KR100869903B1 - Strainer accessorie for rotary filter - Google Patents

Abstract

A filtering element of a rotary filter strainer is provided to wash simply a filter in which suspended materials are accumulated and to improve a filtering capacity of a rotary filter in which the automatic back washing is performed. A connecting rod(201-1) is formed at an upper side of a cylindrical outside frame(201) and a bottom side of the cylindrical outside frame is opened. A height of a cone typed supporting shaft(202) is a half or less of that of an outer frame. A breadth of the bottom side of the cone supporting shaft is smaller than an inside diameter of the outer frame. The upper side of the cylindrical inner frame is combined with the bottom side of the cone typed supporting shaft. A cone typed shield(203-1) is formed at the bottom side of the cylindrical inside frame. A nozzle unit(204) is a cover for blocking a bottom side of an inner frame and an outer frame and comprises a connecting pipe(204-1) combined with a strainer through-hole of the rotary filter. A fiber filter is a cover for covering the outer frame outside.

Description

Strainer accessorie for Rotary filter

The present invention is a rotary filter composed of a cylindrical filter cylinder and a coaxially formed strainer to rotate the inside of the filter cylinder and the actuator for rotating the strainer, the upper side is a coupling port is formed in the center and the lower side is an outer cylindrical cylinder; A conical support shaft formed at a conical vertex coupled to the coupler and having a cone height less than or equal to half the height of the outer frame and a conical bottom width smaller than the outer frame inner diameter; A cylindrical inner frame having an upper side coupled to a bottom surface of the conical support shaft and having a conical blocking film formed downward downward, an open lower side, and a slit formed on a circumferential surface thereof; A cover for blocking a lower side of the outer frame and the inner frame, the nozzle unit having a coupling tube formed at a center thereof in communication with the strainer through hole of the rotary filter; The cover covering the outside of the outer frame, relates to a filtration member of the rotary strainer strainer, characterized in that composed of a fibrous filter media formed on the outside of the surface.

In general, water pollution refers to a state in which pollutants exceed the natural self-cleaning action of water and are discharged into the natural water, so that the natural water itself cannot perform the self-cleaning action by the physicochemical and biological actions.

It is a fixed water pollutant that emits pollutants through a path leading to lakes or rivers at certain places such as factories, power plants, and sewage treatment plants, and arable land, forests, cities and suburbs, roads, parking lots, and car washes contain dust, sediment It is a non-static water pollution source that emits various pollutants such as asbestos, fertilizers, heavy metals, salt, oil, and garbage.

In order to prevent such water pollution, the pollutants are equipped with water treatment facilities, and those used are water filters.

However, since the flow of polluted water discharged to natural water has the same continuous flow as general water, it is preferable that the operation of the filter to improve the polluted water quality should be continuously performed like the flow of water.

However, since the operation of the filter is to filter out contaminant suspended solids by the internal filtration filter, periodic cleaning of the filter is essential.

That is, the filter must be stopped to clean the filter.

In addition, the washing operation of the filtration filter accumulating suspended solids is very difficult, and the more frequent the frequency of washing (backwashing) to maintain a good filtration capacity, the more the filtration efficiency is reduced.

In order to solve the above problems, the applicant has invented a rotary filter of the prior application patent registration 10-0807085.

The present invention has a feature that can continuously perform filtration and backwash automatically, the filtration performance is determined by the strainer.

The present invention is a subsequent invention which improves the filtration capacity of the rotary filter.

It is an object of the present invention to provide a filtration member of a rotary strainer which improves the filtration capacity of a rotary filter in which automatic backwashing is performed because the backwashing proceeds while the operation of the filter continues and the filtration filter accumulating suspended solids is simplified. It is done.

In order to achieve the above object, the present invention is a rotary filter composed of a cylindrical filter and a coaxially formed strainer to rotate the material inside the filter and the actuator for rotating the strainer, the upper side is a coupling sphere is formed in the center and the lower side An open cylindrical outer frame; A conical support shaft formed at a conical vertex coupled to the coupler and having a cone height less than or equal to half the height of the outer frame and a conical bottom width smaller than the outer frame inner diameter; A cylindrical inner frame having an upper side coupled to a bottom surface of the conical support shaft and having a conical blocking film formed downward downward, an open lower side, and a slit formed on a circumferential surface thereof; A cover for blocking a lower side of the outer frame and the inner frame, the nozzle unit having a coupling tube formed at a center thereof in communication with the strainer through hole of the rotary filter; As a cover covering the outside of the outer frame, the filtration member of the rotary strainer strainer is characterized by consisting of a fibrous media formed on the outside of the surface of the technical features.

According to the present invention, there is provided an filtration member of a rotary strainer for improving the filtration capacity of a rotary filter in which filtration and backwashing are automatically performed.

Hereinafter, the present invention will be described with reference to the accompanying drawings. In describing the present invention, when it is determined that the detailed description of the related well-known technology or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. will be.

The terms to be described below are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators, and the definitions should be made based on the contents throughout the specification for describing the present invention.

