KR20230147335A - Device for purifying water - Google Patents

Abstract

The water purification device according to the present invention is a filter cylinder body with a water supply pipe connected to the lower part and a side wall formed in the circumferential direction to form a space for receiving water supplied inside through the water supply pipe, and is coupled to the upper part of the filter cylinder body and upper and lower sides. A middle plate through which a through hole is formed, through which the water contained in the filter cylinder moves upward, a discharge cylinder coupled to the upper part of the middle plate, and a steel wire with protrusions formed on the upper portion at regular intervals are continuous. It includes a spiral spring formed by being wound in a spiral shape, the upper spring portion is seated on the protrusion, and includes a spring filter coupled to the intermediate plate inside the filter cylinder.

Description

{Device for purifying water}

The present invention relates to a water purification device, and more specifically, to a water purification device that can be used semi-permanently without replacing the filter that filters water.

In general, water is a liquid that makes up about 70% of the human body, and is the source of life and an essential substance for living phenomena. However, recently, due to various environmental pollution, water contains contaminants such as organic substances, inorganic substances, and harmful substances, making it unsuitable for drinking.

In particular, in the case of tap water, which is the most commonly encountered water in modern society, secondary pollution occurs when contaminants introduced into the raw water are not filtered out during the water purification process or are generated due to aging of drain pipes and water supply pipes. This may result in a condition that is unsuitable for immediate use.

As a result, schools, military bases, government offices, etc. are increasingly installing and using water purifiers, which are devices that purify tap water, and the water purifier market is also expanding.

Recently, many people purchase and drink bottled water instead of using water purifiers, but it is also common for bottled water to be contaminated due to various factors, so the number of schools, military units, and government offices using water purifiers is increasing. As interest in water increases, In many cases, water purified through a water purifier was used only as drinking water, but its scope of use is gradually expanding, including use as cooking water in group meals such as school cafeterias.

Such a water purifier is used by installing a water purifier filter inside the device, and the water flowing into the device is filtered and purified by the water purifier filter before being discharged.

As filters for water purifiers that perform the filtration function, carbon filters, sediment filters, and UF membrane filters are mainly used.

In addition, in addition to the carbon filter and the sediment filter, a hollow fiber membrane filter is provided to remove viruses so that people can drink water, and an electrostatic adsorption filter is provided before the hollow fiber membrane filter, thereby removing nano particles contained in the running water. A filter system that solves the problem of clogging of hollow fiber membrane filters caused by nanoparticles and a decrease in water flow rate by filtering particles is used, but this uses multiple filters, which increases the volume of the water purifier and increases material and installation costs. There is a problem with maintenance being inconvenient.

Meanwhile, when looking at prior art literature regarding filters for water purifiers, Domestic Patent No. 101-103a10103a71 includes an external housing with an open top, a space inside, and an outlet at the bottom; A cap is detachable from the upper part of the external housing and allows water to flow through an inlet formed at the upper part, wherein the upper part of the external housing is open and has a space part, and the lower part has an internal outlet in communication with the outlet of the external housing. A water purifier filter structure is disclosed, wherein an inner housing is formed, and activated carbon is inserted into the inner housing.

However, in the case of such a conventional water purification device, there is a problem in that the filter becomes clogged with foreign substances as a certain usage time elapses, necessitating periodic replacement of the filter and incurring maintenance costs.

Therefore, the present invention was made to solve the problems of the prior art, and its purpose is to provide a water purification device that can be used semi-permanently and reduces maintenance costs without replacing filters.

A water purification device according to a preferred embodiment of the present invention is a filter cylinder body in which a water supply pipe 10 is connected to the lower part and a side wall forming a space for accommodating water supplied inside through the water supply pipe 10 is formed in the circumferential direction. 101), and a through hole (103a) is formed that is coupled to the upper part of the filter body (101) and penetrates upward and downward, and the water contained in the filter body (101) moves upward through the through hole (103a). A plate 103, a discharge cylinder 105 coupled to the upper part of the intermediate plate 103, and a spiral spring ( 152), and the upper spring 152 portion is seated on the protrusion 152a, and includes a spring filter 150 coupled to the intermediate plate 103 inside the filter cylinder 101. It is characterized by

In addition, the spring filter 150 includes a central plate 151 extending vertically in the center,

A lower support member 154 including a bottom coupled to the lower end of the central plate 151 to support the lower end of the spiral-shaped spring 152, and a side portion protruding from the edge of the bottom in the circumferential direction. )and,

It is coupled to the upper part of the central plate 151 and further comprises an upper fixing member 153 coupled to the through hole of the intermediate plate to fix the spring filter 150 to the intermediate plate 103. Do it as

In addition, the central plate 151 is characterized in that the plane of the plate rotates along the vertical and longitudinal directions, so that the side surfaces of the central plate 151 have a spiral shape along the longitudinal direction.

