KR100274759B1 - Microfiltration method and system using textile hose - Google Patents

Abstract

PURPOSE: Provided are a microfiltration method using a hose-shaped flexible membrane made of minutely woven fabric for enhancing the efficiency of microfiltration or backwash and a microfilter thereof. CONSTITUTION: The microfilter comprises: i) a support plate being fixed in a body in the form of a tank or cover and separating a feed water part from a filtered water part; ii) flexible fabric hoses(300) installed at regular intervals on the support plate; and iii) tube-type spacers(400) having inside diameters being far smaller than those of the hoses(300) and being formed with a plurality of holes(401). In a filtration process, feed water is flowed through the spacer by a fluid pressure outside the hose or a sucking force inside the hose, so that a path for flowing an internal fluid can be formed even if the hose is contracted and then attached to the outer circumstance of the spacer. In a backwash process, the hose is expanded by an internal fluid such as backwash water or air flowed into the hose and then restored to a cylinder shape, so that filtered material on the outer circumstance of the hose is fallen off. In addition, the internal fluid is discharged through pores, therefore the filtered material is secondly separated.

Description

Precision filtration method using fiber hose and its device

The present invention relates to a microfiltration method and apparatus using a fiber hose that facilitates microfiltration and cleaning by using a hose-type membrane to precisely weave the fiber yarn to have flexibility.

Existing precision filtration device has a filter module by rolling several layers of precision filter made of cartridge type using thread, filtration membrane, filtration cloth, sintered metal, and polymer material, precision filter made of hollow fiber membrane, and filtration membrane. Many kinds of precision filters are used, such as the configured filter and the precision filter using ceramics.

Such a conventional filter is most often replaced with a one-time use; Backwashing, washing and reusing are largely classified.

By the way, the conventional filtration module is the most common type of fixed inflexibility, especially made of ceramic or metal mesh, but in the case of filtration and backwashing, both maintain the same form fixed, so that the shape of the filtration membrane is not deformed Very low efficiency

In addition, even when using a flexible filtration membrane is attached to the body having a certain shape to form a filter, so that the precision filter configured as this causes a waste of resources when discarded after a single use and becomes a source of environmental pollution as waste. In addition, backwashing and reusing the precision filter is difficult to backwashing and cleaning because it is not efficient, and the microfiltration device made of ceramic or polymer material is very expensive and difficult to use.

The present invention can be reused after backwashing using a hose-type precision filtration membrane woven by a flexible fiber yarn, the backwashing method is simple, high backwashing efficiency, and using a fiber hose that can maintain a low maintenance cost The purpose is to provide a microfiltration method and apparatus.

1 is a cross-sectional view of an embodiment of a filtration device of the present invention.

(a) is cross sectional view and (b) is A-A 'cross sectional view.

Figure 2 shows the operating state of the main part of the present invention

(a) is a filtration principle diagram showing the filtration state of treated water.

(b) is a backwash principle diagram showing the backwashing process of the filtration hose.

Figure 3 is an operating state diagram of one embodiment of the present invention.

4 is a cross-sectional view of another embodiment of the present invention.

5 is an operational state diagram of another embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

100: filtration tank body 101: fluid inlet

102: backwash outlet 103: treatment export outlet

104: VENT 110: Cover body

111: treated water outlet 120: treated water part

130: supply water 200: filtration hose support plate

300: filtration hose 400: spacer

401: through hole 500: fluid storage tank

600: suction pump 700: supply pump

In order to achieve the above object, in the present invention, a fibrous yarn having flexibility is precisely woven into a hose shape, and the tubular spacer is formed by inserting and configuring a tubular spacer having a plurality of holes, which is much smaller than the inner diameter of the hose, and is filtered. In the process, the suction of the filtration fiber hose is caused by the fluid pressure outside the hose or the fluid suction force inside the hose, so that a passage through which the fluid can flow even if the filtration fiber hose is contracted and attached to the outer surface of the porous spacer is secured. In the backwashing process, the back fluid is expanded by a fluid such as filtration water or air introduced into the filtration fiber hose and restored to a cylindrical shape so that the substance attached to the outer surface of the filtration fiber hose falls and at the same time the internal fluid Secondary to the surface as it exits through the air gap And the material is characterized in that so as to tally.

One embodiment of the present invention is such that the upper portion of the filter fiber hose and the hose inside the hose fixedly attached to the mounting hole of the support plate and then mounted inside the tank body, by the support plate of the upper portion of the treated water and It is divided into supply water part.

The filtration tank body is composed of a fluid inlet and treated water outlet, backwash outlet, vent portion.

The supply fluid is supplied to the supply water inside the body by a pump through the lower fluid inlet, is filtered at the surface of the filtration hose, collected through the filter hose support plate through the spacer to the treated water part, and discharged again through the treated water outlet. .

