111 or attached by an adhesive. In addition, the sealing cap 113 may be forcibly fitted into the opening of the housing body 111. In addition, the O-ring may be fitted to the sealing portion of the sealing cap 113 and the housing body 111 to seal the gap. The coupling structure of the sealing cap 113 and the housing body 111 can be variously modified.

The electrostatic filter unit 120 may be disposed inside the filter housing 110. The electrostatic filter unit 120 may be formed of a material that is electrostatically charged, such as a nanotrap material, to adsorb foreign substances contained in the water introduced by the inlet 115. Such materials may be configured to carry a positive charge. Accordingly, negatively charged foreign matters, such as viruses, bacteria, and fine particles contained in the water may be adsorbed onto the material forming the electrostatic filter unit 120 by static electricity.

The configuration of the material constituting the electrostatic filter unit 120 for this purpose is not particularly limited, and any configuration known in the art can be used as long as the configuration is positively charged. However, the material forming the electrostatic filter unit 120 may be configured to take a negative charge.

The electrostatic filter unit 120 may also be formed with a plurality of pores of a predetermined size that can filter the foreign matter contained in the water. That is, a large number of voids may be formed in the material forming the electrostatic filter unit 120. Accordingly, the electrostatic filter unit 120 collects the foreign matter contained in the water by static electricity as described above, and collects the foreign matter contained in the water while passing the plurality of pores formed in the electrostatic filter unit 120. It can be filtered. As a result, the filtration performance of the electrostatic filter unit 120 may be significantly improved.

The electrostatic filter unit 120 may be bent in a zigzag and formed in a pleated form. For example, the electrostatic filter unit 120 may be zigzag along the circumferential direction of the filter housing 110 and may be formed in a cylindrical shape as a whole. Since the electrostatic filter unit 120 is formed in a pleated form, the contact area with water may be increased to about 1.5-10 times. Therefore, by maximizing the effective filtration area of the electrostatic filter unit 120, the filtration performance of the electrostatic filter unit 120 may be further improved.

The electrostatic filter unit 120 may include activated carbon. For example, activated carbon powder may be included in a material forming the electrostatic filter unit 120, so that activated carbon may be included in the electrostatic filter unit 120. Thereby, the filtration performance of the electrostatic filter part 120 can be improved more.

The electrostatic filter unit 120 may include a plurality of electrostatic filter layers 121, 123, and 125 having pores of different sizes. The plurality of electrostatic filter layers 121, 123, and 125 may be sequentially stacked to form one filtering sheet. In FIG. 4, the electrostatic filter layers 121, 123, and 125 are illustrated in which three layers are stacked. However, the electrostatic filter layers 121, 123, and 125 may be fabricated in such a manner that two layers or four or more layers are stacked.

Since the electrostatic filter unit 120 includes a plurality of electrostatic filter layers 121, 123, and 125 having pores of different sizes, foreign substances having different sizes may be filtered for each of the electrostatic filter layers 121, 123, and 125. Therefore, it is possible to prevent a specific portion of the electrostatic filter unit 120 from being concentrated by foreign matters, and to prevent the filtration function from being biased in a portion of the electrostatic filter unit 120. Furthermore, since the entire electrostatic filter unit 120 may normally filter foreign matter, the performance of the composite filter 100 may be improved and the life of the filter may be extended. In addition, since the water pressure of the composite filter 100 can be prevented from being significantly increased as the electrostatic filter unit 120 is blocked, damage to the composite filter 100 to the water treatment device can be prevented.

Electrostatic filter layers 121, 123, and 125 having smaller pores may be disposed in the electrostatic filter unit 120 toward the carbon filter unit 130 (center portion of the composite filter). That is, the electrostatic filter unit 120 may be disposed on the outermost electrostatic filter layer 121 having the largest gap and the electrostatic filter layer 125 having the smallest gap formed therein. Since the voids are gradually formed from the outer side to the inner side of the electrostatic filter unit 120, the foreign substances having the largest size are filtered out of the outermost electrostatic filter layer 121, and the smallest size of the innermost electrostatic filter layer 125. Foreign material can be filtered out.