In addition, between the spiral spring 152 and the central plate 151, there is an upper bent portion 160a made of a single steel wire that extends upward and is bent downward, and an upper bent portion 160a extending downward from the upper bent portion 160a. The lower bent portions 160b, which are bent upward, are alternately and repeatedly formed and further include bending extension members 160 formed along the circumferential direction on the inner peripheral surface of the spiral spring 152.

In addition, another spiral-shaped spring 152' is disposed between the bent extension member 160 and the central plate 151, and is formed by continuously winding a steel wire with protrusions 152a at regular intervals in a spiral shape. , Characterized in that the upper spring 152 is seated on the protrusion 152a of the another spiral-shaped spring 152'.

In addition, an additional spring 170 is disposed between the spiral spring 152 and the central plate 151, and is formed by continuously winding a steel wire with protrusions 170a at regular intervals in a spiral shape. The upper spring 170 is seated on the protrusion 170a of (170), and the additional spring 170 is formed in a direction opposite to that of the spiral spring 152. .

In addition, the gap of the additional spring 170 intersects the gap of the spiral spring 152.

In addition, it further includes a pressure sensor 106 for measuring the internal pressure of the filtering body 101, and when the internal pressure of the filtering body 101 measured by the pressure sensor 106 is higher than a preset constant pressure, the control unit Water is supplied through the discharge pipe 11 coupled to the discharge cylinder 105 by a pump, and while moving the water from the discharge cylinder 105 to the filter cylinder 101, it is attached to the spring filter 150. It is characterized by removing existing foreign substances.

In addition, a male thread portion is formed on the outer peripheral surface of the upper fixing member 153, and the male thread portion of the upper fixing member 153 is screwed to a female thread formed in the through hole 103a of the intermediate plate 103. Do it as

In addition, a lower extension portion 153a is formed at the lower part of the upper fixing member 153, extending downward from the upper end of the spiral spring 152 and covering the upper part of the spiral spring 152 in the circumferential direction. It is characterized by being

In addition, the filtering cylinder 101 further includes a bottom plate 102 in which the lower end of the side wall is coupled and a coupling hole in the center is formed in which the water supply pipe 10 is coupled,

The discharge cylinder 105 includes an upper plate 104 to which the discharge pipe 11 is coupled, and a side wall formed along the circumference to form an internal space by being coupled to the lower part of the upper plate 104. It is characterized by

In addition, the spring filter 150 is characterized in that a diatomaceous earth layer 180 is formed on the outside of the spiral-shaped spring 152.

According to the present invention, a water purification device is provided that reduces maintenance costs without replacing filters and can be used semi-permanently.

1 is a cross-sectional view of a water purification device according to the present invention;
Figure 2 is a plan cross-sectional view of the intermediate plate in the present invention,
Figure 3 is a detailed view of the spring filter in the present invention,
Figure 4 is a partially enlarged view of Figure 3,
Figure 5 is a diagram showing the coupling relationship between the spiral-shaped spring and the bent extension member in the spring filter in the present invention;
Figure 6 is a plan view of Figure 5,
Figure 7 is a diagram showing another embodiment of the spring filter in the present invention;
Figure 8 is a diagram showing another embodiment of the spring filter in the present invention,
Figure 9 is a plan view of Figure 8.

Hereinafter, the water purification device 100 according to the present invention will be described in detail with reference to preferred embodiments.

Figure 1 is a cross-sectional view of a water purification device according to the present invention, Figure 2 is a plan cross-sectional view of the intermediate plate in the present invention, Figure 3 is a detailed view of the spring filter in the present invention, Figure 4 is a partially enlarged view of Figure 3, Figure 5 is a diagram showing the coupling relationship between the spiral-shaped spring and the bent extension member in the spring filter in the present invention, Figure 6 is a plan view of Figure 5, and Figure 7 shows another embodiment of the spring filter in the present invention. It is a drawing, and Figure 8 is a diagram showing another embodiment of the spring filter in the present invention, and Figure 9 is a plan view of Figure 8.

