KR102055679B1 - Membrane unit for immersion type membrane separation system - Google Patents

Abstract

The present invention provides a membrane unit for an immersion type membrane separation device, comprising: a pair of vertical frames erected on a floor; A left upper horizontal frame, a right upper horizontal frame, a lower left horizontal frame, and a lower right horizontal frame connecting the vertical frames; A lifting bar having a pair of bar brackets protruded to an upper side of the vertical frame to be opposed to each other at a center of the upper part of the vertical frame, coupled between the pair of bar brackets, and having a citation ring formed at a center thereof; A pair of header brackets are formed to protrude to the upper side of the vertical frame to be opposed to each other on the upper side of the vertical frame, coupled between the pair of header bracket, the flow path is formed inside, the suction header formed with a suction pipe on one side ; A left upper module holder coupled to the suction header bottom and having a plurality of holes formed at equal intervals; An upper right module fixing unit coupled to the upper right upper frame and having a plurality of holes at equal intervals; A lower left module fixing unit coupled to an upper surface of the lower left horizontal frame and having a plurality of holes at equal intervals; A lower right module holder coupled to an upper surface of the lower right horizontal frame and having a plurality of holes formed at equal intervals; An upper header is coupled between the upper left module holder and the upper right module holder, and the lower header is a hollow fiber membrane module coupled between the lower left module holder and the lower right module holder; Immersible membrane separation apparatus comprising a; diffuser coupled to the bottom of the transverse frame is formed with a plurality of air holes and connected to an external air pump to aeration compressed air through the air holes A lightweight separator unit for a system.

Description

Membrane unit for immersion type membrane separation system

The present invention relates to a membrane unit, and more particularly to a lightweight membrane unit for an immersion type membrane separation device that is lightweight and simple in structure.

Membrane unit for immersion membrane separation device is a device that purifies waste water or sewage by filtering and filtering out foreign pollutants and microorganisms and suspended solids contained in waste water or sewage by biological process or physicochemical process.

Separation membranes generally use hollow fiber membranes, and hollow fiber membrane modules are used to bundle hundreds to thousands of hollow fiber membranes in order to increase and integrate processing capacity within a limited space.

In order to reduce the weight of the membrane unit, the choice of materials is important, but it is necessary to change the structure so that the components constituting the membrane unit are properly positioned without mutual interference, and in particular, the interference of other components in the space where the hollow fiber membrane module is installed must be eliminated. do. Here, the other components refer to the suction header or the position of the diffuser.

The hollow fiber membrane module is formed by coupling the hollow fiber membrane between the spaced up and down, the difference between the interference between the different components according to the formation position or shape of the connector in communication with the flow path inside the header, the direction of the connector is projected.

In this way, the impact on the weight reduction is large according to the organic relationship such as the position and shape of each component constituting the separator unit, and also has a great effect on the ease of manufacturing process and the structure simplicity. Until now, only the functionality of the separator unit has been focused. There was a problem that does not consider the weight reduction and ease of manufacturing process, which is important in terms of commercial competitiveness of the device.

The diffuser serves to discharge compressed air to prevent micropores from clogging when purified water is sucked through the hollow fiber membrane module.As the intermittent aeration, foreign matter flows through the air hole at the time of no aeration, Among them, heavy ones such as sand sink and accumulate inside the diffuser, causing a decrease in the function of the diffuser, and in particular, foreign matter such as sand is discharged with air during aeration, which acts like a bullet and damages the hollow fiber membrane. However, when opening only when aeration such as valves or nozzles to prevent foreign substances from entering the air hole of the diffuser, the configuration is complicated, the manufacturing cost increases, but there are also problems that frequently occur.

