KR102037420B1 - Membrane frame advanced in efficiency of membrane application and immersion type membrane module unit using the same - Google Patents

Abstract

The present invention relates to a membrane frame and an immersion type membrane module unit using the same. More specifically, the present invention relates to a membrane frame and an immersion type membrane module unit using the same to maximize the membrane application efficiency. A lifting ring is installed at a predetermined distance from the top of the membrane frame composed of an upper frame, a lower frame, and two vertical frames to a lower portion. An upper portion of the lifting ring can form a free space for a lifting hoist to be inserted to allow the hoist to be inserted into the free space of the immersion type membrane module unit when lifting the immersion type membrane module unit. By lowering the floor height of the building as much as possible, the initial investment cost can be reduced, or by deepening the effective depth of a reactor, the treatment efficiency of the immersion type membrane device can be enhanced.

Description

Membrane frame advanced in efficiency of membrane application and immersion type membrane module unit using the same}

The present invention relates to a separator frame and an immersion type membrane module unit using the same, and more particularly, a lifting hook is installed at a predetermined distance from a top end of the separator frame to a lower portion thereof, and a lifting hoist can be inserted into an upper end of the separator frame. The hoist can be inserted into the submerged membrane module unit when forming a free space so that the hoist can be inserted into the submerged membrane module unit to lower the floor height of the building as much as possible to reduce the initial investment cost or to deepen the effective depth of the membrane tank. The present invention relates to a separator frame for maximizing a separator application efficiency and to an immersion type membrane module unit using the same.

The submerged membrane module unit is a device for purifying wastewater by filtering and filtering out dissolved pollutants and microorganisms and suspended solids contained in the wastewater, and consists of a membrane module and a membrane frame.

Separators include spiral wound, tubular, hollow fiber, and plate and frame, among which hollow fiber membranes are designed to increase and integrate processing capacity in a limited space. Thousands of hollow fiber membranes are bundled and used in the form of cylindrical or rectangular hollow fiber membrane modules.

The membrane frame is for supporting a plurality of membrane modules, and includes a top frame for fixing the top of the membrane module, a bottom frame for fixing the bottom of the membrane module, and two vertical frames for fixing the top frame and the bottom frame into a rectangular parallelepiped. do. In addition, the separator frame is connected to a filtered water outlet through which a suction pump is connected to discharge filtered filtrate through a plurality of membrane modules to the outside, and an external air injection device is connected to spray the air bubbles toward the plurality of membrane modules. There is provided an air inlet and an air diffuser.

In addition, the immersion type membrane module unit is to install a plurality of membrane modules inside the membrane frame to be immersed in the membrane tank of a constant depth to filter contaminants. The submerged membrane module unit needs to be replaced or cleaned periodically because contaminants adhere to the membrane surface after a certain period of use.

Chemical cleaning includes in-line washing in a reaction tank and off-line washing in a washing tank outside the reaction tank. In particular, the immersion type membrane module unit should be lifted from the membrane tank by using a membrane lifting device composed of a hoist and a monorail. That is, by hooking the hoist to the hook ring provided in the submerged membrane module unit, the membrane is pulled up completely to the outside of the membrane tank, and then transported in the horizontal direction to be immersed in the cleaning tank for a predetermined time so that the washing is performed.

On the other hand, the conventional separator frame, as shown in Figure 8, the reference ring 165 for hanging the hook of the hoist is installed in the center of the top of the separator frame. In addition, the lifting support 160 is coupled to the upper end of the membrane frame to install the lifting ring 165. At this time, when the lifting support 160 is located inside the vertical frame 110, it interferes with the installation space of the hollow fiber membrane module, so that a bar bracket made of steel sheets is formed on the vertical frame 110, respectively, between the bar brackets (bbk). Install the lifting support 160 on.

As such, in the conventional separation membrane module, since the lifting support 160 and the lifting ring 165 are located at a position slightly higher than the vertical frame 110, as shown in FIG. 9, the submerged separation membrane module unit 200 is formed. When lifting, the floor height (H) of the building in which the submerged membrane module unit 200 is installed should include the height of the hoist. Therefore, the ceiling of the building must be raised in order to sufficiently secure the height of the building (H). In addition, if the floor height (H) of the building is not secured, the effective depth of the separation membrane tank (6) has to be lowered, so there is a problem that the treatment efficiency of the immersion type membrane device is lowered.

