KR102185217B1 - Prefabricated filtration module - Google Patents

Abstract

The present invention relates to a prefabricated filtration module comprising: a cartridge assembly which includes a plate member having a flow hole formed on one side and mounting portions in a groove shape on both side, and a spacer attached to the mounting portions, and in which a plurality of filtration cartridges including a filtration membrane attached to the spacer and exposed to the outside are assembled in a zigzag manner to form a flow path between opposing filtration membranes; and a fluid supply unit assembled on one side of the cartridge assembly and supplying the fluid to the filtration cartridges in contact while receiving and storing the fluid.

Description

Prefabricated Filtration Module{PREFABRICATED FILTRATION MODULE}

The present invention relates to a filtration module capable of improving filtration efficiency by making the fluid to be treated sufficiently in contact with the filtration membrane while being compact.

In general, a treatment technology using a filtration module is widely used for water treatment such as sewage, wastewater, and purified water.

As an example of a technology related to such a filtration module, Korean Patent Registration No. 10-1260498 includes a water-passing housing; A fixing part provided on an upper end of the water passing housing; And 30 to 40 wt% of activated carbon and 60 to 70 wt% of a calcined zeolite carrier, and comprising a filtration unit located in the water passing housing, wherein the filtration unit is disposed on a first filtration layer containing activated carbon and the first filtration layer. And a stack of one or more layers composed of a second filtration layer, wherein the calcined zeolite carrier is formed by calcining a mixture obtained by adding 2 to 3 wt% of a polyamide compound to 97 wt% to 98 wt% of natural zeolite, and the activated carbon is 8 It proposes a filtering module for wastewater treatment, characterized in that it is a palm tree activated carbon having a particle diameter of ~12mm.

However, in the case of the filtration module, it is a configuration in which filtration is performed while fluid passes through a plurality of filtration units in one direction. there is a problem.

Korean Patent Registration No. 10-1260498

Accordingly, in order to solve the above problems, the present invention is to provide a filtration module capable of increasing filtration efficiency by making the fluid to be treated sufficiently contact the filtration membrane while being compact by assembly.

The prefabricated filtration module of the present invention (hereinafter referred to as "the module of the present invention") for achieving the above object includes a plate member having a flow hole formed on one side and a mounting portion formed in a groove shape on both sides, and attached to the mounting portion. A cartridge assembly in which a plurality of filtration cartridges including a spacer and a filtration membrane attached to the spacer and exposed to the outside are zigzag-assembled to form a flow path between opposing filtration membranes; A fluid supply unit that is assembled on one side of the cartridge assembly and supplies a fluid to a filtering cartridge that contacts while receiving and storing the fluid; It characterized in that it comprises a.

As an example, a cylindrical tube that is rotatably mounted in the flow hole is formed so that a flow gap is formed on both sides of the cylindrical tube.

As an example, the filter cartridge is characterized in that the water-tight ring is configured outside the mounting portion.

As an example, the fluid supply unit is formed by assembling at least one fluid supply chamber in which a fluid inlet and a fluid outlet are formed.

As an example, a plurality of locking protrusions are formed on an outer periphery of the cylindrical tube.

The module of the present invention as described above has the advantage of having high filtration efficiency while making the device compact.

1 is an exploded perspective view of the module of the present invention,
Figure 2 is a side cross-sectional view showing a filter cartridge as one configuration of the present invention,
3 is a side cross-sectional view showing a fluid supply chamber as one configuration of the present invention,
4 is an operational state diagram of the filter cartridge in the present invention,
Figure 5 is an operational state diagram showing an embodiment of the filter cartridge as a configuration of the present invention.

Hereinafter, the configuration and operation of the present invention will be described in more detail based on the accompanying drawings. In describing the present invention, terms or words used in the present specification and claims are the present invention based on the principle that the inventor can appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted as a meaning and concept consistent with the technical idea of

The module 1 of the present invention includes a plate member 211 having a flow hole 212 formed on one side and mounting portions 213 formed in a groove shape on both sides, as shown in FIGS. 1 and 2, and the mounting portion 213 ) And a filter cartridge 21 including a spacer 215 attached to the spacer 215 and a filtration membrane 216 attached to the spacer 215 to be exposed to the outside are assembled in a zigzag manner in a plurality of passages between the filtration membranes 21 facing each other ( Cartridge assembly (2) in which 217 is formed; And a fluid supply unit 3 that is assembled on one side of the cartridge assembly 2 and supplies the fluid to the filtration cartridge 21 that contacts while receiving and storing the fluid.