In this way, the electrostatic filter unit 120 is filtered out of the outermost largest foreign matter first and then gradually small foreign matter is filtered toward the innermost, the size of the foreign matter filtered along the thickness direction of the electrostatic filter unit 120 Can vary. Furthermore, when viewed based on the thickness direction of the electrostatic filter unit 120, the filtration performance of the outer and inner sides of the electrostatic filter unit 120 may be significantly uniform.

In addition, the specific electrostatic filter layer of the electrostatic filter unit 120 may be prevented from being concentrated by foreign matters, and the filtering function may be prevented from being biased in the specific layer of the electrostatic filter unit 120. In addition, since almost all of the electrostatic filter layers 121, 123, and 125 can filter foreign substances normally, the performance of the composite filter 100 may be improved and the life of the composite filter may be extended. In addition, as the specific layer of the electrostatic filter unit 120 is blocked, it is possible to prevent the water pressure of the composite filter 100 from being significantly increased, thereby preventing damage to the composite filter or the water treatment device. Furthermore, since the electrostatic filter unit 120 may exhibit uniform filtration performance in the longitudinal direction and the thickness direction as a whole, the electrostatic filter unit 120 may participate in filtration as a whole.

An embodiment of the electrostatic filter unit 120 will be described below.

0.5-2um of voids may be formed in the outermost electrostatic filter layer 121. When the air gap of the outermost electrostatic filter layer 121 is less than 0.5 μm, a relatively small amount of water may pass through the outer surface of the electrostatic filter unit 120. Therefore, since the flow performance of water in the electrostatic filter unit 120 is significantly reduced, the water pressure of the composite filter 100 is abnormally increased, and the filtration performance of the electrostatic filter unit 120 may be significantly reduced. In addition, as the water pressure of the composite filter increases, the risk of damaging the composite filter or the water treatment device may be significantly increased.

In contrast, when the air gap of the outermost electrostatic filter layer 121 is greater than 2 μm, a relatively large amount of water may pass through the outer surface of the electrostatic filter unit 120. Accordingly, foreign matter may be hardly filtered through the outermost electrostatic filter layer 121, and filtration of foreign matter may be biased to the electrostatic filter layers 123 and 125 disposed inside. Furthermore, it may be difficult for the electrostatic filter unit 120 to perform the filtration function uniformly as a whole.

In addition, a gap of 0.05-0.5 um may be formed in the innermost electrostatic filter layer 125. The innermost electrostatic filter layer 125 is a layer that finally filters foreign substances and viruses in the electrostatic filter unit 120.

When the air gap of the innermost electrostatic filter layer 125 is less than 0.05 μm, a significantly small amount of water may pass through the inner surface of the electrostatic filter unit 120. Therefore, since the flow performance of water in the electrostatic filter unit 120 is significantly reduced, the water pressure of the composite filter is abnormally increased, and the filtration performance of the electrostatic filter unit 120 may be significantly reduced. In addition, as the water pressure of the composite filter increases, the risk of damaging the composite filter or the water treatment device may be significantly increased.

On the contrary, when the air gap of the innermost electrostatic filter layer 125 exceeds 0.5 μm, since the inner air gap of the electrostatic filter unit 120 is formed too large, foreign substances, viruses, etc. are finally generated in the electrostatic filter unit 120. It may be difficult to filter.

As such, the voids of the electrostatic filter layer of the electrostatic filter unit 120 should be properly designed in consideration of the capacity, water pressure, filtration performance, or filtration rate of the water treatment device.

A support (not shown) may be disposed inside the electrostatic filter 120 to maintain the shape of the electrostatic filter 120. The support may be formed of a porous material to allow water to pass therethrough. The support may allow the electrostatic filter unit 120 to be stably fixed to the carbon filter unit 130.

The carbon filter unit 130 may be disposed inside the electrostatic filter unit 120. The carbon filter unit 130 may be a carbon block in which carbon powder is solidified in a cylindrical or polygonal cylinder shape. The carbon filter 130 has a hollow portion formed to be connected to the water outlet 116, and may filter foreign substances contained in the water filtered by the electrostatic filter unit 120. The carbon filter unit 130 may filter heavy metals such as lead contained in water.

