KR200379549Y1 - Module of flat membrane for immersion type - Google Patents

Abstract

The present invention consists of a rigid film with a simple shape and a member for performing the flow path guide function, and thus the manufacturing cost is low, and if necessary, the flat membrane may be used because the multiple layers of the flow path guide function can be used. It not only reduces the resistance of the treated water flowing into the support, but also provides the function of the flow path for the treated water to flow into the catchment port, and also increases the membrane filling density by minimizing the thickness of the support, thereby reducing the installation space. And a submerged flat membrane module having a large water treatment capacity.

According to the present invention, the support 310 and the flat membrane 330 are laminated on both sides of the support 310, respectively, wherein the support 310 includes a hard thin film 311 and the hard thin film 311. ), Each of which is laminated on both sides, and has a flow path guide member 312 having a mesh structure so that the treated water flowing in through the flat membrane 330 flows upward, at least one layer or more layers.

Description

Module of flat membrane for immersion type

The present invention relates to an immersion type flat membrane module provided in the water treatment apparatus, comprising a support body provided in the immersion flat membrane module of a simple thin shape and a member for performing the flow path guide function, the manufacturing cost is low, if necessary Since the member that performs the flow guide function can be used in multiple layers, it not only reduces the resistance of the treated water flowing through the flat membrane to the support but also provides the function of the flow path for the treated water to flow into the water collecting port. In addition, the present invention relates to an immersion type flat membrane module having a relatively small installation space and a large water treatment capability by increasing the membrane filling density by minimizing the thickness of the support.

Immersion type water treatment equipment is a device for treating sewage, sewage and agricultural wastewater including livestock waste, livestock waste, industrial wastewater, etc. using a membrane. It is a phase that separates only components, and membrane separation is a separation method that separates a substance in molecular state by using the physical and chemical properties of the membrane.

Membranes are classified into porous membranes, microporous membranes, and homogeneous membranes according to their structure, and are divided into microfiltration membranes, ultrafiltration membranes, reverse osmosis membranes, gas separation membranes, pervaporation membranes, and the like according to their use. Such a membrane is difficult to be used alone, and the membrane is used so that the membrane can be used in a separation process.

In addition, membranes are classified into flat type modules, tubular modules, and hollow fiber membrane modules according to their shape. Among them, two types of hollow fiber membrane modules are pressurized type and suction type (immersion type). It is used as a pressurized type.

Here, the hollow fiber membrane module and the tubular module used in the pressurization type have to maintain the linear velocity within the membrane to reduce the contamination of the membrane.

In addition, the hollow fiber membrane module used as the suction type is subjected to water treatment by hitting the air bubbles on the surface of the membrane in water, at this time, there is a problem that the membrane is entangled with the fibrous contaminants and the membrane itself is damaged.

As an alternative to this, a flat plate module used as a suction type refers to a membrane formed on a plane or a sheet, which not only adheres contaminants well but also facilitates the removal of contaminants and prevents the membranes from being operated. There is little fear of being damaged and this has the advantage of lower operating costs.

However, unlike the hollow fiber membrane module, the flat plate module used as the suction type cannot be washed through the backwash. Therefore, the flat plate module used as the suction type has a membrane filling rate, allowable raw water turbidity concentration, physical cleaning resistance, and removal efficiency. It should be used with reference to the same conditions.

In addition, the structure and strength of the membrane itself also greatly affects the lifespan and throughput of the flat membrane module. Therefore, consideration should be given to the design and structure of the flat membrane module.

The conventional submerged flat membrane module 100, which is pre-registered in the Korean Utility Model with reference to FIG. 1 (registration number; 20-0241540), has a non-woven fabric for distance separation on both sides of the support 110 with respect to the support 110. 120 and the flat membrane 130 are sequentially stacked.

The support 110 is a plate-shaped member having a predetermined thickness. A plurality of partitions 111 are embedded in the vertical direction so that the flow of the treated water flows upward, and a flow passage 113 is formed, and the treated water flows on both sides. A plurality of inflow holes 112 are formed between each partition wall 111 formed therein.

