KR101193206B1 - Stainless Disk Filter - Google Patents

Abstract

SUMMARY OF THE INVENTION An object of the present invention is to provide a stainless disk filter which can be used semi-permanently while being capable of high-capacity treatment and automatic / continuous operation in a filter that can be used in a pretreatment filtration process.
The stainless disk filter of the present invention, in the filter used in the pre-treatment filtration process, an empty space is formed inside to accommodate the fluid, and the lower housing 11a is formed with a lower outlet port 11a through which raw water flows in or wash water is discharged to one side. 10a and a housing 10 in which an empty space is formed inside to accommodate the fluid and an upper housing 10b on which one side is formed an upper outlet 11b through which washing water is introduced or discharged filtration water; A stainless disk stack 20 which is accommodated in the lower housing 10a and is formed by stacking a plurality of stainless disks 21 having a scratch S on a surface thereof; Interposed between the lower housing (10a) and the upper housing (10b) is fixedly disposed on the upper end of the stainless steel disk stack (20) to securely support the upper end of the stainless steel disk stack (20), the raw water in the center Alternatively, the stainless steel disk stack 20 may be disposed to be movable up and down at a lower end of the stainless disk stack 20, and a fixed plate 31 having a through-flow guide channel 12 formed therein so as to guide the flow direction of the washing water. Comprising a compression plate 32 for supporting the lower end of the compression means for moving the compression plate 32 up and down to perform compression or decompression of the stainless disk stack 20, 30; In the filtration process, the compression plate 30 is moved upward by the compression means 30, the stainless disk stack 20 is compressed and the scratch formed on the stainless disk 21 ( S) forms pores, and the raw water flows into the lower outlet port 11a and passes through the compressed stainless disk stack 20, and the foreign matter is filtered by the pores to the upper outlet port 11b. In the backwashing process, the compression plate 32 is moved downward by the compression means 30 to decompress the stainless disc stack 20, and wash water to the upper outlet 11b. Is introduced and passed through the decompressed stainless steel disk stack 20, the foreign matter loaded during the filtration process is washed and discharged to the lower outlet (11a), the stainless disk 21 In upper or lower direction of a predetermined angle (α) it characterized in that the bending is formed.

Description

Stainless Disk Filter {Stainless Disk Filter}

The present invention relates to a stainless steel disc filter which can be used semi-permanently while being capable of high-capacity treatment and automatic / continuous operation in a filter that can be used in a pretreatment filtration process.

Water is widely used for various purposes in general living environment or industrial sites. Accordingly, the application range of water purification technology is expanding. In particular, in the treatment of domestic purified water, sewage, medicine, semiconductor water, cooling water and the like, a rapid filtration treatment method for promoting water pressure difference is widely used.

In general, water purifiers use a pretreatment filter to remove relatively large foreign substances, such as rust residues from the tube, and then use a carbon filter using activated carbon adsorption, a reverse osmosis membrane filter, a hollow fiber membrane filter, or a sterile ceramic filter. In order to ensure that drinking is suitable, minerals are preserved as much as possible, but water purification is carried out through the process of filtering bacteria or heavy metals that adversely affect health. Alternatively, in the case of water used for washing the product at an industrial site, if the washing water is contaminated, foreign substances in the water are also removed by using a pretreatment filter to prevent recontamination of the product during the washing process. After that, it is used as it is, or filtered through another filter to make it suitable for washing water.

As described above, there are various filtration processes in the purified water and various types of filters used according to the purpose, but in any case, a pre-treatment filter that filters out foreign matters is required. Of course, the above description has been made with an example of purified water, but in the case of filtering various fluids such as oil, chemicals, steam, etc., a pretreatment filter for removing foreign substances as described above is required.

As mentioned above, pretreatment filters to remove foreign matter in the fluid are most needed in any filtration process (including water purification). In general, as a material of the pretreatment filter, a material made of porous material is used so that particles of a predetermined size or more can be filtered out and the fluid can escape. For example, a nonwoven fabric, a ceramic, or the like is used.