4 is a cross-sectional view illustrating the composite filter of FIG. 1, FIG. 5 is a perspective view illustrating the fine dust filter unit of the composite filter of FIG. 1, and FIG. 6 is a longitudinal cross-sectional view illustrating the fine dust filter unit of the composite filter of FIG. 1. FIG. 7 is a perspective view illustrating a dust filter material constituting the dust filter of FIG. 5.

4 to 7, the composite filter 100 may further include a fine dust filter unit 140 disposed at a hollow portion of the carbon filter unit 130 and connected to the outlet port 116. The fine dust filter 140 may filter foreign matter contained in the water passing through the carbon filter 130. For example, the fine dust filter unit 140 may filter various particulate matter as well as carbon dust generated from the carbon filter unit 130 during the initial use and use of the filter.

The outer surface of the fine dust filter unit 140 may be spaced apart from the inner surface of the carbon filter unit 130. As the fine dust filter 140 and the carbon filter 130 are spaced apart from each other, a buffer space 141 may be formed inside the carbon filter 130. The buffer space 141 allows the water passing through the carbon filter unit 130 to form a uniform water pressure as a whole in the buffer space 141. Therefore, since the overall uniform water pressure acts on the fine dust filter unit 140, the filtration performance of the fine dust filter unit 140 can be made uniform throughout.

An embodiment of the fine dust filter 140 is as follows.

The dust filter 140 may include a core member 143 and a dust filter material 145.

The core member 143 may be formed in a cylindrical shape as a whole. A plurality of through holes 143a may be formed in the core member 143 to allow water to pass therethrough. In addition, the core member 143 is made of a water permeable material may pass through the water. One side of the core member 143 may be opened and the other side may be closed. The opening of the core member 143 may be connected to the outlet 116 of the sealing cap 113. The core member 143 supports the fine dust filter material 145 to form a certain shape to allow water to pass therethrough.

The fine filter material 145 may be installed in a structure wound around the core member 143. The fine dust filter material 145 may be wound around the outer surface of the core member 143 in various forms. For example, the fine dust filter material 145 may be formed in a form wound in one layer or a plurality of layers wound on the outer surface of the core member 143. When the fine dust filter material 145 is wound in plural layers, since the water passes through the dust filter material 145 in a zigzag, the flow distance of the water may be long. Therefore, since the contact area between the fine dust filter material 145 and water is increased, the filtration performance of carbon dust and particulate matter can be significantly improved.

The dust filter material 145 may include support layers 146a and 146b and dust filter layers 147a and 147b. The support layers 146a and 146b may be disposed on both sides of the dust filter material 145, and the dust filter layers 147a and 147b may be disposed between the support layers 146a and 146b.

The support layers 146a and 146b support the fine dust filter layers 147a and 147b. The support layers 146a and 146b may be porous members in which pores are formed to allow water to pass therethrough.

At least two fine dust filtration layers 147a and 147b may be stacked between the support layers 146a and 146b. The fine dust filtering layers 147a and 147b may be formed of a nonwoven fabric having a void, a fiber membrane, a synthetic resin membrane, or a composite thereof. At this time, each of the fine dust filter layers 147a and 147b may be manufactured in a woven form by crossing a seed line and a blade line.

The fine dust filtering layers 147a and 147b may have pores of different sizes. That is, the fine dust filtering layers 147a and 147b facing the inner surface of the dust filter material 145 have relatively small voids, and the fine dust filtering layer 147a facing the outer surface of the dust filter material 145. 147b) may have relatively large voids. Since the fine dust filtering layers 147a and 147b have pores of different sizes, carbon dust and particulate matter having different sizes may be filtered for each of the fine dust filtering layers 147a and 147b.

Therefore, since the specific dust filter layers 147a and 147b can be prevented from being concentrated, the dust filter unit 140 can maintain a uniform filter performance as a whole. In addition, since the flow performance of the water in the fine dust filter unit 140 may be improved, it is possible to prevent the water pressure from being abnormally increased inside the composite filter 100.

Hereinafter, a description will be given based on a configuration in which two fine filtration layers are stacked.

The fine dust filter 140 may include a first fine dust filtering layer 147a and a second fine dust filtering layer 147b.