Republic of Korea Patent Publication No. 10-2012-133601 (2012.12.11) Republic of Korea Patent Publication No. 10-2005-116566 (2005.12.13) Republic of Korea Patent Publication No. 10-2006-7874 (2006.01.26) Republic of Korea Patent No. 10-1554924 (2015.09.16)

In order to solve the problems described above, the present invention changes the shape of a specific component and greatly changes the structure and shape of the hollow fiber membrane module so as to be lightweight and simplified, and foreign substances having a large specific gravity flow into the discharge port of the diffuser. To provide a lightweight membrane unit for an immersion type membrane separation device that can be released immediately.

In order to achieve the above object, the present invention provides a membrane unit for an immersion type membrane separation device, comprising: a pair of vertical frames erected on a floor; A left upper horizontal frame, a right upper horizontal frame, a lower left horizontal frame, and a lower right horizontal frame connecting the vertical frames; A lifting bar having a pair of bar brackets protruded to an upper side of the vertical frame to be opposed to each other at a center of the upper part of the vertical frame, coupled between the pair of bar brackets, and having a citation ring formed at a center thereof; A pair of header brackets are formed to protrude to the upper side of the vertical frame to be opposed to each other on the upper side of the vertical frame, coupled between the pair of header bracket, the flow path is formed inside, the suction header formed with a suction pipe on one side ; A left upper module holder coupled to the suction header bottom and having a plurality of holes formed at equal intervals; An upper right module fixing unit coupled to the upper right upper frame and having a plurality of holes at equal intervals; A lower left module fixing unit coupled to an upper surface of the lower left horizontal frame and having a plurality of holes at equal intervals; A lower right module holder coupled to an upper surface of the lower right horizontal frame and having a plurality of holes formed at equal intervals; An upper header is coupled between the upper left module holder and the upper right module holder, and the lower header is a hollow fiber membrane module coupled between the lower left module holder and the lower right module holder; Immersible membrane separation apparatus comprising a; diffuser coupled to the bottom of the transverse frame is formed with a plurality of air holes and connected to an external air pump to aerated air through the air holes Provides lightweight membrane units for systems.

In addition, a plurality of distribution pipes having a plurality of air holes are formed in the hollow pipe constituting the diffuser, the distribution pipe is formed in communication with the distribution pipe is extended downwardly and the foreign matter discharge pipe is always open, When air is supplied to the distribution pipe and aerated through the air hole, the air is discharged through the air hole due to the hydraulic pressure difference, but the foreign matter discharge pipe communicating with the distribution pipe does not discharge the air, and the air flows through the air hole. As the specific gravity greater than the water is characterized in that it can be discharged without being stacked in the distribution pipe, the hollow fiber membrane module is made by connecting the hollow fiber membrane between the upper header and the lower header, the upper header and the lower header Vertical connectors and horizontal connectors formed at both ends are perpendicular to each other. As it is ranging, and include the foreign material discharge pipe characterized in that the variable-length pipe which is variable is formed as a sliding insert or pull to push foreign matter sandwiched between the exhaust pipe.

According to the present invention, since only one suction header coupled to the connector of the hollow fiber membrane module is formed, the structure is simple and advantageous in weight reduction. In addition, until now, the connector used in the membrane unit has been formed in only one of the vertical direction or the horizontal direction at both ends or the top of the header, in the present invention, the vertical connector and the vertical connector formed in the hollow fiber membrane module in the direction of the vertical and horizontal Since the hollow fiber membrane module is shaken by the aeration pressure, both the vertical direction and the horizontal direction can be firmly held by the module holder. In addition, although foreign matter such as sand enters the air hole formed in the diffuser and remains, it can be discharged like air during aeration and act like a bullet, but the sand flowing into the air hole is prevented from dropping the air pressure during discharge. It can escape again, preventing damage to the hollow fiber membranes.

1 is a perspective view of the combination of the membrane unit according to the present invention.
Figure 2 is a perspective view of the main part of the separator unit according to the present invention.
3 shows a state in which the hollow fiber membrane module according to the present invention is coupled to the module holder.
4 is an enlarged view of "A" in FIG.
FIG. 5 is an enlarged view of “B” of FIG. 3.
6 is a cross-sectional view of a state in which the hollow fiber membrane module is coupled to the module holder according to the present invention.
Figure 7 shows a diffuser of another embodiment according to the present invention.