It is well known that foreign matters removed in the process of removing foreign matters eventually accumulate in the pretreatment filter, and thus the pretreatment filter is degraded as it is used longer. Accordingly, in most devices, the pretreatment filter is replaced every predetermined period. However, since the pretreatment filter has to be frequently replaced in this manner, a waste of time, manpower, and cost has arisen. In more detail, in the case of the conventional pretreatment filter as described above, since a material such as a nonwoven fabric is used, it is difficult to regenerate the filter by removing such foreign matter from the filter after the foreign matter accumulates inside the filter. Therefore, there was a problem in that the pretreatment filter itself had to be continuously replaced with a new one.

Therefore, the present invention has been made to solve the problems of the prior art as described above, the object of the present invention is a filter that can be used in the pre-treatment filtration process, a large-capacity processing and automatic / continuous operation, while semi-permanent use This is in providing a possible stainless steel disc filter.

Stainless steel disk filter of the present invention for achieving the object as described above, in the filter used in the pre-treatment filtration process, an empty space is formed inside to accommodate the fluid and the lower side flow in which raw water flows in or wash water is discharged to one side. The lower housing 10a in which the sphere 11a is formed, and the upper housing 10b in which an empty space is formed to accommodate the fluid, and the upper distribution port 11b in which washing water flows in or discharges filtration water are formed on one side thereof. Stacked housings 10; A stainless disk stack 20 which is accommodated in the lower housing 10a and is formed by stacking a plurality of stainless disks 21 having a scratch S on a surface thereof; Interposed between the lower housing (10a) and the upper housing (10b) is fixedly disposed on the upper end of the stainless steel disk stack (20) to securely support the upper end of the stainless steel disk stack (20), the raw water in the center Alternatively, the stainless steel disk stack 20 may be disposed to be movable up and down at a lower end of the stainless disk stack 20, and a fixed plate 31 having a through-flow guide channel 12 formed therein so as to guide the flow direction of the washing water. Comprising a compression plate 32 for supporting the lower end of the compression means for moving the compression plate 32 up and down to perform compression or decompression of the stainless disk stack 20, 30; In the filtration process, the compression plate 30 is moved upward by the compression means 30, the stainless disk stack 20 is compressed and the scratch formed on the stainless disk 21 ( S) forms pores, and the raw water flows into the lower outlet port 11a and passes through the compressed stainless disk stack 20, and the foreign matter is filtered by the pores to the upper outlet port 11b. In the backwashing process, the compression plate 32 is moved downward by the compression means 30 to decompress the stainless disc stack 20, and wash water to the upper outlet 11b. Is introduced and passed through the decompressed stainless steel disk stack 20, the foreign matter loaded during the filtration process is washed and discharged to the lower outlet (11a), the stainless disk 21 In upper or lower direction of a predetermined angle (α) it characterized in that the bending is formed.

At this time, the stainless disk 21 is characterized in that the predetermined angle (α) is formed to have a value within the range of 1 ° to 20 °.

In addition, the stainless disk stack 20 is characterized in that the stainless disk 21 bent upward and the stainless disk 21 bent downward are alternately arranged.

In addition, the stainless disk 21 is characterized in that the heat treatment is performed after bending.

In addition, the stainless disk 21 is characterized in that the scratch (S) is formed to have a depth within the range of 1㎛ 100㎛.

In addition, the stainless steel disc 21 is scratched using a computer router on the surface, a roll mold press processing, a chemical polishing process, or a grinding process to perform a scratch (S) to be formed It features.

In addition, the stainless disk laminate 20 is formed by alternately stacking at least two or more kinds of stainless steel disks 21a and 21b each having different areas and scratches S having different depths formed on respective surfaces thereof. It is characterized by.

Alternatively, the stainless disk stack 20 may have an inner stainless disk 21a and a larger area than the inner stainless disk 21a, and may have a different depth from the scratch S formed on the surface of the inner stainless disk 21a. It is characterized in that the external stainless steel disc 21b on which the scratches S are formed are alternately stacked with each other. In this case, the inner stainless disk 21a and the outer stainless disk 21b are formed integrally with each other.