The main reason why the distance-separated nonwoven fabric 120 is laminated is to reduce the resistance caused by the support 110 and the flat membrane 130 contacted by suction pressure when the treated water passing through the membrane flows into the flow path inside the support 110. For sake.

The distance separation nonwoven fabric 120 is mainly used as a spacer of a RO or NF spiral wound module.

In addition, although the conventional submerged flat membrane module 100 is not shown, there is a channel for sealing on the upper, lower, left, and right sides of the submerged flat membrane module 100, and the treated water introduced when driving the suction pump may be discharged to the outside. In the upper channel, a catch port connected to the channel is connected to the suction pump.

As described above, the conventional water treatment device equipped with the submerged flat membrane module 100 has a channel connected to the upper, lower, left, and right sides of the submerged flat membrane module 100 and a sump connected to the upper channel, and a suction pump connected to the sump. Water contaminated by the driving of the purified water is passed through the flat membrane 130, the purified water is passed through the distance-separated nonwoven fabric 120 is introduced into the inlet hole 112 of the support 110, The introduced treated water flows to the upper portion of the submerged flat membrane module 100 through the plurality of flow passages 113 formed by the plurality of partitions 111 formed in the vertical direction, and the flowed treated water passes through the sump of the upper channel. Through the outside.

In addition, referring to Figures 2 and 3, the other conventional submerged flat membrane module 200 pre-registered (registration number; 20-0285695) in the Republic of Korea Utility Model, both sides of the support 210 around the support 210 Each of the non-woven fabric 220 and the flat membrane 230 for distance separation are sequentially stacked, but a plurality of partitions 211 are formed in a horizontal direction in the support 210, and a separator is shown in the center. And a plurality of outlet portions 214 having a predetermined size are formed at each side between the barrier ribs 211 formed in the horizontal direction on both sides thereof, and a slit shape is formed between the barrier ribs 211 formed therein on both planes. A plurality of inlets 212 are formed.

Another conventional flat membrane module 200 having such a structure is that the treated water introduced through the plurality of inlets 212 by the driving of a suction pump (not shown) is split in half by a separator. Of the treated water flows to both sides along a plurality of horizontal flow paths (not shown) formed by the partitions installed in the horizontal direction, and each of the treated water flowing to both sides is an outlet formed on both sides of the support 210. Flowing upward (vertical) through 214 is discharged to the outside through the catch 215.

However, the support of each of the prior art immersion type flat membrane module has a complex structure in which a partition is formed so that the treated water flowing through the flat membrane flows toward the catchment. For this reason, when manufacturing an article by injection molding, it is difficult to mold the article and there is a problem that the manufacturing cost increases.

In addition, since the treatment water is discharged to the outside through the flow path formed between the partition walls inside the support when the treated water is introduced by the suction pump, the thickness of the support should be manufactured to have a predetermined size or more to form the flow path. As a result, the thickness of the flat membrane module becomes thicker, and thus the film filling density of the flat membrane module structure is lowered, resulting in a relatively large installation space and a limitation in water treatment capacity.

In addition, the distance between the flat membrane and the support by the non-woven fabric for distance separation, but the contact between the support and the flat membrane caused by the suction pressure during use, causing a great resistance until the treated water passing through the flat membrane until entering the flow path of the support There is a problem. In order to solve such a problem, the power of the suction pump must be increased, which also causes a problem that power consumption is consumed a lot.

The present invention was devised to solve the above problems, and the object of the present invention is to provide a support for the flow guide member having a rigid thin film and a net structure having a simple shape as well as low manufacturing cost and the thickness of the thin support By increasing the membrane filling density to provide a submerged flat membrane module having a relatively small installation space and large water treatment capacity.

Another object of the present invention is to configure the support with a rigid thin film having a simple shape and a flow path guide member having a network structure, thereby separating the resistance between the flat membrane and the support and reducing the resistance of the treated water. It is to provide an immersion type flat membrane module that performs a combination of the flow path guide function to control the flow toward the catchment.