Republic of Korea Patent Publication No. 10-2019-0048998 (published: 2019.05.09) Republic of Korea Patent Registration No. 10-1579488 (Registration Date: 2015.12.16)

The present invention is to solve the problems of the prior art, the main object of the present invention, the lifting ring is installed at a predetermined distance away from the top of the separator frame, the lifting hoist to enter the upper portion of the lifting ring When forming the free space to lift the submerged membrane module unit, the lifting hoist is inserted into the upper end of the submerged membrane module unit, thereby lowering the floor height of the building where the submerged membrane module is installed to reduce the initial facility investment cost. It is to provide a membrane frame of the submerged membrane module unit that can reduce and deepen the effective depth of the membrane tank to improve the treatment efficiency of the submerged membrane device.

As a means for achieving the object of the present invention, the membrane frame maximized the membrane application efficiency according to the present invention, in the membrane frame for supporting a plurality of membrane modules,

An upper frame including one or more upper supports to fix the upper ends of the plurality of membrane modules;

A lower frame including one or more lower supports for fixing lower ends of the plurality of membrane modules;

Including; two vertical frames installed between the upper frame and the lower frame;

A lifting ring installed at a position spaced a predetermined length downward from the upper frame;

And a free space formed at an upper portion of the lifting ring so that the hoist connected to the lifting ring can be inserted up and down.

In the present invention, the vertical frame, and two vertical supports are installed vertically between the ends of the two upper support and the two lower support,

A lower support horizontally installed at the lower ends of the two vertical supports;

And an intermediate support installed between the two vertical supports at a position spaced apart from the uppermost end of the vertical support by a predetermined length.

The lifting ring is formed in the middle of the upper surface of the lifting support which is installed between two intermediate supports formed on the two vertical frames.

The lower frame includes two lower supporters installed in parallel and an auxiliary support provided between the two lower supporters, and a fixing rod is vertically installed between the lifting support and the auxiliary support.

The lifting support is installed in parallel and spaced apart from a plurality of separator modules installed vertically between the upper frame and the lower frame.

The upper frame is composed of two upper supports which are installed in parallel, and the two upper supports are separated by a certain distance so that the hoist can be inserted.

The fixed rod is connected to the lifting ring to distribute the load applied to the lifting ring to the lower support through the auxiliary support.

In addition, the immersion type membrane module unit using the membrane frame maximized the membrane application efficiency according to the present invention,

A top frame including at least one top support for fixing the tops of the plurality of separator modules, a bottom frame including at least one bottom support for fixing the bottoms of the plurality of separator modules, and installed between the top frame and the bottom frame A rectangular parallelepiped separator frame composed of two vertical frames;

A plurality of separator modules installed in rows between the upper frame and the lower frame of the separator frame;

An intermediate support installed at a position spaced a predetermined length downward from an uppermost end of the two vertical supports forming the vertical frame of the separator frame;

A lifting support installed between two intermediate supports installed on the two vertical frames;

A lifting ring formed in the center of the upper surface of the lifting support;

Including a free space formed in the upper portion of the lifting ring so that the hoist connected to the lifting ring can be inserted up and down;

When hoisting the submerged membrane module unit is characterized in that the hoist is inserted into the free space of the membrane frame.

According to the present invention, the lifting ring is installed at a predetermined distance from the top of the separation membrane frame to a lower distance, and an upper portion of the lifting ring forms a free space for the hoist to lift the submerged membrane module unit to correspond to the height of the hoist. It is possible to reduce the height of the floor of the building in which the immersion membrane module unit is installed to reduce the initial investment cost or to deepen the effective depth of the membrane tank, thereby improving the treatment efficiency of the immersion membrane device.

1 is a perspective view showing a preferred embodiment of the membrane frame to maximize the efficiency of the membrane application according to the present invention,
Figure 2 is a side view of the membrane frame to maximize the membrane application efficiency shown in Figure 1,
3 is a perspective view showing an example of a separator module according to the present invention;
4 is a perspective view showing a preferred embodiment of the immersion type membrane module unit according to the present invention,
5 is a side view of the submerged membrane module unit shown in FIG. 4;
6 is a plan view of the immersion membrane module unit shown in FIG.
7 is an explanatory diagram showing a state in which the submerged membrane module unit is lifted according to the present invention;
Figure 8 is a perspective view showing an example of a membrane frame to maximize the efficiency of the separator application according to the prior art,
9 is an explanatory diagram showing a state of lifting the immersion type membrane module unit according to the prior art.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of the membrane frame and the immersion type membrane module unit using the same to maximize the separator application efficiency according to the present invention will be described in detail.

