KR20030003166A - Apparatus for fine filtering having variable pore structure - Google Patents

Abstract

PURPOSE: A device with variable pore structure for micro filtration is provided to effectively remove suspended solids from effluent discharged from wastewater treatment facilities as well as completely separate suspended solids captured by the device by using water together with air. CONSTITUTION: The device with variable pore structure for micro filtration includes a plural upper filter fix frames(2); a plural lower filter fix frames(3); rails(22,33) for fixing the upper filter fix frames and the lower filter fix frames to guide linear motion of the filter fix frames(2,3); a piece(4) for connecting the filter fix frames(2,3); a plate(8) which has several orifices for filtrate discharge.

Description

Apparatus for fine filtering having variable pore structure}

The present invention relates to a filtration device that can control the pore of the flexible fiber yarns filled in the filter fixing frame of the upper and lower filtration device, in particular during filtration to obtain excellent water quality through fine filtration by making the filter medium in pore structure The present invention relates to a pore-controlled precision filtration apparatus that performs a perfect backwash with water and air in a state where the pore structure of a filter medium is dismantled, thereby drastically improving the filtration quality, the amount of filtration, and the filtration duration.

In general, pollutants that pollute the environment in sewage, wastewater, and drinking water are largely divided into dissolved (0.1 μm or less) and suspended (0.1 μm or more), and various kinds of suspended solids, sewage, industrial water, and lake water, etc. Contains Suspended Solids. Here, the suspended solids are solid substances composed of particles (organic and inorganic) having a size of 0.1 micron or more, and are also called suspended substances because they suspend water.

Water containing the suspended substance (suspension) is not suitable for use as general water at home or industrial sites, etc. as it is. Therefore, by treating and using the suspended solids present in these waters has been developed a water treatment filtration device to save water and water resources to increase the energy saving effect.

In order to further improve the performance of the filtration apparatus, the filtrate is used as a filter medium, and the filter unit is fixed to the lower end of the filtration unit, the filter medium is brought into close contact with the raw water supply pressure, and the media is expanded with the air and washing water supply pressure. (Registration No. 10-0241198; Application No. 10-1997-0050047, Application Date 1997-09-30; Filtration apparatus having a variable filter layer), but this method is a single layer and the degree of adhesion of the media is determined by the raw water supply pressure. Since it is determined that the capture space of the floating material is small, the filtration duration is short, the frequency of washing is frequent, it is difficult to cope with the fluctuation of water quality of the influent, it is difficult to arbitrarily control the desired water quality and quantity.

In order to solve the above problems, a conventional pore controlled filtration device (Public Publication No. 2000-0072266; Application No. 10-2000-0049089; Application Date 2000-08-24; Pore controlled filtration device) has been developed and known. Filtration device that achieves filtration and backwashing by close / relaxing the filter bed with restoring force and repulsive force due to spring and pore control bag.As a separate pore control bag and spring are installed inside the device, considerable inconvenience is required when changing the media. The adhesion of the sac is not only limited, but also has a problem in that when the device is used for a long time, the elastic force of the spring is exhausted, causing a problem of adhesion / relaxation of the media.

Floating solid material separation device in a solution using a conventional flexible fiber yarn to solve the problem (Registration No. 10-0324727; Application No. 10-1999-0013396; File date 1999-04-15; Floating in a solution using a flexible fiber yarn Solid material separation device), which can control the depth of the filter layer and the particle capture space according to the length of the fiber yarn used as the media, and the porosity, pore size, particle capture amount and filter water quality It was easy to control and easy to cope with the change of water quality of the feed water, and the method of integrating flexible and elastic fiber yarns was difficult to mechanize and the size of the filtration device was increased due to low filtration rate. .