1 is a perspective view of the present invention, Figure 2 is a cross-sectional structural view of the present invention, Figure 3 is a perspective view of a cylindrical inner frame of the present invention, Figure 4 is a drawing substitute photo of the fibrous media used in the present invention, Figure 5 6 is a flow chart showing the flow of water during filtration of the present invention, Figure 6 is a flow chart showing the flow of water during backwashing of the present invention, Figure 7 and Figure 8 is a side cross-sectional structural diagram of a rotary filter to which the present invention is applied.

The present invention is a fiber filter of a strainer used in a rotary filter, such as the applicant's prior patent registration 10-0807085, and largely composed of a cylindrical outer frame, a conical support shaft, a cylindrical inner frame, a nozzle portion, a cover, and a fibrous media.

In order to explain the present invention, it should be understood about the rotary filter in which the present invention is used. First, the present invention will be described with reference to FIGS. 7 and 8.

FIG. 7 is a gravity rotary filter and FIG. 8 is a pressure rotary filter, and the basic principle of its operation is the same, and the direction of the arrow shown in the drawing is the direction of water flow during filtration.

The rotary filter is a filter in which the strainer 20 is coaxially formed inside the filter barrel 10 in which the raw water inlet 11 and the backwash water discharge port 13 are controlled by opening and closing of the control valve.

One end of the strainer 20 extends outside the filter barrel 10 to communicate with the treated water outlet 12.

The surface of the strainer 20 is formed with a screen or a filtration membrane formed with fine pores in order to filter suspended matter.

The rotary filter is mainly connected to the pressure pipe and the fluid path is determined by the fluid flow by the strong water pressure, so that the water pressure of the pressure pipe becomes the filtration pressure, and therefore, the filtering capacity by the screen formed on the outer circumferential surface of the strainer 20. This is determined, and the filtration capacity of the screen during operation is determined according to the state of the pore.

In order to always maintain the filtration performance of such a screen at all times, the rotary filter rotates the strainer in the forward and reverse directions during backwashing so that suspended matter accumulated on the screen surface is washed with the backwashing water.

The rotary filter has a filtration path connected to the raw water inlet 11, the strainer 20, the treated water discharge port 12, as shown in Figure 7 and 8, opening the filtration path to the flow of fluid Generation to allow filtration to be performed.

When the filtration path is formed, the flow of fluid occurs naturally due to the water pressure in the pressure pipe, and the suspended solids contained in the raw water do not pass through the screen of the strainer 20 and accumulate in the filtration tank 10. At this time, the inflow of the raw water Due to the pressure, the suspended solids are concentrated and accumulated toward one side of the filter barrel 10 while the backwash water outlet 13 is formed in the concentrated accumulation portion of the suspended solids, and the suspended solids are discharged periodically. .

That is, the rotary filter forms a backwash path connected to the raw water inlet 11 and the backwash water outlet 13, and periodically opens the backwash water outlet during filtration so that suspended matters are discharged. When the porosity worsens, the raw water inlet 11 and the backwash water outlet 13 are blocked, and the strainer is strongly rotated to wash the screen surface, and then discharged to the backwash water outlet 13.

Structure and operation of the rotary filter is made as described above, the present invention is to improve the filtration capacity of the rotary filter.

In order to improve the filtration capacity of the strainer, it is desirable to increase the screen surface area formed on the strainer, and the introduction thereof has been introduced in the prior application.

The present invention relates to a filtration member 200 of the rotary strainer strainer coupled to the screen through-holes in order to increase the surface area of the screen, to form a cylinder of the frame structure largely freely entering and exiting water, the inflow of water into the cylindrical frame It forms a flow path guide having a rhombus cross section for guiding the path when it flows out, and the outer surface of the cylindrical frame is covered with a fiber bag formed with a fleece for filtration.

In order to establish such a structure, the present invention is assembled with a cylindrical outer frame 201, a conical support shaft 202, a cylindrical inner frame 203, a nozzle unit 204, and a fibrous media 210 as shown in FIG. 1. It is composed.

The outer frame 201 is a skeleton structure to form an appearance as a cylindrical frame structure formed so that water can be freely in all directions. The upper side of the outer frame 201 is provided with a coupling hole 201-1 at the center for coupling with the conical support shaft 202 to be described later, the lower side is opened in preparation for the coupling with the nozzle unit 204 to be described later do.

The conical support shaft 202 is a conical structure, a projection 202-1 is formed at the vertex of the cone is coupled to the coupler 201-1 of the outer frame 201, the cone height is the outer frame 201 ) Is less than half the height, the bottom width of the cone is formed smaller than the inner diameter of the outer frame 201, is coupled to the inner upper portion of the outer frame (201).

The inner frame 203 is a cylindrical frame structure that is coupled to the lower portion of the conical support shaft 202 inside the outer frame 201, and as shown in FIG. There is a characteristic to be formed.

That is, the inner frame 203 and the outer frame 201 are assemblies for forming a coaxial structure.

Therefore, the inner frame 203 has the same diameter as the bottom surface of the conical support shaft 202 and the conical blocking film 203-1 formed downward from the top to the bottom is formed therein, the lower side is a nozzle portion to be described later A preliminary coupling with 204 is opened and a slit by a frame is formed on the circumferential surface.