In the detailed description of the invention, it should be noted that the same components or parts represent the same reference numerals as much as possible. In addition, detailed descriptions of related well-known functions or configurations included in the present invention will be omitted in order not to obscure the subject matter of the present invention.

First, Figure 1 is a perspective view showing a preferred embodiment of the membrane frame maximized the efficiency of the membrane application according to the present invention, Figure 2 is a side view of the membrane frame maximized the efficiency of the membrane application shown in FIG.

As shown, the membrane frame 1 to maximize the separator application efficiency of the present invention, which supports a plurality of membrane modules 50, the upper frame 10 and the lower frame 20 and the upper frame ( 10) and two vertical frames 30a and 30b installed vertically between the lower frame 20.

In addition, a plurality of separator modules 50 are installed vertically in a row between the upper frame 10 and the lower frame 20 of the separator frame 1, and are spaced a predetermined length downward from the top of the separator frame 1. There is a lifting ring 35 is installed to hang the hook of the lifting hoist (5). The clearance 37 is formed at a predetermined size so that the lifting hoist 5 can be inserted into an upper end of the membrane frame 1.

Therefore, the membrane frame (1) maximizing the membrane application efficiency according to the present invention, when lifting the submerged membrane module unit in the membrane tank for cleaning the drug, the lifting hoist (5) to the inside of the upper end of the membrane frame (1) Since it can be inserted, it is possible to lower the floor height (H) of the building is installed immersion membrane module unit 100 by a height corresponding to the height of the hoist (5).

More specifically, the separator frame 1 forms a rectangular parallelepiped by combining the upper frame 10, the lower frame 20, and the two vertical frames 30a and 30b.

And the upper frame 10 is composed of one or more upper support (11) for fixing the top of the plurality of membrane module 50 is installed in a row. 1 shows two top supports 11 spaced apart at regular intervals and installed in parallel. At this time, the upper support 11 is made of a hollow hollow metal pipe, the lower surface is formed with a plurality of filtered water connecting pipes 12 connected to the upper head of the plurality of membrane modules 50 at regular intervals. . At this time, between the two upper support (11) constituting the upper frame 10 is spaced at regular intervals so that the lifting hoist (5) can be inserted. In addition, the left and right both ends of the upper frame 10 is opened to allow the lifting hoist 5 to smoothly flow.

Subsequently, the lower frame 20 includes one or more lower supporters 21 for fixing lower ends of the plurality of membrane modules 50 installed in a row. 1 shows two lower supporters 21 spaced at regular intervals and installed in parallel. In addition, a plurality of auxiliary supports 22 are installed to be spaced apart from the lower support 21 by a predetermined interval. In FIG. 1, auxiliary supports 22a and 22c are respectively provided on the outside of the two lower supports 21, and one auxiliary support 22b is installed in parallel between the two lower supports 21.

Subsequently, the vertical frames 30a and 30b fix the upper frame 10 and the lower frame 20, and both ends of the two upper supports 11a and 11b and the two lower supports 21a and 21b. Two vertical supports 31a and 31b disposed between both ends of the lower supporters 32 horizontally installed between the lower ends of the two vertical supports 31a and 31b, and the two vertical supports ( It comprises an intermediate support 33 is installed horizontally at a position away from the top end of the 31a) (31b) by a predetermined length. The vertical frame 30 is composed of a rectangular frame in which two vertical supports 31a and 31b, a lower support 32, and an intermediate support 33 are coupled to each other and open at an upper end thereof.

In addition, the lower frame 20 has two lower supports 32a and 32b horizontally at both ends of two lower supports 21a and 21b and a plurality of auxiliary supports 22a, 22b and 22c. It is installed in a direction and consists of a rectangular frame shape as a whole. At this time, the two lower supporters 22 are made of a hollow metal pipe, and a plurality of injection nozzles for injecting air supplied from the outside are formed at regular intervals on the upper surface thereof. In addition, the upper surface of the lower support 22 is provided with a plurality of fixing parts 24 made of a cylindrical shape so that the lower head of the plurality of membrane modules 50 is inserted into a predetermined length and fixed at regular intervals. In addition, the vertical support 32 and the lower support 33 is also made of a hollow hollow metal pipe, and communicates with the lower support 21 to enable the supply of air supplied from the outside.