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

As shown in Figure 1 and Figure 2, a pair of vertical frame 110 is provided spaced apart to be supported on the floor. The vertical frame 110 is preferably used by a stainless steel sheet so that the material does not rust in water. The vertical frame 110 is a rectangular steel plate, and the separation distance between the height of the vertical frame 110 and the vertical frame determines the size of the separator unit.

The upper portion of the vertical frame 110 is coupled to the upper left horizontal frame 120 and the upper right horizontal frame 130 interconnecting the vertical frames. The upper left horizontal frame 120 connects the upper left side of the vertical frame 110 with each other, and the upper right horizontal frame 120 connects the upper right side of the vertical frame 110 with each other and is integrally coupled to form a separator unit. Strengthen.

The lower portion of the vertical frame 110 is coupled to the lower left and right horizontal frame 140 and the right lower horizontal frame 150 interconnecting the vertical frame 110. The lower left horizontal frame 140 connects the lower left side of the vertical frame 110 with each other, and the lower right horizontal frame 150 connects the lower right side of the vertical frame 110 with each other to strengthen the structure.

In the center of the upper end of the vertical frame 110 is formed a citation ring 165 that can lift or lower the membrane unit using a mechanical device such as a crane, the vertical frame that is opposed to form a citation ring (165) ( The lifting bar 160 is coupled between the 110. When the lifting bar 160 is located inside the vertical frame 110, it interferes with the installation space of the hollow fiber membrane module to be described later, so that the bar brackets (bbk) made of steel sheets are formed on the vertical frames 110, respectively, between the bar brackets (bbk). Combine salvage bar 160 to. Therefore, the lifting bar 160 is slightly higher than the vertical frame 110, and the lifting ring 165 is formed therein. Quotation ring 165 is formed at the center of gravity, it is possible to maintain the balance without tilting when lifting or lowering the membrane unit.

The suction header 170 is coupled to the upper end of the vertical frame 110 in the lateral direction. The suction header 170 is connected to the suction pump outside the separator unit to form a negative pressure, and a flow path is formed therein to allow fluid to flow therein. The suction header 270 also interferes with the installation space of the hollow fiber membrane module when positioned on the inner side of the longitudinal frame 110, thereby forming a header bracket made of steel on the top of the longitudinal frame 110, respectively, between the header brackets hbk. Couple the suction header 170 to the. One side of the suction header 170 is formed with a suction pipe 172 in communication with the flow path inside the suction header is connected to the external pump to form a negative pressure.

The upper surface of the suction header 170 is coupled to the upper left module holder 180 formed with a plurality of holes at the same interval. The hole bh is a place where the upper vertical connector vc of the hollow fiber membrane module 230 to be described later is fitted, and a flow path hole (not shown) corresponding to the hole is formed on the bottom of the suction header, and the hole bh ) And the flow path formed inside the suction header 170 are in communication with each other. The hole bh of the upper left module holder 180 is formed in the vertical direction.

The upper right side frame 130 is coupled to the upper right module fixing stand 190 formed with a plurality of holes (bh) at the same interval. The hole bh is where the upper horizontal connector lc of the hollow fiber membrane module 230 is fitted. The hole bh of the upper right module fixing stand 190 is formed in the horizontal direction. When the plurality of hollow fiber membrane modules 230 are fitted to the upper right module fixing stand 190, the bar may be pushed up by pressing the upper right module fixing stand 190 because it may be swung or lifted by an external force applied to the hollow fiber membrane module 230 during use. bar). Both ends of the push bar are joined to the longitudinal frame 110 by welding, and a bolt hole is formed in the middle of the push bar, and the upper right side frame fixing plate 190 avoids a hole to form a corresponding bolt hole. By forming a bolt hole corresponding to the 130 also by fastening the bolt so that the push bar (bar) firmly press the upper right module holder (190).