On the other hand, in backwashing, when water or air is supplied through the outlet of the treated water, fluid is supplied through the spacer to flow into the filtration hose, and the filtration hose contracted by filtration is expanded to attach to the surface of the filtration hose. By allowing the filtered suspended solids to be detached, the suspended solids in the supply fluid can be effectively filtered and backwashed easily.

In another embodiment of the present invention, the treatment outlet is formed in the upper center and the cover-shaped body without the lower body and the upper portion is attached to the cover body by the support plate fixed to the cover body and the filter hose in the state exposed to the lower side A plurality of filtering members composed of spacers inserted into the filter module are installed at regular intervals, and the filtering device is sucked and filtered by a suction pump connected to the treatment outlet of the cover body in a state of being submerged in the fluid. It is characterized in that the filtration hose that has been contracted by the introduced fluid is expanded to easily detach the filtered suspended matter.

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

1 is a cross-sectional view showing an embodiment of the filtration device of the present invention, the filtration tank body 100 has an inner space of the upper portion of the treated water 120 and the lower supply water 130 by the support plate 200, respectively. A vent 104 and a treatment outlet 103 are installed in the upper portion of the treated water space, and a fluid inlet 101 and a backwash outlet 102 are respectively provided on the side and bottom of the lower portion of the supplied water space. .

A plurality of precision filtration fiber hose 300 is installed protruding into the inner lower space of the filtration tank body 100 in a plurality of mounting holes 201 formed at a predetermined interval on the support plate 200, the inner side of the fiber hose 300 It has an outer diameter smaller than the inner diameter of the fiber hose 300, the tubular spacer 400 is a plurality of through holes 401 perforated is installed.

The fiber hose 300 is configured to seal the bottom portion as a fiber shape having excellent flexibility.

The porous tube spacer 400 installed inside the fiber hose 300 has a diameter smaller than that of the microfiltration fiber hose 300, so that the filtration fiber hose 300 is contracted during the filtration process so that the porous tube spacer 400 is disposed therein. A fluid flow path is formed even though it is attached to 400 so as to enable filtration. During the backwashing process, the fiber hose 300 is expanded by a fluid such as filtered water or air introduced into the microfiltration hose. It is restored to a cylindrical shape to drop the filtered materials on the surface, and secondly, the inner fluid is discharged through the pores to detach the filtered materials attached to the surface.

That is, the inflowing fluid flows out through the pores of the filtration hose, thereby effectively removing the filtration suspended solids on the surface of the hose so as to increase the backwashing efficiency, thereby enabling effective filtration.

After the filtration material is coated on the surface of the microfiltration hose during the initial filtration process, the filtration material is used for fine filtration, and the desorption materials discharged during the backwashing process are partially re-supplied during the filtration process to reuse the coating material.

In the present invention as described above, when the feed water is supplied through the fluid inlet 101 at the time of passage of the treated water, the fiber weaving microfiltration hose is soft and flexible, and is contracted by the pressure of the supply fluid as shown in FIG. It is attached to a spacer mounted therein, and the suspended solids in the fluid adhere to the surface to form a filtration layer.

The treated water passing through the filtration hose 300 is collected through the plurality of through holes 401 into the spacer 400 tube and flows to the upper portion of the support plate 200, and is discharged through the treated outlet 103.

During the initial filtration, some very small suspended solids cannot be filtered by the pores of the microfiltration hose. However, after this period, very small suspended solids are effectively filtered by the layer formed by suspended solids filtered on the surface of the microfiltration hose.

Filtration by the microfiltration hose is filtered by the initial filtration hose and then by the suspended solids filtered at the surface of the filtration hose.

The filtered water passing through the filtration membrane layer is discharged to the treated water reservoir along the flow path formed by the internal spacers.

When the suspended solids are filtered while the filtration proceeds, the treatment flow rate is lowered. When the treated water or the compressed air is injected into the precision filtration hose from the upper part of the filtration tank body 100 and the pressure is applied, it contracts and becomes crushed. As shown in (b) of FIG. 2, the internal pressure causes the hose to expand in a round shape.

At this time, the suspended solids attached to the microfiltration hose are dropped and the suspended suspended solids are removed by the water or air discharged through the pores of the microfiltration hose.

The flexible and soft microfiltration hose is a new type of microfiltration device that filters in a constricted form during filtration and in the form of a round hose when backwashing, which effectively removes the adhered foreign matter.

3 is an operating state diagram of an embodiment of the present invention.

The fluid supplied by the supply pump 700 is supplied to the filtration module in the body 100, and the filtered water filtered in the fiber hose filtration module in the body is discharged to the upper treated water outlet 103.

If the filtered water is not coated enough during the initial operation, and the treated water quality is bad, close the valve B 106, open the valve A 105, and send the treated water back to the fluid storage tank 500. When the treated water is made, the valve B 106 is opened and discharged into the filtered water storage tank.

When backwashing, close the valves A and B 105 and 106, and then open the valve C 107 to supply the backwash fluid, and open the valve D 108 to send the backwashed fluid to the fluid reservoir 500 to settle. Discharge.