That is, the module 1 of the present invention is composed of a cartridge assembly 2 and a fluid supply unit 3 formed by assembling a plurality of filter cartridges 21, and the cartridge assembly 2 is filtered as described below. The flow holes 212 of the cartridge 21 are stacked and assembled in a zigzag so that they cross each other, so that the flow path 217 formed by assembling the filtration cartridge 21 is also formed in a zigzag manner, thus minimizing the device and filtering the fluid. It is configured to increase the filtration efficiency by lengthening the contact length with (21), and when an abnormality such as blockage occurs in some of the filtration cartridges (21), the replacement is easy, so that maintenance and management are also advantageous.

Here, the assembly structure of each of the filter cartridges 21, cartridge assembly 2, and fluid supply unit 3 can be applied to various known techniques, so a detailed description thereof will be omitted.

As shown in the drawing, the filtration cartridge 21 includes a plate member 211 having a flow hole 212 formed on one side and having a mounting portion 213 formed in a groove shape on both sides, and a spacer attached to the mounting portion 213 And a filtration membrane 216 attached to the spacer 215 and exposed to the outside.

The flow hole 212 is characterized in that a cylindrical tube 214 mounted to be rotatable is formed, and flow gaps 218 are formed on both sides of the cylindrical tube 214.

As the flow gap 218 is formed in the flow hole 212 in this way, the fluid flowing through the flow path 217 first flows (W1) to the other flow path 217 through the adjacent flow gap 218 and the flow rate is In many cases, the flow (W2) is made to the other flow path 217 through the other flow gap 218 as well. The reason why the flow gap 218 is formed as a pair is that the fluid flows through the flow hole 212 at the same time. This is to solve the problem that a load such as backflow may occur due to flow resistance, etc. when flowing through the flow path 217, and the fluid flowing through the flow path 217 is sufficiently contacted with the filtration membrane 216 by controlling the flow rate of the fluid. It is to increase filtration efficiency.

Here, in order to form a pair of flow gaps 218, a cylindrical tube 214 is mounted so as to be rotatable in the flow hole 212, which is applied to the flows (W1, W2) of the fluid passing through the flow gaps 218, respectively. Accordingly, it is to control the flow resistance of the fluid so that the cylindrical tube 218 is rotated.

That is, the cylindrical tube 218 is rotated so that a pair of flow gaps 218 are formed in order to control the filtration load as seen above by a pair of flow gaps 218 and to control the formation of shoots according to the flow rate control. The flow resistance of the fluid is controlled by

As shown in the drawing, the filtration cartridge 21 is provided with mounting portions 213 in the shape of grooves on both sides while connecting to the flow hole 212, respectively, a spacer 215 and a filtration membrane 216 in the mounting portion 213. ) Is attached. As shown in the drawing, the depth of the mounting part 213 should be larger than the sum of the thicknesses of the spacer 215 and the filtration membrane 216 so that the flow path 217 is formed.

The spacer 215 is laminated under the filtration membrane 216 to control shape deformation and damage of the filtration membrane 216 and allow the solution to permeate, and the material is not limited. For example, a porous plastic, etc. Can be applied.

In the case of the filtration membrane 216 as well, since various known materials may be used, detailed description of the material will be omitted.

In the present invention, the flow path 217 is formed as shown in FIG. 2, but as each filtration cartridge 21 is assembled in a zigzag manner, the filtration membrane 216 of the filtration cartridge 21 on the other side is a flow hole ( 212), and in the case of the filtration membrane 216 at this part, as the fluid W2 flowing through the flow gap 218 near the end passes through, a structure in which filtration can be performed in the entire filtration membrane 216 is formed. will be.