The upper left lower frame frame 140 is coupled to the lower left module fixture 210 formed with a plurality of holes at the same interval. The hole is where the lower vertical connector vc of the hollow fiber membrane module 230 is fitted. The holes of the lower left module holder 210 are formed in the vertical direction.

The upper right side frame 150 is coupled to the lower right module fixing plate 220 formed with a plurality of holes (bh) at the same interval. The hole is where the lower horizontal connector (lc) of the hollow fiber membrane module 230 is fitted. The hole bh of the lower right module holder 220 is horizontal. When the plurality of hollow fiber membrane modules 230 are fitted to the lower right module holder 220, the bar may be pushed or pressed by the lower right module holder 220 because the hollow fiber membrane module 230 may be swung or lifted by an external force applied to the hollow fiber membrane module 230 ( bar). Both ends of the push bar are joined to the vertical frame 110 by welding, and form a bolt hole in the middle of the push bar (bar) and avoid the hole in the lower module fixing base 220 to form a corresponding bolt hole after the lower right By forming a bolt hole corresponding to the horizontal frame 150 and fastening the bolts so that the push bar (bar) firmly press the lower module holder 220.

As shown in FIGS. 3 to 6, the hollow fiber membrane module 230 is coupled between the upper left module fixing unit 180, the lower left module fixing unit 210, the upper right module fixing unit 190, and the lower right module fixing unit 220. The hollow fiber membrane module 230 is formed by connecting several strands of the hollow fiber membrane 236 between the upper header 232 and the lower header 234. The upper header 232 has a flow path formed therein, a vertical connector vc is formed at the left end, and a horizontal connector lc is formed at the right end. A hole is formed at the center of the vertical connector vc, and the hole is in communication with a flow path formed inside the upper header 232.

The vertical connector vc formed on the upper header 232 is inserted into and coupled to the hole bh of the upper left module holder 180 to communicate with the flow path of the suction header 170. The outer circumference of the vertical connector (vc) is formed of an elastic O-ring such as a rubber ring to maintain the watertight even when the fluid pressure acts upon suction when inserted into the hole. The vertical connector vc is provided with a plurality of reinforcing pieces (rf) in the longitudinal direction of the vertical connector (vc) to reinforce the structure to prevent breakage when the hollow fiber membrane module 230 swings due to aeration pressure in the water.

The horizontal connector lc formed at the right end of the upper header 232 is inserted into and coupled to the hole bh of the upper right module fixing stand 190. The horizontal connector (lc) has no pores, so it does not matter even if the watertight is not maintained, but since the hollow fiber membrane module 230 may be damaged by the impact force when rocking due to aeration pressure, an O-ring with a cushion such as a rubber ring is formed. It can absorb the impact force.

The vertical connector vc formed at the left end of the lower header 234 is inserted into and coupled to the hole bh of the lower left module fixing base 210. The lower header 234 does not have a flow path therein, and there is no hole in the vertical connector vc formed in the lower header 234, so there is no need to maintain watertightness, but to prevent breakage by absorbing shock during swinging. An elastic O-ring is formed on the outer circumference of the vertical connector vc.

A horizontal connector lc is formed at the right end of the lower header 234. The horizontal connector lc formed at the right end of the lower header 134 is inserted into and coupled to the hole of the lower module fixing stand 220. The horizontal connector (lc) has no pores, so it does not matter even if the watertight is not maintained, but since the hollow fiber membrane module 230 may be damaged by the impact force when rocking due to aeration pressure, an O-ring with a cushion such as a rubber ring is formed. It can absorb the impact force.