Conventional underwater suspended solids filtering device (registration number 10-0354836, application number 10-1999-0013448, filed date 2001-03-15; underwater suspended solids filtering device) to solve the above problems is the flow of water through the filter bed The filter device adopts the principle of filtering media and the capillary phenomenon caused by the media filled in the longitudinal direction as the main filtration principle by making it co-current. It is characterized by the small size of the device by increasing the speed greatly, but it was difficult to remove the suspended solids in the water of less than 5㎛.

The present invention was created in order to solve the problems shown in the conventional filtration device as described above, regardless of the type, size, state, etc. of the suspended solids in the filtration to filter the suspended solids contained in the water 1㎛ or more A pore-controlled precision filtration device that creates a pore structure by bringing it into close contact with a critical thickness, and in the case of backwashing, disassembles the pore structure and performs perfect backwashing with water and air to improve filtered water quality, filtered water quantity, and filtration time. Its purpose is to provide.

Another object of the present invention is to provide a pore-controlled precision filtration device capable of quickly coping with external environmental changes due to flow rate increase and water quality change by modularizing the filter fixing frame mounted in the filtration device.

Another technical problem to be achieved by the present invention, by trapping the trapped particle outflow prevention plate inside the top of the inlet of the filter device to make the pore structure of the top of the inlet more densely induce deeper and multi-layer filtration of the influent to capture particles of 1㎛ or more It is an object of the present invention to provide such a pore controlled fine filtration device.

Another technical problem to be achieved by the present invention is to fill a filter medium with a relatively large pore in the filter fixing frame close to the inlet, and to fill a medium having a relatively small pore as the distance from the inlet is minimized, thereby minimizing the resistance to the filter medium. It is an object of the present invention to provide a pore-controlled precision filtration apparatus for treating water and wastewater effluent.

Another object of the present invention is to provide a pore-controlled precision filtration device that provides a smooth discharge of trapped particles desorbed by water and air during backwashing by installing a backwash water outlet in a double jacket form.

Another technical problem to be achieved by the present invention is to provide a pore-controlled precision filtration device that enables a parallel filtration system that can increase the treatment capacity by combining a plurality of filtration devices in parallel to be suitable for treating a large amount of raw water. There is a purpose.

1 is a block diagram of a filtration process of a pore control type microfiltration device according to the present invention.

Figure 2 is a block diagram of the backwashing process of the pore control type precision filtration device according to the present invention.

Figure 3a is a detailed view of the upper filter frame of the pore control type microfiltration apparatus according to the present invention.

Figure 3b is a detailed view of the lower filter medium of the air gap controlled microfiltration apparatus according to the present invention.

Figure 4 is a detailed view of the piece for connecting the filter medium of the pore control type microfiltration apparatus according to the present invention.

5 to 8 are each a graph of an experimental embodiment of a pore control type precision filtration device according to the present invention.

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

1: filtration device 2: upper filter frame

3: lower media fixing frame 4: media fixing frame connection piece

6: inlet perforated plate 7: inlet

8: close contact sheet 9: outlet

10: outlet outlet 11: backwash water outflow jacket

12: backwash water outflow outlet 13: median fixing station

14: backwash water / backwash air inlet 15: trapped trapping particles

16: flexible fiber yarn (s) 22: rail for upper media fixing frame

33: Rail for lower media fixing frame

In order to achieve the above object, the pore control type microfiltration device according to the present invention separates and removes the suspended solids in the effluent or the purified water from the sedimentation tank of the sewage and / or wastewater treatment plant during filtration, A filtration apparatus for desorbing contaminants trapped in a media using water, comprising: a plurality of upper media fixing frames and lower media fixing frames respectively installed on upper and lower portions of the filtration apparatus to fix flexible fiber yarns as media; An upper filter fixing frame rail and a lower filter fixing frame rail which are respectively installed on the upper and lower portions of the filtration device to guide the linear movement of the respective filter fixing frame; A connecting piece for connecting the media fixing frame such that the plurality of media fixing frames linearly moving on the rails are spaced from each other in close contact or at regular intervals; It is installed in the upper and lower filter fixing frame located at one end of the plurality of filter fixing frame to release the close or close contact with the flexible fiber yarns by the linear movement of the filter fixing frame, discharge the effluent water in a certain area of the upper It characterized in that it comprises a filter medium contact plate is formed with holes for outflow.