The nozzle unit 204 is a cover covering the open lower side of the outer frame 201 and the inner frame 203, the stopper is formed with a coupling pipe 204-1 is formed in communication with the strainer through-hole of the rotary filter in the center .

As shown in FIG. 4, the fibrous media 210 of the present invention is a bag that is coated on the outside of the outer frame, and a fleece is formed on the outer surface of the fiber filter and forms a filtration layer in a rotary filter.

With respect to the flow path in the present invention by such a configuration will be described taking filtration and backwashing as an example.
In the present invention, the flow of the flow path during filtration is as shown in Figs. 7 and 8, and the reverse flow path is formed during backwashing.
On the other hand, since the coupling pipe 204-1 of the nozzle unit 204 of the present invention is in communication with the strainer 20, water introduced into the strainer 20 during backwashing as shown in FIG. It is introduced into the inner frame 203 through the coupling pipe 204-1 of the nozzle unit 204, is guided laterally by the inner conical blocking film 203-1 of the inner frame 203 and the outer frame through the slit Spilled to 201.

delete

At this time, the water is moved to the upper side of the inner frame 203 through the spaced space between the inner frame 203 and the outer frame 201 by the centrifugal force is also emitted to the upper side of the outer frame 201.
When the filtration is formed, the flow path as shown in FIGS. 7 and 8 is formed, while the opposite flow path is formed as shown in FIG. 5, and the water flows through the coupling pipe 204-1 of the nozzle unit 204. Inflow to (20).

As described above, according to the present invention, the moving space of the water becomes large, so that there is no resistance pressure to the flow rate of the fluid during filtration.

The flow path is also formed by the water subjected to the centrifugal force generated by the rotational force of the strainer 20 backwashed by the conical blocking film 203-1 of the inner frame 203 and striking the entire inside of the fibrous material. Maximize backwashing efficiency of textile media.

In other words, when the fluid receives centrifugal force due to the nature of the slit structure, water is concentrated at the end of the slit, so the fluid velocity is increased, so that the fibrous material is strongly blown, and when the strainer 20 rotates, Smooth backwashing is achieved by the vortices generated by repeating the rotation and reverse rotation and the air bubbles introduced during backwashing.

Fiber filter 210 of the present invention is a bag-shaped cover covering the outside of the outer frame 201, the fleece is formed on the outer surface, wherein the fleece of the fiber filter 210 is compressed by filtration by water pressure during filtration The air gap is formed, and at the time of backwashing, it is expanded by hydraulic pressure to form a backwashing space.

The present invention configured as described above is attached to the screen through-holes of the strainer 20, the filtration and backwashing is carried out at the same time, and the filtration of the rotary filter strainer to improve the filtration capacity of the rotary filter to perform backwashing by rotating the strainer 20 As the elements of the basic technology, the embodiment shown for the purpose of the present invention described above is only one embodiment in which the present invention is embodied, in order to realize the gist of the present invention in addition to those shown in the drawings It can be seen that a combination of forms is possible.

Therefore, the present invention is not limited to the above-described embodiments, and various changes can be made by any person having ordinary skill in the art without departing from the gist of the present invention as claimed in the following claims. It will be said that the technical spirit of this invention is to the extent possible.

1 is a perspective view of the present invention

2 is a cross-sectional structural view of the present invention

3 is a perspective view of a cylindrical inner frame of the present invention

Figure 4 is a perspective photo for the drawing of the fiber media used in the present invention

Figure 5 is a flow diagram showing the flow of water during the filtration of the present invention

Figure 6 is a flow diagram showing the flow of water during backwashing of the present invention

7 and 8 is a side cross-sectional structural view of the rotary filter to which the present invention is applied

* Explanation of symbols on main parts of the drawings *

10: filter tank 11: raw water inlet

12: treated water discharge port 13: backwash water discharge port

20: strainer 30: motor

200: filter member of the rotary strainer

201: cylindrical outer frame 201-1: coupler

202: conical support shaft 202-1: protrusion

203: inner frame 203-1: conical barrier

204: nozzle portion 204-1: coupling pipe

210: textile media

Claims (1)

In the rotary filter consisting of a cylindrical filter cylinder, a coaxial strainer to be rotated inside the filter cylinder and an actuator for rotationally driving the strainer, An upper side of the cylindrical outer frame having a coupler formed at the center thereof and an open side thereof; A conical support shaft formed at a conical vertex coupled to the coupler and having a cone height less than or equal to half the height of the outer frame and a conical bottom width smaller than the outer frame inner diameter; A cylindrical inner frame having an upper side coupled to a bottom surface of the conical support shaft and having a conical blocking film formed downward downward, an open lower side, and a slit formed on a circumferential surface thereof; A cover for blocking a lower side of the outer frame and the inner frame, the nozzle unit having a coupling tube formed at a center thereof in communication with the strainer through hole of the rotary filter; An outer bag covering the outside of the outer frame, the filament having a fleece formed outside the surface; Filtration member of the rotary filter strainer, characterized in that configured.

Images