The vertical connector vc formed on the upper header 132 and the lower header 134 is a vertical direction and the horizontal connector lc is different from each other as a horizontal direction, both in one direction (vertical direction or horizontal direction) such as vertical direction or horizontal direction. If it is formed only, it is advantageous to prevent the fluctuation in one direction when the hollow fiber membrane module 230 is swung by the aeration pressure, but becomes weak in the other direction. If the vertical connector (vc) in the vertical direction and the horizontal connector (lc) in the horizontal direction are formed in the hollow fiber membrane module, the vertical connector (vc) formed in the upper header and the lower header is left upper module fixing unit 180 The swing is limited by the lower left module holder 210, and the swing is greatly reduced, and when swinging in the horizontal direction, the swing is limited by the upper right module holder 190 and the lower right module holder 220. Greatly reduced.

A diffuser 250 is installed at the bottom of the vertical frame to connect the external air pump to aeration the compressed air in the hollow fiber membrane module. The diffuser forms a plurality of air holes ah in the hollow pipe 260 to supply compressed air to the hollow pipe 260 so that air is periodically aerated through the air holes ah.

As another embodiment of the present invention, as shown in FIG. 7, a plurality of distribution pipes 270 are formed at the bottom of the hollow pipe 260 of the diffuser, and a plurality of air holes (ah) are formed in the distribution pipe 270. Form. The distribution pipe is connected to communicate with the hollow pipe 260 through the auxiliary distribution pipe 272, so that the compressed air passing through the hollow pipe 260 passes through the distribution pipe 270 and aeration through the air hole (ah). It is. Several foreign substance discharge pipes 280 are formed at both ends or bottom of the distribution pipe. The foreign substance discharge pipe 280 is formed downward while communicating with the distribution pipe 270 and the lower portion thereof is opened.

The distribution pipe 280 is coupled to the variable pipe 282 that can be inserted into the distribution pipe to be changed in length as necessary. Variable pipe 282 is to change the length by pulling or pushing like a fishing rod.

Referring to the operation according to the present invention configured as described above are as follows.

When the membrane unit is installed in the sewage water to be treated, the external suction pump is connected to the suction pipe 172 of the suction header 170, and the suction pump is operated to generate fine pores of the hollow fiber membrane 232 by negative pressure. Only integers are sucked through.

If the process of water purification through the hollow fiber membrane is prolonged for a long time, fine pores may be blocked, in which case the compressed air is blown through the air hole (ah) by blowing compressed air at regular intervals through the diffuser (250). The aerated compressed air shakes off contaminants stuck to the micropores of the hollow fiber membrane 236 to prevent the micropores from being blocked.

The aerated air provides strong fluidity to the fluid so that the hollow fiber membrane 236 as well as the entire hollow fiber membrane module 230 and the whole membrane unit are rocked. When the hollow fiber membrane module 230 swings, the impact force is transmitted to the horizontal connector (lc) and the vertical connector (vc), but fatigue destruction may occur, but the vertical connector (vc) is the upper left module holder (180) and the lower left module holder ( The flow is limited by 210. The horizontal connector lc is limited in swing by the upper right module fixing stand 190 and the lower right module fixing stand 220. That is, it prevents fatigue from breaking by limiting excessive fluctuations.

When air is discharged through the air hole (ah) of the hollow pipe 260, foreign matter contained in the wastewater is not introduced into the hollow pipe 260 through the air hole (ah), but air is discharged at regular intervals. If not, foreign matter is introduced into the hollow pipe 260 through the air hole (ah). In particular, foreign matters having a large specific gravity, such as sand, once introduced into the hollow pipe 260, are not easily discharged even when aerated, and are stacked on the hollow pipe to occupy space, thereby degrading the function of the diffuser. When it is discharged with air when it is aerated, it collides with the hollow fiber membrane at high speed as a bullet, and if it is repeated, the hollow fiber membrane may be damaged eventually. As shown in FIG. 7, a distribution pipe 270 is formed and a foreign substance discharge pipe is extended ( 280), the sand introduced through the air hole exits immediately without being laminated.

