KR200368690Y1 - Submergible flat sheet membrane filtering apparatus - Google Patents

Abstract

The disclosed submerged flat membrane filtration apparatus includes a flat membrane member having a mesh spacer and a membrane surrounding the spacer; A pair of supports having a coupling slit into which both side edge portions of the flat membrane member are fitted, and a pair of cap members connected to the pair of supports and provided with a filtrate discharge port on one side thereof. When using the immersion type flat membrane filtration device having such a configuration, it is not necessary to put the prepared filtration device in a separate cage or the like, so that the filtration device can be put directly into the filtration reactor, so that the volume can be reduced, thereby reducing the installation space of the device and installing work. It also becomes easy. In addition, since two filtrate discharge ports are used during the filtration operation, a large flow path of the filtrate is formed, thereby reducing the pressure loss, and thus, an improvement in the permeation efficiency can be expected. In addition, depending on the necessity, it is possible to make a large number of flat membrane members by connecting them, or to make them smaller, so that the size of the product can be freely selected.

Description

Submergible flat sheet membrane filtering apparatus

The present invention relates to an immersion flat membrane filtration device used in the filtering field.

In general, the immersion type flat membrane filtration device is a device for performing filtration in the state immersed in the treated water for the purification treatment of domestic sewage, wastewater, livestock wastewater, leachate, etc., as shown in Figure 1, the module frame (1) A plurality of flat membrane modules 10 in the structure is supported. That is, a plurality of slits 1a are formed in the module frame 1 so that the flat membrane module 10 is sandwiched and supported by the slits 1a. As shown in FIG. 2, the flat membrane module 10 includes a pair of membranes 11 and a screen support 12 that are symmetrically arranged with spacers 13 interposed therebetween, and a support frame to which their edges are joined. 14), cap 15, and the like. In addition, since the submerged flat membrane filtration device is used in combination with an aeration process of removing foreign matters stuck to the surface of the membrane 11, sufficient space is ensured to smoothly flow bubbles between the flat membrane modules 10. Should be. Reference numeral 1b denotes a hole formed in the module frame 1 so that bubbles generated under the module frame 1 can pass through the surface of the membrane 11 in accordance with an acid process. Reference numeral 15a denotes a filtrate discharge port provided in the cap 15 so that the filtrate filtered through the membrane 11 exits.

When the submerged flat membrane device is installed in the reaction tank 3 for the filtration operation, the seating frame 4 prepared in the reaction tank 3 by being inserted into a separate stainless cage 2 as shown in FIG. 3 and then lifted by a pulley or the like. Settled on. Subsequently, the filtration operation is performed while the diffuser 5 is operated, and the filtrate which is filtered into the membrane 11 is sent to a predetermined position along the filtrate discharge port 15a of the cap 15.

However, in order to use such a conventional submerged flat membrane filtration apparatus, the flat membrane module 10 should be inserted into the cage frame 2 as described above after being inserted into the module frame 1, and the seating frame in the reactor 3 again. Since installation in (4) has its disadvantages, the installation is quite complicated. In addition, since the filtrate passing through the membrane 11 exits through the single port 15a, the permeation efficiency may be lowered and the pressure loss is also increased.

The present invention has been made to solve the above disadvantages, and an object of the present invention is to provide an immersion type flat membrane filtration device whose structure is improved so that the installation into the reactor is simple and the permeation efficiency is improved.

1 is a view showing a conventional submerged flat membrane filtration device,

2 is a cross-sectional view taken along the line II-II of FIG. 1;

Figure 3 is a view showing a process of installing the immersion type flat membrane filtration device of Figure 1 in the reaction vessel,

4 is a view showing an immersion type flat membrane filtration device according to a first embodiment of the present invention,

5 is a cross-sectional view taken along the line VV of FIG. 4;

FIG. 6 is an exploded perspective view showing a structure of a combination set consisting of a flat membrane member, a support, a cap, and the like among the submerged flat membrane filtration devices shown in FIG. 4;

7 is a view showing a coupling portion of the flat membrane member and the support of the coupling set shown in FIG.

8 is a view showing an immersion type flat membrane filtration device according to a second embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

100 ... Immersion flat membrane filtration device 110 ... Flat membrane member

111 membrane 112 screen support

113 ... mesh spacer 114 ... adhesive molding

120,220 ... support 130 ... cap member

131 Filtrate discharge port 160 ...

The submerged flat membrane filtration apparatus of the present invention for achieving the above object comprises a flat membrane member having a mesh spacer and a membrane surrounding the spacer; A pair of supports provided with coupling slits into which both edge portions of the flat membrane member are fitted; And a pair of cap members connected to the pair of supports and provided with a filtrate discharge port at one side thereof.