In a preferred embodiment of the present invention, the medium contact plate is installed at a predetermined height on the opposite side of the installed position and the inlet perforated plate formed with a plurality of inlet holes for the inlet water inlet; A trapped particle leakage preventing plate installed inward from the inlet porous plate at an upper portion of the influent porous plate to suppress wall flow of the influent and prevent the outflow of the captured particles captured by the flexible fiber yarns; And a backwash water outlet jacket installed around the upper outer side of the filtration device to induce the discharge of suspended solids detached from the flexible fiber yarns during backwashing of the filtration device.

In a preferred embodiment of the present invention, the lower filter fixing frame is formed with a plurality of holes for alternately injecting air and water for backwashing the filtration device.

In a preferred embodiment of the present invention, each of the upper filter medium fixing frame and the lower filter medium fixing frame is formed for fixing the flexible fiber yarns, the filter medium is formed to form an equilateral triangle with each other.

In a preferred embodiment of the present invention, near the inlet porous plate is filled with a relatively large void flexible fiber yarns, and as the distance away from the influent porous plate is filled with a proportionally smaller flexible fiber yarn.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the pore control type microfiltration apparatus according to the present invention. In the following description of the present invention, when it is determined that detailed descriptions of related well-known technologies or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

1 is a configuration diagram during the filtration process of the pore control type microfiltration device according to the present invention, Figure 2 is a configuration diagram during the back washing process of the pore control type microfiltration device according to the present invention. 3A and 3B are detailed views of the upper filter fixing frame and the lower filter fixing frame of the pore-controlled microfiltration device according to the present invention, respectively, and FIG. 4 is a detailed view of the piece for connecting the filter fixing frame of the pore-controlled microfilter according to the present invention. to be.

1 to 4, the microfiltration device 1 according to the present invention includes an upper filter fixing frame 2 and a lower filter fixing frame 3 for fixing the flexible fiber yarn 16 as a filter. Are respectively mounted on the upper and lower portions of the upper and lower portions of the upper and lower housings of the filtration device 1 so as to smoothly carry out the linear movement of the filtering frame 2 and 3. It is fixed to, and the media fixing frame connecting piece (4), which is a means for keeping the media fixing frame (2) (3) in close contact or spaced at equal intervals is placed inside the media fixing frame (2) (3), the media fixing frame ( 2) (3), the media close contact plate 8, which performs the pore structure (adhesion of the flexible fiber yarns) and disassembly (the widening of the flexible fiber yarns) of the flexible fiber yarns 16 through the reciprocating motion, is the rightmost media. It is fixedly installed in the fixing frame (2) and (3), and evenly inflow of inflow water is provided at the lower left of the filtration device (1). An inlet porous plate 6 having a plurality of inlets 7 formed therein is installed, and the trapped particle leakage preventing plate 15 for fixing to the influent wall flow is fixed on the inlet porous plate 6, and filtered. On the outside of the top of the apparatus 1, a backwash water outlet jacket 11 is installed to be inclined toward the backwash water outlet 12 to smoothly discharge the detached suspended solids during backwashing.

On the other hand, the arrangement of the filter fixture (13; Figs. 3a, 3b) for fixing the filter in the filter frame (2) (3) to form an equilateral triangle arrangement with each other for uniform filling and precision filtration of the filter medium. In addition, the flexible fiber yarns 16 mounted to the median fixing fixtures 12 and 13 are installed with the thickest fiber yarns in the vicinity of the inflow porous plate 6, and the thinner the fiber yarns as they get closer to the outlet 9. To adjust the porosity of the media. In addition, the flexible fiber yarns 16 mounted on the media fixing fixtures 12 and 13 are installed to be longer than the interval between the upper and lower media fixing frame 2 and 3 to secure flexibility during backwashing, and the backwashing water. The outlet jacket 11 has a slope of 5 ° or more from the bottom so that the concentrate can be smoothly discharged.