The filter cartridge 21 has a water-milling ring 219 outside the mounting part 213, and as shown in the drawing, the water-milling ring 219 is configured in a "c" shape to attach the mounting part 213 It is to be attached to one surface of the plate member 211 in a surrounding shape to ensure watertightness during assembly.

The fluid supply unit 3 is assembled on one side of the cartridge assembly 2 and corresponds to a configuration to supply the fluid to the filter cartridge 21 in contact with the fluid supply unit 3 while receiving and storing the fluid to be treated.

In particular, in the present invention, in order to achieve efficient filtration by sequentially treating a certain amount of fluid, and to improve the processing speed and reduce the load, the fluid supply unit 3 is provided with a fluid inlet 311 as shown in FIG. An example in which the fluid outlet 312 is formed by assembling one or more fluid supply chambers 31 is provided.

By discharging the fluid to be treated at different locations through the fluid outlets 312 from the plurality of fluid supply chambers 31, the fluids discharged from the fluid supply chambers 31 pass through the flow path 217 formed in a zigzag with almost the same copper line. By passing through the time difference caused by the difference in start, the efficiency is expressed in the treatment of the same flow rate.

That is, in the processing of the same flow rate, the flow rate that can be processed in each flow path 217 is determined, so that the fluid is simultaneously discharged from several lines at different locations and passes through each flow path 217 with a time difference, thereby improving temporal efficiency. To improve.

Meanwhile, there are cases in which relatively large foreign substances (S) such as hair are mixed in the fluid, and when such relatively large foreign substances (S) are deposited on the filtration membrane 216, a floc may be formed in the filtration membrane 216, and the formation of such a floc. Becomes a factor that hinders the flow of fluid. In addition, the relatively large foreign material S may cause problems such as damage to the filtration membrane 216.

Accordingly, in the present invention, a relatively large foreign matter (S) such as hair, apart from filtration by the filtration membrane 216, is filtered in the fluid flow process (W1, W2) to prevent clogging and damage of the filtration membrane 216 mentioned above. An example is presented in FIG. 5.

In this embodiment, a plurality of locking protrusions 214-1 are formed on the outer periphery of the cylindrical tube 214, so that relatively large foreign substances such as hair are formed in the locking protrusions 214-1 in the fluid flow process (W1, W2). (S) is to be filtered. That is, in the fluid flow process (W1, W2), the cylindrical tube 214 rotates clockwise (S1) and counterclockwise (S2), and as such rotation is repeated, foreign matter (S) mixed in the fluid is It is to be caught by the protrusion 214-1 and filtered.

The present invention as described above has been described with reference to an embodiment shown in the drawings, but this is only exemplary, and various modifications and other equivalent embodiments are possible from those of ordinary skill in the art. Will understand. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

1: module of the present invention 2: cartridge assembly
3: fluid supply unit 21: filter cartridge
211: plate member 212: flow hole
213: mounting portion 214: cylindrical tube
215: spacer 216: filtration membrane
217: Euro

Claims (5)

A plurality of filtration cartridges including a plate member having a flow hole formed on one side and mounting portions in a groove shape on both sides, a spacer attached to the mounting portion, and a filtration membrane attached to the spacer and exposed to the outside are assembled in a zigzag manner. A cartridge assembly in which a flow path is formed between opposing filtration membranes;
A fluid supply unit that is assembled on one side of the cartridge assembly and supplies a fluid to a filtering cartridge that contacts while receiving and storing the fluid;
Prefabricated filtration module comprising a.
The method of claim 1,
An assembly type filtration module, characterized in that the flow hole has a cylindrical tube mounted to be rotatable to form a flow gap at both sides of the cylindrical tube.
The method of claim 1,
Assembled filtration module, characterized in that the water-sealing is configured to the outside of the mounting portion on the filtration cartridge.
The method of claim 1,
The fluid supply unit,
An assembled filtration module, characterized in that formed by assembling at least one fluid supply chamber in which a fluid inlet and a fluid outlet are formed.
The method of claim 2,
Assembly type filtration module, characterized in that a plurality of locking projections are formed on the outer periphery of the cylindrical tube.

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