The water purification device 100 according to a preferred embodiment of the present invention includes a filter body 101 to which the water supply pipe 10 is connected at the bottom, a middle plate 103 coupled to the upper part of the filter body 101, and the middle plate 103. It includes a discharge cylinder 105 coupled to the upper part of the plate 103, and a spring filter 150 coupled to the intermediate plate 103 inside the filter cylinder 101 to filter water.

In the present invention, the filter body 101 is connected to the water supply pipe 10 at the bottom to accommodate the water supplied from the water supply pipe 10 and filters the water by the spring filter 150, and has a circular bottom plate ( 102) and a side wall that is coupled to the upper part of the bottom plate 102 and forms a space for receiving water supplied therein.

A coupling hole is formed in the center of the circular bottom plate 102, and the water supply pipe 10 is coupled to this coupling hole to supply water into the filter tube 101. And, the lower end of the circular side wall of the filter cylinder 101 is fitted around the edge of the bottom plate 102 and coupled thereto.

The side wall of the filter tube 101 is circular in this embodiment, but is not limited thereto and may also be rectangular or polygonal. The material of the side wall may be transparent or opaque. If the side wall is made of a transparent material, there is an advantage that the water quality and filtration status can be checked with the naked eye.

The intermediate plate 103 is coupled to the top of the side wall of the filter cylinder 101, and a plurality of through holes 103a are formed. A female thread is formed in the lower part of the through hole 103a that penetrates upward and downward, and the upper fixing member 153 of the spring filter 150 is screwed to it.

In addition, the upper end of the side wall of the filter cylinder 101 is fitted and coupled to the lower surface of the middle plate 103, and the lower end of the side wall of the discharge cylinder 105 is fitted and coupled to the upper surface of the middle plate 103.

The discharge cylinder 105 is coupled to the upper part of the middle plate 103 to receive water filtered by the spring filter 150 through the through hole 103a of the middle plate 103. It includes a side wall forming the side and an upper plate 104 coupled to the top of the side wall.

The lower end of the circular side wall of the discharge cylinder 105 is coupled to the upper surface of the middle plate 103, and the upper end of the circular side wall of the discharge cylinder 105 is coupled to the upper plate 104.

The side wall of the discharge cylinder 105 is also circular in this embodiment, but is not limited thereto and may also be rectangular or polygonal. The side wall of the discharge cylinder 105 may be made of a transparent or opaque material. If the side wall is made of a transparent material, the water quality and filtration status can be confirmed with the naked eye.

A coupling hole is formed in the center of the circular upper plate 104, and the discharge pipe 10 is coupled to this coupling hole, so that the filtered water in the discharge cylinder 105 is discharged. Then, the upper end of the side wall of the discharge cylinder 105 is fitted and coupled to the lower surface of the upper plate 104.

The spring filter 150 is coupled to the middle plate 103 inside the filter body 101 to filter water flowing into the filter body 101, and includes a central plate 151 and a central plate 151. It includes a lower support member 154 coupled to the lower end, an upper fixing member 153 coupled to the upper part of the center plate 151, and a spiral-shaped spring 152.

In the spring filter 150, the central plate 151 is formed in the form of a plate extending vertically, and the lower end of the central plate 151 is fixed to the lower support member 154 with a bolt 155, and the central plate 151 is fixed to the lower support member 154 with a bolt 155. A ring portion (151a) is formed at the top, and this ring portion (151a) is caught and fixed to the locking portion (103b) disposed in the through hole (103a).

As shown in FIG. 3, the center plate 151 is formed in a shape in which the plate plane rotates along the vertical and longitudinal directions, and the side surfaces of the central plate 151 form a spiral shape along the longitudinal direction. When the central plate 151 is formed in this way, during washing, the washing water is supplied from the discharge cylinder 105 into the spring filter 150 and then discharged to the outside of the spring filter 150. At this time, the central plate ( Washing efficiency is improved by supplying washing water to the spiral-shaped spring 152 in a radial direction from the center of 151).