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

Figure 4 is an exploded perspective view of a laminated structure of the immersion type flat membrane module of the present invention, Figure 5 is an exploded perspective view of the laminated structure of the support of the components of Figure 4, Figure 6 is a configuration of Figure 4 It is a perspective view of the flow path guide member which is an element, FIG. 7 is a front view which shows the laminated | stacked between the flow path guide members which are a component of this invention, FIG. 8 is AA sectional drawing of FIG.

As shown, the subject innovation is a support body 310, the flat film 330 is laminated on both sides of the support body 310, respectively, the support body 310 is a rigid thin film 311 and the At least one or more flow path guide members 312 having a network structure are stacked to be disposed on both surfaces of the rigid thin film 311 so that the treated water flowing through the flat membrane 330 flows upward.

In the mesh structure of the flow guide member 312, a blade member 312a is disposed at predetermined intervals, and the string member 312b is diagonally bonded at predetermined intervals on the blade member 312a disposed at each predetermined interval. A plurality of flow paths 313 are fixed to each other between the layers of the blade members 312a and the layers of the string members 312b.

The number of laminated layers of the flow path guide member 312 is 1 to 10 layers.

In addition, although the flow guide member 312 is illustrated as a circular rod on the drawing, it may be used in various shapes such as bars or hexagonal bars.

When overlapping between the flow path guide member 312, the blade member 312c and the string member 312b between the flow path guide member 312 which are in contact with each other are alternately disposed.

9 is a front view showing that the fixing means for providing the flat membrane module of the present invention to be fixed to the water treatment device is combined.

As shown, the flat membrane module of the present invention is fixed by four channels (400) to be fixed to the immersion type water treatment device. Here, the catchment port 500 is connected to the upper channel 400, and the connected catchment port 500 is connected to the suction pump.

10 is a front view showing another embodiment of the present invention, the network structure of the flow guide member of the present invention is a cross-shaped structure.

As shown in the drawing, the mesh structure of the flow guide member 312 has a blade member 312c disposed at predetermined intervals, and the string member 312d is disposed at predetermined intervals on the blade member 312c disposed at predetermined intervals. Each of the plurality of flow paths 313 is formed between the layers of the blade member 312c and the layers of the plurality of seed members 312d by being fixed to each other by a cross.

It describes the operation of the present invention configured as described above.

Immersion-type flat membrane module 300 according to the present invention is the water contaminated by the driving of the suction pump (not shown) is passed through the flat membrane 330 is purified, the purified water is introduced into the support 310 At this time, the support 310 is laminated to the flow path guide member 312 having at least one or more layers of the network structure on the rigid thin film 311.

Here, in the mesh structure of the flow guide member 312, the blade member 312a is disposed at predetermined intervals, and the string member 312b is fixed to be bonded at a predetermined interval on the blade member 312a disposed at predetermined intervals. Since the flow guide member 312 has its own thickness.

As a result, the flow guide member 312 reduces the resistance of the treated water introduced by spaced apart between the flat membrane 330 and the support 310, and at the same time a plurality of seed members on the plurality of blade members 312a As the 312b is fixed diagonally, the treated water flows to the water collecting port 500 through various flow paths 313 formed between the layers of the plurality of blade members 312a and the layers of the plurality of string members 312b. It also performs a combination of functions.

For this reason, the rigid thin film 311 which comprises the support body 310 can be manufactured by the thin film which has a simple shape, and it is expensive by installing a some partition and a plurality of inflow parts, etc. in a support body in order to form the conventional flow path. In addition to lowering the manufacturing cost of the membrane, the thickness of the thin support increases the membrane filling density, thereby providing a relatively small installation space and a large water treatment capacity when installed in the water treatment apparatus.

When the flow path guide member 312 stacked on the thin film 311 is stacked in multiple layers, the blade member between the flow path guide members 312 abutting each other among the plurality of overlapped flow path guide members 312. The 312c and the string member 312b are alternately arranged to secure more flow paths 313 to smoothly flow the treated water.