<Example 2>

Figure 4 shows another embodiment of the present invention as the lower structure of the body 110 is an open state so as to be filtered by immersing the filtration module directly in a separate fluid reservoir.

Treatment outlet 111 is formed in the center of the upper body 100, the upper treatment water portion 120 and the lower supply water portion 130 by a relatively wide support plate 200 formed with a mounting hole 201 at regular intervals. The installation port 201 is installed in a plurality of filtration hoses 300 and the space 400 at predetermined intervals.

The filtration hose 300 has a flexibility that the lower end is blocked, the inside of the filtration hose 300 is a plurality of through holes 401 perforated and the tubular spacer 400 having an outer diameter smaller than the inner diameter of the filtration hose is Insert is installed.

5 is a view showing the operating state of the present invention so that the filtration device is immersed in the fluid storage tank 500 to be operated by the suction pump 600 connected to the treatment outlet 111 is the inside of the fluid storage tank 500 It is to simplify the configuration of the present invention by allowing the feed water to be filtered by the filtration device of the present invention.

In another embodiment of the present invention in the case of filtration when the filtration hose 300 as shown in Figure 2 (a) has a flexible form of shrinkage, backwashing is expanded and rounded as shown in Figure 2 (b) It is a new precision filtration device that is formed in the form of a hose to detach the foreign matter attached to the outer surface of the filtration filter 300 is completely different from the existing device.

In addition, the backwashing time is short, can use air or filtered water during backwashing, and the amount of filtered water or air used for backwashing is very small.

In the apparatus of the present invention, the spacer in the microfiltration hose uses a soft and flexible tube having a space through which plastic water can pass, but a soft and flexible porous tube.

The spacer is mounted inside the microfiltration hose and is not filled all over the inside of the hose, but the spacer is mounted with a space for shrinkage during filtration. That is, the porous tube uses a smaller diameter than the microfiltration hose so that the filtration hose can be shrunk during filtration.

Precision filtration hose is very convenient because it is inexpensive because weaving using fiber yarn, and the material can be easily applied according to the purpose.

And because it can be used for a long time, it is economical and the device is simple, so it is easy to operate and easy to maintain.

This invention is

first; It is a precision filtration hose woven in the form of a filtration hose by using a fiber yarn, and it is easy to handle the product due to its low price, softness and flexibility, and it is easy to manufacture, thus reducing the device cost.

second; The microfiltration hose is soft and flexible, so it is shrunk by the fluid pressure during filtration and expands when the fluid enters during backwashing, greatly improving the filtration and backwashing efficiency.

third; Existing filters use a large amount of filtered water or air at the time of backwashing, but the filter of the present invention can be effective backwashing using less than 50% of the existing product usage.

Claims (5)

In the case of the filtration process, the porous tube spacer is smaller in diameter than the microfiltration hose. During the filtration process, the filtration hose is contracted and attached to the internal porous tube spacer. Precision filtration method using a fiber hose that is expanded by a fluid, such as to restore the cylindrical form to drop the filtered material on the surface, and to remove the filtration material attached to the surface as secondary fluid is discharged through the pores. The method of claim 1, After the filtration material is coated on the surface of the fine filtration hose during the initial filtration process, the filtration material is precisely filtered and the desorption material discharged during the backwashing process is partially re-supplied during the filtration process to reuse the coating material. Precision filtration method using fiber hose. An installation hole 201 is formed to install a plurality of filtration members including the fiber hose 300 at uniform intervals, and is combined with a separate body 110 to treat the upper portion of the treated water 120 and the lower supply water. Support plate 200 to be divided into 130; A plurality of fine filtration fiber hoses 300 fixed to the mounting hole 201 of the support plate 200 and installed to protrude into the lower space, the lower side of which is woven into a fibrous yarn having flexibility as a closed pipe shape; It is inserted into the inside of the fiber hose 300, has an outer diameter smaller than the inner diameter of the fiber hose 300, the periphery of the tubular spacer 400 is a plurality of through holes 401 perforated is installed Precision filtration device using a fiber hose. The method of claim 3, wherein In the body 100 to which the support plate 200 is coupled, an inner space is divided into upper and lower portions by the support plate 200, and a vent 104 and a treatment export port 103 are installed in the upper space, and a lower portion thereof. Precision filtration device using a fiber hose, characterized in that the fluid inlet 101 and backwash outlet 102 is installed on the side and bottom of the space, respectively. The method of claim 3, wherein The body 110 to which the support plate 200 is coupled is provided with a treatment outlet 111 at an upper portion thereof, and a lower cover side is exposed, and a plurality of filtration hoses 300 coupled by the support plate 200. The filtering member including the spacer 400 in the hose is filtered by the suction action by the suction pump 600 connected to the treatment outlet 111 of the cover part in the state immersed in the fluid of the fluid storage tank 500. Precision filtration device using a fiber hose.