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

Figure 4 shows the submerged flat membrane filtration device 100 according to an embodiment of the present invention.

As shown, the immersion type flat membrane filtration device 100 of the present embodiment, a plurality of coupling sets consisting of the flat membrane member 110 and the support 120 and the cap member 130 and the upper and lower cap 115 is connected to the hook portion ( 132 and 123 has a structure that is integrally fastened by the connecting bolt 101 and the nut (102). Reference numeral 160 serves as a diffuser unit to blow foreign air through the diffuser 161 on the surface of the flat membrane member 110 to drop foreign matter. The detailed structure of the diffuser unit 160 will be described later.

Looking at each of the combination set, the flat membrane member 110 and a pair of supports 120, a pair of cap members 130 coupled to the support 120, and the upper and lower ends of the flat membrane member 110 as described above The upper and lower caps 115 are coupled to each other, and the flat membrane member 110 in which substantially filtration is performed may include a spacer 113a, which is a mesh, as shown in FIG. 5, and the membrane 111 and the screen support 112. ) Has a U-shaped structure. That is, the membrane 111 and the screen support 112 are folded and laid out, and then the spacer 113a is placed thereon, and the membrane 111 and the screen support 112 are folded in half. This results in one end being blocked and the other end being open. The open end is molded with an adhesive 114 to block it. Only one flat membrane member 110 may be provided per coupling set. However, it is preferable to stack a plurality of flat membrane members 110 in a set as shown in the drawing in order to increase the filtration efficiency. At this time, the mesh spacer 113b is also provided between the flat membrane members 110. When bubbles generated from the air diffuser unit 160 pass through the mesh spacer 113b, the bubbles are broken finely and turbulence is promoted, so that foreign matters stuck to the surface of the membrane 111 can be more effectively removed. To this end, the air blowing nozzle hole 161a of the diffuser 160 is formed to match the mesh spacer 113b between the flat membrane members 110, and the upper and lower caps 115 The air slit 115a is formed in accordance with the position of the mesh spacer 113b. Therefore, bubbles generated by the air blown out through the nozzle hole 161a flow into the air slit 115a of the lower cap 115, and then the mesh spacer 113b between the flat membrane members 110 is opened. After passing through and finely crushed to clean the surface of the membrane 111 and exit through the air slit 115a of the upper cap 115. At this time, the guide wing 162 of the diffuser 160 guides the air bubbles well to the flat membrane member 110 without being scattered to other places.

Such flat membrane members 110 are inserted into the coupling slit 121 of the support 120 in the state in which the ends are bonded to each other with the adhesive 114 as shown in FIGS. 6 and 7 and the coupling slit 121. Also fixed to the inner wall with an adhesive 114, the fabric pad 116 is installed on the corresponding portion of the flat membrane member 110 in order to prevent damage to the contact with the inner wall of the coupling slit 121 during the insertion and bonding process. It is. The fabric pad 116 can be attached to the membrane 111 by sewing, thereby preventing damage due to direct contact between the membrane 111 and the inner wall of the coupling slit 121, strengthening adhesion, and concentrating the flat membrane. . On the other hand, the cap member 130 is provided with a filtrate discharge port 131 is coupled to the upper end of the pair of supports 120, the flat membrane member 110 is coupled. The filtrate discharge port 131 is in communication with the hollow portion 122 connected to the coupling slit 121 of the support 120, the filtrate passing through the membrane 111 flows into the hollow portion 122 Out of the filtrate discharge port (131).

Therefore, the immersion type flat membrane filtration apparatus 100 having such a structure prepares the flat membrane member 110 formed of the mesh spacer 113, the membrane 111, and the screen support 112, and then combines the slits of the support 120 ( 121) to create a combined set by inserting the filtration device as it is just put into the filtration reactor as it takes up a little installation space and easy installation work. The diffuser 161 of the diffuser unit 160 may be made integral with the filtration device 100, or may be installed in the reactor and the filtration device 100 may be installed at the position.

When the immersion type flat membrane filtration device 100 is placed in a reaction tank and the filtration unit 160 is operated to start the filtration operation, the filtrate meshes through the membrane 111 and the screen support 112 of the flat membrane member 110. It enters into the sieve spacer 113, continues to move toward the hollow portion 122, and then exits to the filtrate discharge port 131. At this time, since the filtrate discharge port 131 is provided in each of the pair of cap members 130 as described above, the flow path becomes wider than the structure previously discharged to a single port, thereby reducing pressure loss and improving permeation efficiency. do.