The operation of the pore control type microfiltration device according to the present invention configured as described above will be described with reference to FIGS.

Referring to FIG. 1, in the filtration process, the media contact plate 8 moves forward in the direction of the inflow porous plate 6, so that the flexible fibers 16 filled in the media fixing frame 2 and 3 have a critical thickness, that is, media The fixing frame 2 and 3 are brought into close contact with each other to form a pore structure. Here, since the trapped particle outflow prevention plate 15 is installed inside the filtration device 1 rather than the inflow porous plate 6 as shown, the flexible fiber yarn 16 in the area where the trapped particle outflow prevention plate 15 is installed. ) Form a more tight pore structure.

In the state in which the flexible fiber yarns 16, which are the media forming the filtrate as described above, are in close contact with each other, the inflow water is filtered through the inlets 7 of the inflow porous plate 6 installed at the lower end of the filtration device 1. When introduced into the media, the influent flows evenly into the filled media, while particles larger than the median pores formed by the flexible fibres 16 are trapped in the media by the flexible fibres 16 and then the media layer. Will come out.

After the particles larger than the filtrate pores included in the influent are trapped in the flexible fiber yarns 16, the filtered inflow water exits the media layer, and the filtered inflow is the outlet 9 of the media adhesion plate 8. It is discharged to the outside of the filtration device 1 through the outlet outlet 10 via them. That is, the inflow water flows into the lower part of the filtration device 1 and proceeds upward, and is filtered by the flexible fiber yarns 16, and then passes through the outlet port 9 of the medium contact plate 8 and then the outlet port 10. Through the filtration device 1 is discharged to the outside.

The filtration layer of the filtering device 1 is formed by the trapped particle outflow prevention plate 15 so that the inflow water permeable plate 6 forms a more dense pore structure than the inflow porous plate 6 part. A flow path to the filtrate naturally forms, resulting in deep and multilayer filtration. In this case, it is possible to flexibly cope with the inflow water quality and quantity by adjusting the filling density, thickness, depth of the filtrate, etc. of the flexible fiber yarns 16, which are media. If the discharge rate of the effluent during the filtration process operation decreases below the set value or the pressure in the filtration device 1 rises above the set value, the filtration process is stopped and the process is switched to the backwash process.

The backwashing process is performed in a state in which the pore structure of the flexible fiber yarn 16 media filled with the media fixing plate 8 is retracted and filled in the media fixing frame 2, 3. Preferably, the backwashing air is injected from the backwashing water / backwashing air inlet 14 (FIG. 3) of the lower filter fixing frame 3 to desorb the suspended solids trapped in the flexible fiber yarns 16, and then Supply 0.5 ~ 1.0% backwash water to clean up desorbed suspended solids. When the backwashing air is injected, the medium close contact plate 8 is oscillated from side to side, thereby increasing the desorption effect due to the turbulent effect formed. In the case of wastewater that is not easily detached due to its high viscosity, it is equipped with vibration generating means such as a single-axis rotary cam, hammer, vibrator, etc., which is not shown in the lower part, so that the filtration module can be vibrated quickly and strongly or upside down, left or right, and backwashed. Can increase. The concentrated water generated in the backwashing process is discharged to the outside through the backwashing water outlet 12 through the backwashing water outlet jacket 11 of the upper part of the filtration apparatus 1, and the reversed water is discharged for natural discharge of the concentrated water. The wash water outlet jacket 11 is inclined at least 5 ° from the bottom.

The backwashing process is repeated once to five times to keep the media clean according to the suspended solids concentration and properties accumulated in the flexible fiber yarns 16. The backwashing process changes the pore structure of the filtration layer to increase the opportunity and area for contacting the pressurized air and the backwash water with the media, and the turbulence formed by the pressurized air and the backwash water and the media contact plates 8 on the sides. This increases the backwash effect.