That is, by preventing foreign matter and sand from accumulating in the hollow pipe 260, air does not act as a bullet when discharged. Since the foreign matter discharge pipe 280 communicating with the distribution pipe 270 is always open, the foreign matter discharge pipe 280 can be rolled up when the foreign material such as sand is introduced and discharged immediately by gravity, but the air pressure can also be discharged and aerated. It can not function as an diffuser, but because it extends under the foreign matter discharge pipe 280, a hydraulic pressure difference between the distribution pipe 270 and the lower end of the foreign matter discharge pipe 280 occurs, so that the Air does not escape through the foreign substance discharge pipe (280). When the pressure becomes relatively high pressure, it is possible to escape the water pressure according to the height difference, but in this case, by pulling out the variable pipe 290, the height difference between the distribution pipe 270 and the foreign matter discharge pipe (actually variable pipe) the bottom. Just do it.

110: vertical frame 120: upper left horizontal frame
130: upper right horizontal frame 140: lower left horizontal frame
150: right and lower horizontal frame 160: lifting bar
165: lifting ring 170: suction header
172: suction tube 180: upper left module holder
190: upper right module holder 210: lower left module holder
220: lower right module fixing station 230: hollow fiber membrane module
232: upper header 234: lower header
236: hollow fiber membrane
250: diffuser 260: hollow pipe
270: distribution pipe 280: foreign substance discharge pipe
290: variable pipe

Claims (4)

In the membrane unit for immersion membrane separation apparatus,
A pair of longitudinal frames 110 erected to be supported on the floor;
A left upper horizontal frame 120, a right upper horizontal frame 130, a lower left horizontal frame 140, and a lower right horizontal frame 150 connecting the vertical frames;
A lifting bar 160 opposed to each other at the center of the upper vertical frame so that a pair of bar brackets protrude upwards of the vertical frame, coupled between the pair of bar brackets, and a citation ring formed at a center thereof;
A pair of header brackets are formed to protrude to the upper side of the vertical frame to be opposed to each other on the upper side of the vertical frame, is coupled between the pair of header bracket, the flow path is formed inside, the suction header formed with a suction pipe on one side 170;
An upper left module fixing unit 180 coupled to the suction header bottom and having a plurality of holes formed at equal intervals;
An upper right module fixing unit 190 coupled to the upper right upper frame and having a plurality of holes at equal intervals;
A lower left module fixing unit 210 coupled to an upper surface of the lower left horizontal frame and having a plurality of holes at equal intervals;
A lower right module fixing unit 220 coupled to an upper surface of the lower right horizontal frame and having a plurality of holes formed at the same interval;
The upper header 232 is coupled between the upper left module holder 180 and the upper right module holder 190, the lower header 234 is coupled between the lower left module holder 210 and the lower right module holder 220, The vertical connector vc and the horizontal connector lc formed at both ends of the upper header 232 and the lower header 234 are hollow fiber membrane modules 230 formed perpendicular to each other;
And a diffuser (250) coupled to the bottom of the vertical frame (110) and having a plurality of air holes formed therein and connected to an external air pump to aerated air through the air holes. Lightweight membrane unit for submerged membrane separation apparatus. The method of claim 1,
In the hollow pipe constituting the diffuser, a plurality of distribution pipes 270 having air holes are formed, and the distribution pipe extends downwardly while communicating with the distribution pipe, and the foreign substance discharge pipe 280 is always open at the bottom thereof. The foreign matter discharge pipe is provided with a variable pipe 290 that is variable in length while being inserted into the foreign matter discharge pipe and pushed or pulled to form a variable pipe, and the air is supplied to the distribution pipe and aerated through the air hole. Air is discharged through the air hole, but the foreign matter discharge pipe communicated with the distribution pipe does not discharge the air, and foreign substances having a relatively specific gravity greater than water introduced through the air hole are not laminated in the distribution pipe without being laminated. Lightweight membrane unit for immersion type membrane separation apparatus, characterized in that. delete delete

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