In addition, both ends of the stainless steel disc filter are vertically fixed to the bottom of the fixing plate 31 and the lower housing 10a, respectively, and are formed through the compression plate 32 and the stainless steel disc 21, and thus, the stainless steel disc. At least one support rod (22) for preventing deviation of the position of the stainless disk (21) when the laminate (20) is compressed or decompressed; Characterized in that further comprises.

According to the present invention, in the filter that can be used in the pre-treatment filtration process, there is a big advantage that it is possible to use a large-volume treatment and automatic / continuous operation, but also semi-permanent use. More specifically, in the present invention, the filtration is performed by the flow of the fluid in the forward direction in the compressed state of the stainless steel disk laminate, on the contrary, when the fluid flows in the reverse direction, the compression of the laminate is released, so that the gaps between the stainless steel disks are naturally opened. As backwashing is performed, it is possible to easily regenerate through backwashing simply by changing the direction of the fluid flow, so unlike the conventional pretreatment filter, there is no need for replacement. There is a big effect to save the waste of money.

In addition, the pretreatment filter of the present invention can be used not only for water purification, but also for high filtration of fluids having different properties from water such as high temperature fluids, chemicals, steam, oils, etc. There is a big advantage to being compatible.

1 is a perspective view of a stainless disk filter of the present invention.
2 and 3 are cross-sectional views of the stainless steel disc filter of the present invention.
4 is a detailed view of the stainless disk of the present invention.

Hereinafter, a stainless disk filter according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a stainless steel disc filter of the present invention, and FIGS. 2 and 3 are cross-sectional views of the stainless steel disc filter of the present invention. As shown, the stainless steel disc filter of the present invention is a filter used in the pretreatment filtration process, and includes a housing 10 composed of a lower housing 10a and an upper housing 10b, a stainless disk stack 20, It comprises a compression means (30). Hereinafter, each part will be described in more detail.

The housing 10 is composed of a lower housing 10a and an upper housing 10b as shown, and they are formed in a stacked form with each other. At this time, the lower housing (10a), the empty space is formed inside to accommodate the fluid, the raw water flows in one side (in the filtration process) or the wash water is discharged (in the back washing process) 11a) is formed. In addition, the upper housing (10b), like the lower housing (10a) is formed in the form of an empty space therein to accommodate the fluid, and also wash water flows into one side (in the backwashing process) is filtered water is discharged ( At the time of the filtration process, the upper flow opening 11b is formed.

The stainless steel disk stack 20 is accommodated in the housing 10 so that foreign matter is filtered while raw water passes through the stainless steel disk stack 20. As shown in the figure, the stainless disk stack 20 is formed by stacking a plurality of stainless disks 21 having a scratch S on a surface thereof. At this time, in the present invention, in particular, the stainless disk 21 is characterized by being formed by bending a predetermined angle (α) in the upper or lower direction. Figure 4 shows a more detailed view of the stainless steel disk of the present invention, in Figure 4 (A) is shown a form in which the stainless disk 21 is bent. At this time, it is preferable that the predetermined angle α is formed to have a value within the range of 1 ° to 20 °. In addition, the stainless disk stack 20 is preferably formed by alternating the stainless disk 21 bent upward and the stainless disk 21 bent downward. In this case, the stainless disk 21 is heat-treated after bending, so that the stainless disk 21 can be easily restored to its original state (ie, bent form) when compressed and decompressed. The scratch S of the stainless disk 21 will be described in more detail later.

The compression means 30 includes a fixed plate 31 and a compression plate 32 to move the compression plate 32 up and down to compress or decompress the stainless disk stack 20. Hereinafter, the respective parts will be described in detail.

The fixing plate 31 is interposed between the lower housing 10a and the upper housing 10b to distinguish a fluid contained in the lower housing 10a from a fluid contained in the upper housing 10b. . More specifically, during the filtration process, the raw water before filtration is accommodated in the lower housing 10a, and the filtered water after filtration is accommodated in the upper housing 10b, by the fixing plate 31. Since the lower housing 10a and the upper housing 10b are isolated, the two fluids do not mix with each other. In this case, a guide passage 12 having a through shape is formed at the center of the fixed plate 31 so as to guide the flow direction of the raw water or the washing water. Thus, the stainless disk laminate 20 accommodated in the lower housing 10a is formed. By passing through the filtration process is completed can be introduced into the upper housing (10b) through the guide passage (12). In addition, structurally, the fixing plate 31 is fixedly disposed on the upper end of the stainless steel disc stack 20 as shown in order to fix and support the upper end of the stainless steel disc stack 20.