Hereinafter, the present invention will be described in more detail with reference to practical examples.

Example-Sewage Treatment at Y City

Y-Y Y sewage treatment plant installed a filtration device according to the present invention of size 1500L × 1000W × 1000H and operated for 6 months, the average daily flow rate 5,000m ³ / day, average flux 9,918m ³ / m ² / d, and the pressure was always kept below 1 kg _f / cm ² . In addition, the removal efficiency reached 96.2% with 8.2ppm of influent suspended solids and 0.3ppm of suspended solids. The removal efficiency by particle size was maintained at 68% at 1 to 3 μm, 78% at 3 to 5 μm, 81% at 5 to 8 μm, and 90% or more at 8 μm or more. 12 is shown for reference.

As described above, the pore control type precision filtration apparatus according to the present invention can arbitrarily control the effluent water quality and the filtration rate by changing the type and density of the media installed in the media fixing frame, and the pore structure of the media during filtration and backwashing. In addition, by suppressing the increase in the filtration resistance and extending the filtration duration, it is possible to drastically reduce the back washing frequency, the time required for the back washing, and the amount of back washing, as well as to manufacture the filter fixing frame in the form of cartridge. It offers advantages such as ease of use.

Although a preferred embodiment of the present invention has been described in detail above, those skilled in the art to which the present invention pertains, various embodiments of the present invention without departing from the spirit and scope of the invention defined in the appended claims It will be appreciated that modifications or variations may be made. Therefore, changes in the future embodiments of the present invention will not be able to escape the technology of the present invention.

Claims (5)

In the filtration device that separates and removes the suspended solids in the effluent or purified water from the sedimentation tank of the sewage and / or waste water treatment facility during filtration, and desorbs contaminants trapped in the media by using air and water during backwashing, A plurality of upper filter fixing frames and lower filter fixing frames respectively installed on the upper and lower portions of the filtration apparatus to fix the flexible fiber yarns that are filter media; An upper filter fixing frame rail and a lower filter fixing frame rail which are respectively installed on the upper and lower portions of the filtration device to guide the linear movement of the respective filter fixing frame; A connecting piece for connecting the filter holders such that the filter holders linearly moving on the rails are spaced from each other in close contact or at regular intervals; It is installed in the upper and lower filter fixing frame located at one end of the plurality of filter fixing frame to release the close or close contact with the flexible fiber yarns by the linear movement of the filter fixing frame, discharge the effluent water in a certain area of the upper Pore-controlled precision filtration device, characterized in that it comprises a filter medium contact plate is formed with a hole for outflow. According to claim 1, wherein the medium contact plate is installed on the opposite side of the installed position at a certain height and the inlet perforated plate formed with a plurality of inlet holes for the inlet water inlet; A trapped particle leakage preventing plate installed inward from the inlet porous plate at an upper portion of the influent porous plate to suppress wall flow of the influent and prevent the outflow of captured particles captured by the flexible fiber yarns; And It is installed around the upper outer periphery of the filtration device and further comprises a backwash water outflow jacket for inducing the discharge of suspended matter detached from the flexible fiber yarns during the backwashing of the filtration device . The method of claim 1 or claim 2, wherein the lower filter medium is a pore-controlled precision filtration device, characterized in that a plurality of holes for alternately injecting air and water for backwashing the filtration device is formed. According to claim 1 or 2, wherein each of the upper filter medium and the lower filter frame is formed in the filter medium for fixing the flexible fiber yarns, the filter medium is characterized in that formed in an equilateral triangle arrangement with each other Pore-controlled precision filtration device. The method according to claim 1 or 2, wherein a relatively large pore of flexible fiber yarns are filled in the vicinity of the influent porous plate, and as the distance from the influent porous plate is filled proportionally smaller flexible fiber yarns are filled. Air gap controlled precision filtration device.