The lifting support 34 is horizontally installed between the two intermediate supports 33 provided on the two vertical frames 30a and 30b. And the lifting ring 35 is installed in the middle of the upper surface of the lifting support 34. Preferably, the lifting support 34 is installed in parallel with the upper support 11 or the lower support 12. And the upper portion of the lifting support 34 is formed with a certain clearance 37 so that the hoist 5 used to lift the immersion type membrane module unit 100 can be inserted.

In addition, referring to Figure 2, the fixing rod 39 is vertically installed between the lifting support 34 and the auxiliary support 22b installed in the center of the lower frame 20. Preferably the tip of the fixing rod 39 is integrally connected with the lifting ring (35). Therefore, the load applied to the lifting ring 35 is distributed to the lower frame 20 through the auxiliary support 22b to improve durability of the membrane frame 1.

As described above, the membrane frame 1 of the present invention is formed in the form of a rectangular parallelepiped so that a plurality of membrane modules 50 can be installed therein, and the lifting ring is positioned at a predetermined distance from the top end of the membrane frame 1. 35 is installed. And the upper portion of the lifting meat 35 is formed with a free space 37 to a certain size so that the lifting hoist (5) can be inserted into the inside of the separator frame (1).

3 is a perspective view showing an embodiment of the membrane module 50 installed in the membrane frame 1 of the present invention. As shown, the separation membrane module 50 is a plurality of hollow fiber membrane 51 is bundled in the form of a circular bundle, the top is provided with a cylindrical upper head 52 and the bottom of the cylindrical lower head 53 Is provided. The hollow fiber membrane 51 is open at the top and sealed at the bottom. In addition, a lower portion of the lower head 54 extends a predetermined length downward to form a skirt portion 54.

And Figure 4 is a perspective view showing a preferred embodiment of the immersion membrane module unit according to the invention, Figure 5 is a side view of the immersion membrane module unit shown in Figure 4, Figure 6 is a immersion membrane module unit of Figure 4 Top view.

As shown, the immersed membrane module unit 100 of the present invention is a plurality of membrane modules (inside the membrane frame 1 of the rectangular parallelepiped consisting of the upper frame 10, the lower frame 20 and the vertical frame 30 ( 50) is made vertically. That is, the upper head 52 of the plurality of membrane modules 50 is fixed to the upper support 11 and is connected to the filtrate connecting pipe 12. In addition, the lower head 53 of the plurality of membrane modules 50 is inserted into and fixed to a cylindrical fixing part 24 provided on the upper surface of the lower support 12.

The submerged membrane module unit 100 is provided with a lifting ring 35 at a position separated by a predetermined length from the top of the membrane frame 1 to the bottom thereof. The lifting ring 35 is installed at the center of the upper surface of the lifting support 34 which is horizontally installed between the two vertical frames 30a and 30b. And the upper portion of the lifting support 34 is formed with a free space 37 to a certain size so that the lifting hoist (5) can be inserted.

Hereinafter, the operation of the submerged membrane module unit 100 according to the present invention will be described. 7 is an explanatory diagram showing a state of lifting the immersion type membrane module unit 100 according to the present invention.

As shown, the immersed membrane module unit 100 of the present invention is immersed in the membrane membrane 6 of a constant depth. The immersion membrane module unit 100 immersed in the membrane tank 6 will be contaminated with the membrane over time, so that the immersion membrane module unit 100 is periodically lifted from the membrane tank 6 to clean the drug. There is a need.

On the other hand, the building in which the membrane tank 6 is installed is provided with a lifting means to lift the immersion type membrane module unit 100. For example, the lifting means comprises a monorail 4 mounted on the ceiling of the building and a hoist 5 moving along the monorail 5. And the hoist 5 may be provided with a hook that is connected to the lifting ring 35 through a rope or chain. And the building in which the membrane tank 6 is installed should have a sufficient height (H) to raise the submerged membrane module unit 100 to a certain height.

Referring to FIG. 7 again, when lifting the submerged membrane module unit 100 according to the present invention, the hoist 5 is attached to the lifting ring 35 installed in the submerged membrane module unit 100 immersed in the membrane tank 6. ) Hook to hook. Subsequently, the hoist 5 is operated to wind the rope or chain to transfer the submerged membrane module unit 100 upward.