The compression plate 32 is disposed on the lower end of the stainless disk stack 20 so as to be movable up and down to support the lower end of the stainless disk stack 20. As described above, the compression means 30 raises the compression plate 32 to compress the stainless disk stack 20, or lower the compression plate 32 to lower the stainless disk stack 20. Causes decompression. At this time, in order to achieve the operation of raising and lowering the compression plate 32 in this way, as shown in the compression plate 32 may be provided with a drive unit, or the compression by a hydraulic pressure without a special drive unit The plate 32 may be naturally raised or lowered, or elastically provided between the compression plate 32 and the inner bottom surface of the housing 10 to facilitate the rising of the compression plate 32. It may be provided with an additional configuration, such as any configuration including a well-known configuration if only the lifting and lowering operation of the compression plate 32 may be provided.

In addition, the stainless disk filter may further comprise a support rod 22 as shown. Both ends of the support bar 22 are vertically fixed to the bottom of the fixing plate 31 and the lower housing 10a, respectively, and are formed through the compression plate 32 and the stainless steel disc 21 to stack the stainless disc. When the sieve 20 is compressed or decompressed, the stainless disk 21 serves to prevent positional deviation.

In the stainless steel disc filter of the present invention, the flow of water is reversed during the filtration process and the backwash process, and at this time, the stainless steel disc stack 20 is compressed or decompressed in each process, thereby filtration or backwashing. This will happen. This will be described in more detail as follows.

First, in the filtration process, as shown in FIG. 2, the compression plate 32 is moved upward by the compression means 30. Accordingly, the stainless disk stack 20 is compressed so that the scratches S formed on the stainless disk 21 form pores. Therefore, the raw water flows into the lower outlet 11a, and the raw water is filled in the lower housing 10a, and the raw water passes through the compressed stainless disk stack 20 and foreign matter is filtered by the pores. . The filtered water is moved to the upper housing 10a through the guide passage 12 to be filled in the upper housing 10a, and finally discharged to the upper outlet 11b.

Next, during the backwashing process, as shown in FIG. 3, the compression plate 30 is moved downward by the compression means 30 to decompress the stainless disc stack 20. As described above, each of the stainless disks 21 is formed to be bent upwards or downwards, and preferably, the stainless disks 21 are bent downwardly with the stainless disks 21 in which the stainless disk stack 20 is bent upwards. The stainless disk 21 is arranged alternately with each other, and when the compression of the stainless disk stack 20 is released, it is shown in Figure 3 in the process of restoring to the original shape as the pressing force is removed from the outside As described above, the stainless disks 21 are separated from each other. In this way, the washing water flows into the upper flow opening 11b in a state where the stainless disks 21 are largely separated, and passes through the stainless disk stack 20 which is decompressed through the guide flow passage 12. When the filtration process, the foreign matter loaded on the surface of the stainless steel disc 21 is washed to be discharged to the lower outlet 11a.

Here, the direction in which water flows into or out of the lower flow port 11a formed in the lower housing 10a and the upper flow port 11b formed in the upper housing 10b is the lower flow. By connecting the valve to the flow path connected to the sphere (11a) and the upper flow port (11b) it can be easily set by changing the inflow or discharge direction. Alternatively, the lower distribution port 11a and the upper distribution port 11b may be made of a pair of separate inlets and outlets each of which only inflows or discharges are formed.

Figure 4 illustrates in more detail the stainless steel disc of the present invention. As shown, the stainless steel disc 21 has a scratch (S), if the depth of the scratch (S) is formed so small that the pore size during compression of the stainless disk stack 20 is not large enough water is It does not overcome surface tension and cannot flow through pores. Table 1 below shows the experimental results when a disk without scratches (S) was used. As shown in the experimental results of Table 1, it is impossible to use as a filter unless scratches S are formed in the stainless disk 21. In addition, when decompressing the stainless steel disk stack 20, when the disk without scratches S is used, the disks do not stick to each other due to the water film formed between the disks, so that the disks do not spread between the disks. The phenomenon that the laminate itself fell as it appeared.