The lower support member 154 is coupled to the lower end of the center plate 151 to support the lower end of the spiral spring 152, and has a circular bottom 154a and protrudes from the edge of the bottom 154a. It includes a circular side portion 154b formed along the circumferential direction and is fixed to the bottom of the central plate 151 with a bolt 155.

The upper fixing member 153 is coupled to the upper part of the center plate 151 to fix the spring filter 150 to the middle plate 103. A male thread is formed on the outer peripheral surface of the upper fixing member 153 and the middle plate ( It is screwed into the through hole (103a) of 103). In addition, the lower part of the cylindrical upper fixing member 153 is formed with a lower extension portion 153a extending downward from the upper end of the spiral spring 152 to cover the upper part of the spiral spring 152 in the circumferential direction. It is formed as follows.

In the spring filter 150, the spiral-shaped spring 152 is disposed around the outer circumference of the center plate 151 and is made of a steel wire wound continuously in a spiral shape, and the spiral-shaped spring 152 has protrusions at regular intervals. (152a) is formed. The protrusion 152a is formed integrally with the upper part of the spiral spring 152, protrudes upward, and has a height of about 10㎛-100㎛ in this embodiment. Therefore, as shown in Figure 5, the spiral springs 152 are wound in close contact with each other and the upper spring 152 portion is seated on the upper surface of the protrusion 152a. In this embodiment, the spiral-shaped spring 152 is made of a steel wire made of stainless steel that is resistant to corrosion, but it is not necessarily limited to this and other materials that are resistant to corrosion may be used.

In addition, as shown in Figures 5 and 6, a bent extension member 160 formed by repeatedly bending in an up and down zigzag manner may be disposed inside the spiral spring 152 and the central plate 151.

The bending extension member 160 is formed along the circumferential direction on the inner peripheral surface of the spiral-shaped spring 152 to filter out finer foreign substances and increase filtration performance. It is made of a single steel wire and has an upper bend that extends upward and bends downward. The portion 160a and the lower bent portion 160b, which extends downward from the upper bent portion 160a and is bent upward again, are alternately formed. The bent extension member 160 is also made of a steel wire made of stainless steel, which is resistant to corrosion, but is not necessarily limited thereto.

In the adjacent upper and lower extension parts 160c and 160d of the bent extension member 160, the gap between the left upper and lower extension parts 160c and the right upper and lower extension parts 160d is about 10㎛, which is the height of the protrusion on the spiral spring 152. It may be formed equal to -100㎛ or may be formed smaller than this.

Meanwhile, Figure 7 shows another example of the spring filter 150. In Figure 7, another spiral-shaped spring 152' is disposed between the central plate 151 and the inside of the bent extension member 160. do. The configuration of another spiral-shaped spring 152' is the same as that of the spring 152. That is, protrusions 152a are formed at regular intervals in another spiral-shaped spring 152', and the protrusions 152a are integrally formed on the upper part of the spiral-shaped spring 152', protrude upward, and have a height of approximately. It is formed to have a height of 10㎛-100㎛.

In this way, another additional spiral-shaped spring 152 is disposed between the bent extension member 160 and the central plate 151 to filter out finer foreign substances, further improving filtration performance, and further improving the bending extension member 160. By supporting it, the bent extension member 160 is prevented from being deformed over time.

Meanwhile, a pressure sensor 106 is installed to measure the pressure inside the filtering tube 101.

When explaining the process of purifying water in the filtration device of the present invention configured as described above, water is first introduced into the filtration tube 105 through the water supply pipe 10 using a pump (not shown).

The raw water flowing into the filter tube 101 is filled with the discharge tube 105 through the through hole 103a of the intermediate plate 103 with foreign substances removed through several spring filters 150, and is filtered. Water is discharged through the discharge pipe (11).

To explain in more detail the process in which the raw water filled in the filter tube 101 is filtered by the spring filter 20, the raw water is filtered according to the height of the protrusion 152a formed on the spiral spring 152 of the spring filter 20. It flows into the inside of the spring filter 150 through the formed gap and the gap between the left and right upper and lower extension parts 160c and 160d in the bent extension 160, and through this process, water is filtered and discharged into the discharge cylinder 105. It is discharged through.