Subsequently, when the submerged membrane module unit 100 completely leaves the membrane tank 6, the hoist 5 is transferred horizontally along the monorail 4 to move the submerged membrane module unit 100 into the cleaning tank 7. Put it down. When a predetermined time is reached, the immersion type membrane module unit 100 is lifted again from the cleaning tank 7 and immersed in the separation tank 6.

At this time, the immersion membrane module unit 100 according to the present invention is provided with a lifting ring 35 at a position separated by a predetermined length from the top of the membrane frame 1 to the bottom, the upper portion of the lifting ring 35 Since the free space 37 into which the hoist 5 can be inserted is formed, when the immersion type membrane module unit 100 is transferred upward, the hoist 5 moves into the upper end of the immersion type membrane module unit 100. Will be inserted.

As such, when the hoist 5 is inserted into the submerged membrane module unit 100, the floor height H of the building in which the submerged membrane module unit 100 is installed may be lowered. In addition, the lower the floor height (H) of the building can reduce the initial investment costs. In addition, even when the floor height H of the building is maintained as it is, the effective depth D of the separation membrane tank 6 can be further deepened, thereby improving the treatment efficiency of the immersion type membrane apparatus.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the invention without departing from the spirit and scope of the invention described in the claims below. I can understand that you can.

1: separator frame 5: hoist
6: membrane 10: top frame
11: upper support 12: filtrate connector
20: lower frame 21: lower support
22: auxiliary support 30: vertical frame
31: vertical support 32: lower support
33: intermediate support 34: lifting support
35: lift ring 37: free space
50: membrane module 52: upper head
53: lower head 56: filtered water outlet
57: air inlet

Claims (8)

In the membrane frame for supporting a plurality of membrane modules,
An upper frame including one or more upper supports to fix the upper ends of the plurality of membrane modules;
A lower frame including one or more lower supports for fixing lower ends of the plurality of membrane modules;
A vertical frame including a plurality of vertical supports installed between the upper frame and the lower frame;
Two intermediate supports spaced downward from the upper frame by a predetermined length and horizontally installed between two vertical supports of the vertical frame;
A lifting support horizontally installed between the two intermediate supports; and
It is installed in the middle of the upper surface of the lifting support is a lifting ring located in the lower portion of the upper frame; including,
The upper portion of the lifting ring is formed with a free space of a predetermined size so that the hoist connected to the lifting ring can be inserted up and down, the hoist is inserted into the lower portion of the upper frame when lifting the separator frame. Separator frame for maximum efficiency of membrane application. delete delete According to claim 1,
The lower frame includes two lower supports which are installed in parallel and an auxiliary support which is installed between the two lower supports, wherein a fixing rod is vertically installed between the lifting support and the auxiliary support. Separator frame for maximum efficiency of membrane application. The method of claim 4, wherein
The lifting support is separated from the plurality of separator modules installed vertically between the upper frame and the lower frame spaced apart from each other at a predetermined interval, the separation membrane frame maximizing the separation membrane application efficiency. According to claim 1,
The upper frame is made of two upper support that is installed in parallel, the separation membrane frame to maximize the separation efficiency of the separation membrane, characterized in that the predetermined distance apart so that the hoist can be inserted between the two upper support. The method of claim 4, wherein
The fixing rod is connected to the lifting ring to distribute the load applied to the lifting ring to the lower support through the auxiliary support, the membrane frame to maximize the membrane application efficiency. A top frame including at least one top support for fixing the tops of the plurality of separator modules, a bottom frame including at least one bottom support for fixing the bottoms of the plurality of separator modules, and installed between the top frame and the bottom frame A rectangular parallelepiped separator frame composed of a vertical frame including a plurality of vertical supports;
A plurality of separator modules installed in rows between the upper frame and the lower frame of the separator frame;
Two intermediate supports spaced downward from the upper frame by a predetermined length and horizontally installed on the vertical frame;
A lifting support horizontally installed between the two intermediate supports; and
It is installed in the middle of the upper surface of the lifting support is a lifting ring located in the lower portion of the upper frame; including,
The upper portion of the lifting ring is formed with a free space of a predetermined size so that the hoist connected to the lifting ring can be inserted up and down, the hoist is inserted into the lower portion of the upper frame when lifting the separator frame. Separator frame for maximum efficiency of membrane application.

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