Number of disks Driving pressure Raw water flow rate Filtrate Flow Filter value 100 pieces 0.6 MPa or more 3 tons / hr Almost none none

On the contrary, if the depth of the scratch (S) is too large, the water is smoothly made, but foreign matter is easily escaped through the pores, so that the filtration effect is not obtained. Therefore, the depth of the scratch (S) should be formed to be adjusted appropriately. In the present invention, the scratch (S) in the stainless disk 21 is to be formed to have a depth within the range of 1㎛ to 100㎛. Thus, when the scratch (S) depth is formed, the experimental results are as shown in Table 2 below.

Number of disks Driving pressure Raw water flow rate Filtrate Flow Filter value 100 pieces 0.1 MPa or more 3 tons / hr 2.5 tons / hr good

From the experimental results of Table 2, it can be seen that when the scratch S is formed on the stainless steel disc 21 as described above, the filtered water comes out to about 2.5 tons, and the filtration effect is also sufficient to be suitable for use as a filter. Can be. In addition, in the present invention, since the stainless disk 21 is formed in a form bent upward or downward, when the compression is dismantled, a force to restore the stainless disk 21 to its original shape acts (scratch S Since the effect of forming a water film is eliminated by), the adverse effect of the force to which the stainless steel discs 21 are attached to each other is also eliminated). The gap between the stainless steel discs 21 naturally opens, so that backwashing can be easily performed. Will be.

At this time, the stainless disk 21 is to be scratched by using a computer router on the surface, a roll mold press processing, a chemical polishing process, or a grinding process to perform a scratch (S) to be formed Can be. Of course, even if the method is not mentioned here, the scratch (S) may be formed in any manner as long as it can be applied to the disk for the pretreatment filter of the present invention as described above.

At this time, the stainless steel disk stack 20 is formed of different areas and at least two or more stainless steel disks 21a and 21b having scratches S having different depths formed on respective surfaces are alternately stacked. It is preferable to make.

More specifically, the stainless disk stack 20 is formed with an inner stainless disk 21a and a larger area than the inner stainless disk 21a, as shown in Fig. 4B. It is preferable that the scratches S formed on the surface of the stainless disk 21a and the outer stainless disk 21b on which the scratches S of different depths are formed alternately stacked. In this way, by being divided into the inner stainless disk 21a and the outer stainless disk 21b, there is an advantage that the water flow more smoothly. At this time, as shown in Fig. 4C, the inner stainless disk 21a and the outer stainless disk 21b may be integrally formed with each other.

As shown in FIGS. 4B and 4C, discs having two different areas and scratches of different depths may be stacked to form the stainless disc stack 20. Alternatively, the stainless disk stack 20 may be formed by stacking disks having scratches S having three or more different areas and different depths.

As described above, the stainless steel disc filter of the present invention is formed by stacking stainless steel discs 21 formed in a bent form with a scratch S on the surface thereof, and compressing the stainless steel disc stack 20 in a compressed state (that is, scratches ( Filtration is performed by passing raw water in the state in which pores are formed by S), and conversely, in the state in which the stainless disc stack 20 is decompressed (that is, the stainless discs 21 are separated from each other by a bending shape). In this open state, the washing water is passed in the opposite direction to perform the washing. As such, foreign matters caught on the scratch S portion of the stainless steel disc 21 naturally fall off when the stainless steel discs 21 are separated, and thus, the washing is very easy. Unlike the pretreatment filter, it can be used semi-permanently without replacement.

Although the operation of the stainless steel disc filter of the present invention has been described above on the basis of an integer, of course, the stainless steel disc filter of the present invention has no structure even in the filtration of fluids having different properties from water such as high temperature fluids, chemicals, steam, oils, and the like. Can be used immediately without change. Extremely, the stainless steel disc filter of the present invention can be used for filtration of chemicals as long as it is used for water purification, or just cleansed. There is a big advantage.

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. It goes without saying that various modifications can be made.