The height of the protrusion 152a can be set and used depending on the type of raw water used. In the present invention, in order to further improve filtration performance, the spiral-shaped spring 152 of the spring filter 150 is used as shown in FIG. 4. A diatomaceous earth layer 180 is formed on the outside.

For this, when a separate pipe is connected to the water supply pipe (11) and an auxiliary mixed with diatomaceous earth is supplied together with water to the filter tube 105, some of the diatomaceous earth as an auxiliary agent flows into the inside of the spring filter 150, but a large amount It is attached to the outside of the spring filter 150 to form a diatomaceous earth layer 50.

In particular, the diatomaceous earth layer 50 is attached to the outer surface of the spring filter 150 because pressure is applied thereto.

In this state, when raw water flows into the discharge pipe 105, the raw water passes through the diatomaceous earth layer 50, which is an auxiliary agent, and at this time, fine contaminants are also removed from the diatomaceous earth layer 50, so when only the spring filter 150 is used. If a more diatomite layer 50 is used, even finer contaminants can be removed.

The water that has passed through the spring filter 150 is collected in the discharge cylinder 105 and discharged through the discharge pipe 11.

On the other hand, if filtration of water continues for a while, contaminants will fill the spring filter (150) and the filtration performance will deteriorate. Therefore, at this time, stop the pump and clean the spring filter (150).

That is, with the raw water supply blocked, water is pumped through the discharge pipe 11 with a pump (not shown) in the opposite direction to the raw water supply and supplied to the discharge pipe 105, and from the discharge pipe 105 to the filtration cylinder 101. By moving the water, water is spouted from the inside to the outside of the spring filter (150). In this process, foreign substances fall off along with the diatomaceous earth layer (180) attached to the spring filter (150). Washing water is discharged to the outside through a separate discharge pipe (not shown).

When cleaning of the spring filter 150 is completed, the diatomaceous earth layer 180 is formed and then raw water is supplied again to perform filtration.

Meanwhile, in the present invention, the pressure sensor 106 measures the internal pressure of the filter tube 101, and when the pressure exceeds a certain level, the pressure sensor 106 automatically performs the above-described procedure by a control unit (not shown). Likewise, the spring filter 150 can be cleaned.

In the present invention, by having the above-described configuration, there is an advantage that maintenance costs are reduced by not replacing the filter and that it can be used semi-permanently.

Meanwhile, Figures 8 and 9 show another example of the spring filter 150. In Figure 8, an additional spiral spring 170 is provided between the central plate 151 and the inside of the spiral spring 152. ) is placed.

The additional spring 170 is disposed inside the helical spring 152 and is made of a steel wire wound continuously in a helical shape. The additional spring 170 is spaced at regular intervals in the same manner as the helical spring 152. Protrusions 170a are formed. That is, the protrusion 170a is formed integrally with the upper part of the spiral-shaped additional spring 170, protrudes upward, and has a height of about 10㎛-100㎛ in this embodiment. Accordingly, the upper spring 170 is seated on the upper surface of the protrusion 170a, like the spiral spring 152 shown in FIG. 5. In this embodiment, the additional spring 170 is made of a steel wire made of stainless steel that is resistant to corrosion, but it is not necessarily limited to this and other materials that are resistant to corrosion may be used.

However, the additional spring 170 is formed in a direction opposite to that of the spiral spring 152 in which the spiral is wound. That is, when the spiral spring 152 is formed by being wound clockwise, the additional spring 170 is formed by being wound counterclockwise. Additionally, when the spiral spring 152 is formed by being wound counterclockwise, the additional spring 170 is formed by being wound clockwise.

In this way, the additional spring 170 is formed in a direction opposite to that of the helical spring 152, and as a result, the lower helical spring 152 and the upper helical spring 152 are formed in the helical spring 152. The gap between the spring 152 portion and the gap between the lower spring 170 and upper spring 170 portions of the additional spring 170 intersect to filter out finer foreign substances, improving filtration performance, The helical spring 152 and the additional spring 170 support each other to prevent the springs 152 and 170 from being deformed over time.

Above, the present invention has been described with reference to preferred embodiments, but the present invention is not limited thereto, and various modifications may be made by those skilled in the art without departing from the gist of the present invention as set forth in the claims below. There will be.