To this end, the flow path guide member 312 has two kinds of flow path guide members 312, in which the blade member 312c and the string member 312b disposed on the flow guide member 312 of the same standard are crossed with each other. Produce and provide.

As such, the treated water introduced into the flow path guide member 312 flows upwardly of the support 310 by suction pressure, flows into the water collecting port 500, and is discharged to the outside.

In another embodiment of the present invention, with reference to FIG. 10, the string member 312d is bonded to the cross member at predetermined intervals on the blade members 312c disposed at predetermined intervals to form a plurality of flow paths 313. Since the function is the same as the above, it is omitted here.

As described above, the present invention can provide the support as a flow guide member having a rigid thin film and a net structure having a simple shape, and the manufacturing cost is low, and the film filling density is increased due to the thickness of the thin support. It has the effect of having small installation space and big water treatment capacity.

In addition, since the support body is provided as a flow guide member having a rigid thin film and a net structure having a simple shape, the space is separated from the flat membrane and the support, thereby reducing the resistance of the inflowing water. It is also effective to carry out the flow guidance function to control flow.

1 is an exploded perspective view illustrating a laminated structure of a conventional immersion flat membrane module;

2 is an exploded perspective view illustrating a laminated structure of another conventional submerged flat membrane module;

3 is a front view showing the support of the components of FIG.

4 is an exploded perspective view of a laminated structure of the submerged flat membrane module of the present invention;

5 is an exploded perspective view illustrating a stacked structure of a support of the components of FIG. 2;

FIG. 6 is a perspective view of a flow guide member that is a component of FIG. 4; FIG.

7 is a front view showing the laminated between the flow guide member that is a component of the present invention,

8 is a cross-sectional view taken along line AA of FIG.

9 is a front view showing that the fixing means for providing the flat membrane module of the present invention to be fixed to the water treatment device is coupled,

10 is a front view showing another embodiment of the present invention, the network structure of the flow guide member of the present invention is a cross-shaped structure.

<Code Description of Main Parts of Drawing>

100,200,300: flat membrane module 110,210,310: support

111,211: bulkhead 112,314: inlet hole

113,313: Euro 120: Non-woven fabric for distance separation

130,230,330 flat membrane 212 inlet

214: outlet 215,500: catchment

311 thin film 312 flow guide member

312a, 312c: blade member 312b, 312d: seed member

400: channel

Claims (6)

The support body 310, Laminating the flat membrane 330 on both sides of the support 310, respectively, The support 310 has a mesh structure such that the hard thin film 311 and the hard thin film 311 are respectively laminated on both surfaces thereof so that the treated water flowing through the flat membrane 330 flows upward. Immersion type flat membrane module, characterized in that the flow path guide member 312 is laminated at least one or more layers. The mesh structure of the flow path guide member 312 is provided with a blade member 312a at predetermined intervals, and a seed line member 312b is predetermined on the blade member 312a disposed at predetermined intervals. Immersion type flat membrane module, characterized in that a plurality of flow paths (313) are formed between the layers on the blade member (312a) and the plurality of layers of the string member (312b) is fixed to be bonded at every interval. The immersion type flat membrane module according to claim 2, wherein the number of laminated layers of the flow path guide member (312) is 1 to 10 layers. 3. The immersion type flat membrane of claim 2, wherein the blade members 312c and the string members 312b between the flow path guide members 312 which are in contact with each other when overlapping the flow path guide members 312 are alternately disposed. module. The net structure of the flow path guide member 312 is provided with a blade member 312c at predetermined intervals, and a seed line member 312d is predetermined on the blade member 312c disposed at predetermined intervals. Immersion-type flat membrane module, characterized in that a plurality of flow paths (313) is formed between each of the layers on the blade member (312c) and the layers of the plurality of string members (312d) are bonded and fixed in a crisscross every interval. The immersion type flat membrane module according to claim 1, wherein the flow guide member (312) uses any one of a rod and a bar.