10: housing
10a: lower housing 11a: lower outlet
10b: upper housing 11b: upper outlet
12: Euro guide
20: stainless steel disc laminate
21: stainless steel disc 22: support rod
30: compression means
31: fixed plate 32: compressed plate

Claims (10)

In the filter used for the pretreatment filtration process,
An empty space is formed therein to accommodate the fluid, and a lower housing 10a in which a lower flow opening 11a through which raw water is introduced or discharged to the discharge water is formed, and an empty space is formed inside to accommodate the fluid. A housing 10 formed by stacking an upper housing 10b on which an upper distribution port 11b through which washing water is introduced or discharged is formed;
A stainless disk stack 20 which is accommodated in the lower housing 10a and is formed by stacking a plurality of stainless disks 21 having a scratch S on a surface thereof;
Interposed between the lower housing (10a) and the upper housing (10b) is fixedly disposed on the upper end of the stainless steel disk stack (20) to securely support the upper end of the stainless steel disk stack (20), the raw water in the center Alternatively, the stainless steel disk stack 20 may be disposed to be movable up and down at a lower end of the stainless disk stack 20, and a fixed plate 31 having a through-flow guide channel 12 formed therein so as to guide the flow direction of the washing water. Comprising a compression plate 32 for supporting the lower end of the compression means for moving the compression plate 32 up and down to perform compression or decompression of the stainless disk stack 20, 30; , ≪ / RTI >
During the filtration process, the compression plate 32 is moved upward by the compression means 30 to compress the stainless steel disc stack 20 so that the scratches S formed on the stainless steel disc 21 form pores. And, while the raw water flows into the lower flow port (11a) while passing through the compressed stainless disk stack 20, the foreign matter is filtered by the pores and then discharged to the upper flow port (11b),
During the backwashing process, the compression plate 32 is moved downward by the compression means 30, thereby decompressing the stainless steel disc stack 20, and washing water flows into the upper outlet 11b. While passing through the decompressed stainless steel disk laminate 20, foreign matters loaded during the filtration process are washed and discharged to the lower outlet 11a,
The stainless disk (21) is a stainless disk filter, characterized in that formed by bending a predetermined angle (α) in the upper or lower direction.
The method of claim 1, wherein the stainless steel disc 21
Stainless steel disc filter, characterized in that the predetermined angle (α) is formed to have a value within the range of 1 ° to 20 °.
The method of claim 1, wherein the stainless steel disc stack 20
Stainless steel disk filter, characterized in that the stainless disk (21) bent upwardly and the stainless disk (21) bent downwardly are alternately arranged.
The method of claim 1, wherein the stainless steel disc 21
Stainless steel disc filter, characterized in that the heat treatment is performed after bending.
The method of claim 1, wherein the stainless steel disc 21
Stainless steel disc filter, characterized in that the scratch (S) is formed to have a depth within the range of 1㎛ 100㎛.
The method of claim 1, wherein the stainless steel disc 21
The stainless disk filter, characterized in that the scratch (S) is formed on the surface by performing a scratch processing using a computer router, a roll mold press processing, a chemical polishing process, or a grinding process.
The method of claim 1, wherein the stainless steel disc stack 20
Stainless steel disc filter, characterized in that the at least two or more kinds of stainless steel discs (21a) (21b) formed of different areas and scratches (S) of different depths are formed on each surface.
The method of claim 1, wherein the stainless steel disc stack 20
The outer stainless disk 21a is formed with an area larger than the inner stainless disk 21a, and the outer stainless disk 21 is formed with a scratch S having a depth different from that of the scratch S formed on the surface of the inner stainless disk 21a. A stainless disk filter, characterized in that 21b is alternately laminated with each other.
9. The inner stainless disk 21a and the outer stainless disk 21b are
Stainless steel disc filter, characterized in that formed integrally with each other.
The method of claim 1, wherein the stainless steel disc filter
Both ends are vertically fixed to the bottom of the fixing plate 31 and the lower housing 10a, respectively, and are formed through the compression plate 32 and the stainless steel disc 21 to compress the stainless steel disc stack 20 or At least one support rod (22) to prevent the positional deviation of the stainless disk (21) when decompression;
Stainless steel disk filter, characterized in that further comprises.

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