101: Filter cylinder 105: Discharge cylinder
102: bottom plate 104: top plate
103: middle plate 103a: through hole
10: water supply pipe 11: discharge pipe
150: spring filter

Claims (12)

A filter cylinder body (101) connected to the lower part with a water supply pipe (10) and having side walls formed in the circumferential direction to form a space for receiving water supplied inside through the water supply pipe (10);
A middle plate 103 that is coupled to the upper part of the filter body 101 and has a through hole 103a penetrating upward and downward, so that the water contained in the filter body 101 moves upward through the through hole 103a. and,
A discharge cylinder 105 coupled to the upper part of the intermediate plate 103,
It includes a spiral spring 152 formed by continuously winding a steel wire with projections 152a formed on the upper portion at regular intervals in a spiral shape, and the upper spring 152 is seated on the projections 152a, A water purifying device comprising a spring filter (150) coupled to the intermediate plate (103) inside the filtering tube (101). According to paragraph 1,
The spring filter 150 includes a central plate 151 extending vertically in the center,
A bottom portion 154a coupled to the lower end of the center plate 151 to support the lower end of the spiral spring 152, and a side portion formed to protrude from the edge of the bottom portion 154a in the circumferential direction ( A lower support member 154 including 154b),
It is coupled to the upper part of the central plate 151 and further comprises an upper fixing member 153 coupled to the through hole of the intermediate plate to fix the spring filter 150 to the intermediate plate 103. A water purification device that uses According to paragraph 1,
The central plate (151) is a water purifying device characterized in that the plane of the plate rotates along the vertical and longitudinal directions, so that the side surface of the central plate (151) has a spiral shape along the longitudinal direction. According to paragraph 2,
Between the spiral spring 152 and the central plate 151, there is an upper bent portion 160a made of a single steel wire that extends upward and is bent downward, and an upper bent portion 160a that extends downward from the upper bent portion 160a and is bent upwardly. A water purification device characterized in that the lower bent portions (160b) are alternately formed and further include a bent extension member (160) formed along the circumferential direction on the inner peripheral surface of the spiral-shaped spring (152). According to paragraph 4,
Another spiral-shaped spring 152' is disposed between the bent extension member 160 and the central plate 151, and is formed by continuously winding a steel wire with protrusions 152a at regular intervals in a spiral shape. A water purification device characterized in that the upper spring (152') is seated on the protrusion (152a) of another spiral-shaped spring (152'). According to paragraph 2,
An additional spring 170 is disposed between the spiral spring 152 and the central plate 151, and is formed by continuously winding a steel wire with protrusions 170a at regular intervals in a spiral shape. ) is formed by seating the upper spring 170 on the protrusion 170a, and the additional spring 170 is formed in a direction opposite to that of the spiral spring 152. . According to clause 6,
A water purifying device, characterized in that the gap of the additional spring (170) intersects the gap of the spiral spring (152). According to paragraph 1,
It further includes a pressure sensor 106 that measures the pressure inside the filter tube 101,
When the internal pressure of the filter tube 101 measured by the pressure sensor 106 is higher than a preset certain pressure, the control unit supplies water through the discharge pipe 11 coupled to the discharge tube 105 by a pump. A water purification device characterized in that it removes foreign substances attached to the spring filter (150) while moving water from the discharge cylinder (105) to the filtering cylinder (101). According to paragraph 2,
A male screw portion is formed on the outer peripheral surface of the upper fixing member 153, and the male screw portion of the upper fixing member 153 is screwed to a female screw formed in the through hole 103a of the intermediate plate 103. Water purification device. According to paragraph 2,
A lower extension portion 153a is formed at the lower part of the upper fixing member 153, extending downward from the upper end of the helical spring 152 and covering the upper part of the helical spring 152 in the circumferential direction. Characterized by a water purification device. According to paragraph 1,
The filter body 101 further includes a bottom plate 102 in which the lower end of the side wall is coupled and a coupling hole in the center is formed in which the water supply pipe 10 is coupled,
The discharge cylinder 105 includes an upper plate 104 to which the discharge pipe 11 is coupled, and a side wall formed along the circumference to form an internal space by being coupled to the lower part of the upper plate 104. Characterized by a water purification device. According to paragraph 1,
The spring filter 150 is a water purification device in which a diatomaceous earth layer 180 is formed on the outside of the spiral spring 152.

Images