Therefore, according to the immersion type flat membrane filtration apparatus according to the present embodiment, it is easy to install and the effect of improving the permeation efficiency of the membrane during filtration can be obtained.

Next, Figure 8 shows an immersion type flat membrane filtration device according to a second embodiment of the present invention.

The flat membrane member 110, the cap member 130, the diffuser unit 160, and the like in this embodiment are substantially the same as those of the first embodiment described above, and the support 220 is configured differently.

That is, in the present embodiment, by making a plurality of coupling slits 221 on the support 220, each of the coupling slits 221 is inserted into the flat membrane member 110 supported by the upper and lower caps 115 described above. In other words, in the first embodiment described above, the apparatus is configured by fastening a plurality of coupling sets composed of the flat membrane members 110 and the individual support bodies 120 with the connecting bolt 101 and the nut 102. In the embodiment, by making a plurality of coupling slits 221 on the integrated support 220 to install the flat member 110, it is possible to omit a separate fastening operation.

In this configuration, a plurality of flat membrane members 110 including the mesh spacer 113, the membrane 111, and the screen support 112 are prepared and inserted into each coupling slit 221 of the support 220. This is completed, making the production easier and more convenient, and also just put the filtration device in the reaction tank for filtration as it takes up a little installation space and easy installation work.

Therefore, the submerged flat membrane filtration apparatus according to the present embodiment is also easy to manufacture and install, and provides an effect of improving the permeation efficiency of the membrane during filtration.

As described above, the submerged flat membrane filtration apparatus of the present invention provides the following effects.

First, it is not necessary to put the prepared filtration device in a separate cage, etc., as it is just put into the filtration reactor, it is possible to reduce the installation space of the device and facilitate the installation work.

Second, since there is no need to use a fixed frame, in some cases it can be made large by connecting a plurality of flat membrane members, on the contrary it can be made small, the product size is free to choose.

Third, because the U-folded membranes are stacked together to form a single bond set, the density of the membranes per unit volume can be increased, thereby significantly reducing the volume compared to the conventional filtration structure, thus reducing the size of the reactor. have.

Fourth, since two filtrate discharge ports are used, the flow path of the filtrate is increased, thereby reducing the pressure loss during delivery, thereby improving permeation efficiency.

Fifth, since bubbles generated from the acidic unit pass through the mesh spacer, turbulence is promoted to more effectively remove the foreign matter adhering to the membrane surface.

It is understood that the invention is not limited to that described above and illustrated in the drawings and that many more modifications and variations are possible within the scope of the following claims.

Claims (9)

A flat membrane member having a mesh spacer and a membrane surrounding the spacer; A pair of supports provided with coupling slits into which both edge portions of the flat membrane member are fitted; And a pair of cap members connected to the pair of supports and provided with a filtrate discharge port at one side thereof. The method of claim 1, Immersion type flat membrane filtration device, characterized in that further provided with an air diffuser unit for blowing air to the surface of the flat membrane member. The method of claim 2, The diffuser unit includes an diffuser formed with a nozzle hole for ejecting air, and an induction wing portion provided on an outer circumferential surface of the diffuser to collect air ejected through the nozzle hole toward the flat membrane member. Device. The method of claim 1, Immersion type flat membrane filtration device characterized in that the screen support is interposed between the mesh spacer and the membrane of the flat membrane member. The method of claim 1, Immersion type flat membrane filtration device, characterized in that the fabric pad is installed in a portion to contact the inner wall of the coupling slit of the support of the membrane so that the flat membrane is focused. The method of claim 1, Immersion type flat membrane filtration device, characterized in that the plurality of flat membrane members are fitted to the coupling slit in a stacked state with a mesh spacer interposed therebetween. The method of claim 6, The upper and lower caps are coupled to upper and lower ends of the plurality of flat membrane members, and further provided with upper and lower caps formed with a plurality of air slits through which air can pass, corresponding to the mesh spacer positions between the flat membrane members. Flat membrane filtration device. The method of claim 7, wherein Immersion type flat membrane filtration device characterized in that the plurality of coupling sets including the support, the cap member and the flat membrane member and the upper and lower caps are integrally fastened. The method of claim 7, wherein The support is provided with a plurality of coupling slits, immersion type flat membrane filtration device, characterized in that the plurality of coupling sets including the cap member, the flat membrane member and the upper and lower caps to be fitted to each coupling slit.