A pore of 1-10 μm may be formed in the first fine dust filtration layer 147a. When the pore of the first fine dust filtering layer 147a is less than 1 μm, a large amount of carbon dust and particulate foreign matter may be concentrated in the first fine dust filtering layer 147a. Therefore, the amount of water passing through the first fine dust filter layer 147a is significantly reduced, and the filtration performance may be degraded. In addition, since the filtration of water is biased in the first fine dust filtration layer 147a, it may be difficult for the fine dust filter 140 to have a uniform filtration performance as a whole.

On the other hand, when the pore of the first fine particle filtration layer 147a is more than 10 μm, the amount of filtration of carbon dust and particulate matter to be filtered in the second fine particle filtration layer 147b may increase. In this case, since the filtration is biased in the second fine filtration layer 147b, it may be difficult for the fine dust filter 140 to have a uniform filtration performance as a whole.

0.2-1um of voids may be formed in the second fine dust filtration layer 147b. When the pore of the second fine particle filter layer 147b is less than 0.2 μm, the fluidity of water in the second fine particle filter layer 147b may be significantly deteriorated, thereby lowering the filtration performance.

On the other hand, when the pore of the second fine dust filtering layer 147b is greater than 1 μm, the pore of the second fine dust filtering layer 147b is similar to the first fine dust filtering layer 147a, so that the second fine dust filtering layer is At 147b, normal filtration may be difficult to proceed.

In consideration of the capacity, water pressure, filtration performance or filtration rate of the water treatment device, the space of the fine filtration layer in the fine dust filter unit 140 should be appropriately designed.

The water filtered by the fine dust filter 140 may be discharged to the outside of the composite filter through the water outlet 116.

As described above, since the composite filter installs the electrostatic filter unit, the carbon filter unit, and the like within one filter housing, the space in which the filter is installed in the water treatment apparatus can be significantly reduced. Thus, the size of the water treatment device can be significantly reduced.

In addition, the composite filter can be incorporated in one filter in a variety of filters, it is possible to significantly reduce the cost of maintaining the water treatment device.

In addition, since the water is filtered through various filter parts such as an electrostatic filter part and a carbon filter part, the composite filter may improve filtration performance.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: composite filter 110: filter housing
111: housing body 113: sealing cap
115: inlet 116: outlet
120: electrostatic filter 121,123,125: electrostatic filter layer
130: carbon filter unit 140: fine dust filter unit
141: buffer space 143: core member
143a: through-hole 145: fine dust filter material
146a and 146b: support layer 147a and 147b fine dust filtration layer

Claims (10)

A filter housing having an inlet and an outlet;
An electrostatic filter unit disposed inside the filter housing and applying static electricity to adsorb foreign substances contained in water introduced by the water inlet; And
A carbon filter part disposed inside the electrostatic filter part, and having a hollow part formed to be connected to the water outlet, and filtering foreign substances contained in the water;
Complex filter of the water treatment device comprising a.
The method according to claim 1,
The electrostatic filter unit is bent in a zigzag form a complex filter of the water treatment apparatus, characterized in that formed in the pleated form.
The method according to claim 1,
The electrostatic filter unit is a composite filter of a water treatment device, characterized in that made of a material that is electrostatic.
The composite filter of claim 1, wherein the electrostatic filter unit has a plurality of pores having a predetermined size to filter foreign substances contained in water.
The method according to claim 1,
The electrostatic filter unit is a composite filter of the water treatment device, characterized in that the activated carbon.
6. The method according to any one of claims 1 to 5,
The electrostatic filter unit includes a plurality of electrostatic filter layers having pores of different sizes,
The composite filter of the water treatment device, characterized in that the electrostatic filter layer having a small gap is arranged toward the carbon filter portion.
The method according to claim 6,
The composite filter of the water treatment device, characterized in that the gap of 0.5-2um is formed in the outermost electrostatic filter layer.
The method according to claim 6,
Composite filter of the water treatment device, characterized in that the air gap of 0.05-0.5um is formed in the innermost electrostatic filter layer.
The method according to claim 1,
A fine dust filter unit disposed at a hollow portion of the carbon filter unit and connected to the water outlet, and filtering foreign matter contained in water passing through the carbon filter unit; Complex filter of the water treatment device further comprising.
The method of claim 9,
An inner surface of the carbon filter part and an outer surface of the fine dust filter part are spaced apart from each other.

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