KR101554924B1 - Membrane unit for immersion type membrane separation system - Google Patents

Abstract

The present invention relates to an anti-movement separation membrane unit for preventing a damage of a hollow fiber membrane module, which is a separation membrane unit for an immersion-type membrane separation device. The separation membrane unit comprises: separation membrane frames; a module support frame connecting the separation membrane frames to reinforce a structure; a hollow fiber membrane module inserted between the module support frames; a pressing bar pressing headers formed on the upper and lower ends of the hollow fiber membrane module to make one surface of the header closely adhere to the module support frame, thereby preventing the vertical movement of the header; a left-to-right movement preventing bar closely adhering to the side end of the header of the hollow fiber membrane module to have both ends fixated to the separation membrane frame; a shock-absorbing member inserted between the header and the left-to-right movement preventing bar made of a steel plate and composed of a material having relatively lower hardness than that of a steel plate in order to prevent the header having relatively lower hardness than that of the left-to-right movement preventing bar from being subjected to fatigue failure or a damage by an instant and repetitive moving force when the left-to-right movement preventing bar closely adheres to the side end of the header of the hollow fiber membrane module; and a stay bar erected vertically between the module support frames to resist deformation when an external force is applied, thereby preventing minute deformation of the separation membrane frame and the module support frame, wherein because the stay bar is capable of moving vertically and horizontally, the fixed position thereof can be re-adjusted to prevent torsional stress from acting in a particular direction when the separation membrane frame and the module support frame are deformed above the allowable level.

Description

[0001] The present invention relates to a membrane unit for immersion type membrane separation,

The present invention relates to a separation unit of a submerged membrane separation apparatus for purifying wastewater or wastewater by treating the wastewater or a day, and more particularly, to a separation membrane unit that prevents flow generated by air pressure aeration when a hollow fiber membrane module is installed in a separation membrane frame, And more particularly, to a separation preventing unit for preventing damage to a hollow fiber membrane module that prevents fatigue breakage or damage of a module.

The submerged membrane separator is a device for purifying wastewater or sewage by filtering and filtering foreign matters such as dissolved pollutants and microorganisms and suspended substances contained in wastewater or sewage through biological processes or physicochemical processes.

The separation membrane generally uses a hollow fiber membrane. Hollow fiber membrane modules are used to collect and bundle hundreds to thousands of hollow fiber membranes in order to increase the processing capacity and integrate them in the charged space.

Since the hollow fiber membrane module is manufactured to fit the size of the separation membrane unit, the size of the hollow fiber membrane module is 150 cm × 120 cm. The structure of the hollow fiber membrane module generally comprises a hollow fiber membrane having a predetermined length and a header for fixing upper and lower ends of the hollow fiber membrane, and a modular frame for maintaining the structure by connecting upper and lower headers to both ends of the header.

When a negative pressure is generated through a pumping device connected to the flow path of the header, purified water flows into the header through the hollow fiber membrane and is discharged to the outside.

The material of the header is made of metal or synthetic resin, and it is general to use a synthetic resin which is light in weight, cheap in price, and excellent in moldability.

When the hollow fiber membrane module is installed in the separation membrane unit, the separation membrane unit is provided with a module support base for seating the header, and a hollow fiber membrane module is assembled between the module support bases.

Hollow fiber membrane modules are standardized for cost reduction or productivity improvement, but there is a limit to precise manufacturing, so a certain machining error occurs. If such a hollow fiber membrane module is assembled to the module support of the separation membrane unit, there will be a step due to the machining error and the flow will be generated. In addition, even if a module supporting frame or a module supporting frame holding a hollow fiber membrane module, especially a separation frame forming a skeleton frame, is manufactured in a precise size, it is inevitable that a machining error will occur. Therefore, In order to prevent the flow of the module, a flow prevention structure of various structures is provided.

The structure for preventing the vertical movement of the hollow fiber membrane module is provided, but a structure for preventing lateral movement of the hollow fiber membrane module has not been developed. This is because the flow displacement is smaller than that in the up-down direction, but a more fundamental problem is that it is possible to damage the header in which the flow path is formed when a structure for preventing the flow of the hollow fiber membrane module in order to catch the fine flow is provided. Damage to the header means that untreated wastewater is introduced, so that it is difficult to perform the function as a purifier even if the amount is very small.

As described above, the header is formed with a flow path with a hollow space therein, and a plurality of hollow fiber membranes are coupled to the flow path. The hollow fiber membrane has a strong tensile strength, but it has no structural strength. Therefore, when it is connected to the header, it is not possible to form a hole in the header like a metal tube and to insert a tab into the hole and then to join them by bolt fastening method. I can not.

In addition, when the hollow fiber membrane is bonded to the header, the hollow fiber membranes may be continuous or overlap without being spaced from each other at regular intervals, so that one side of the header is linearly opened, a plurality of hollow fiber membranes are inserted therein, Keep watertight by milling. In addition, since the watertightness of the hollow fiber membrane module is very important, high technical factors are added in the course of applying the adhesive, but the cross section of the joint portion is reduced or enlarged due to the pressure change applied to the hollow fiber membrane through the suction pump. The coupling portion between the header and the hollow fiber membrane is structurally weak.

Therefore, it is important to consider the damage of the header when the hollow fiber membrane module is constructed to prevent the vertical and horizontal movements of the hollow fiber membrane module. However, it is difficult to prevent the damage of the header when the left / It was difficult to catch the directional flow.

Also, the membrane frame may have a fine but structural deformation when it is used due to the residual stress due to welding heat, the bending of the steel sheet, or the residual stress generated during the forming process, The header portion of the hollow fiber membrane module can be broken or the flow of the hollow fiber membrane module can be further accelerated, but it has been difficult to prevent its structural deformation.

Korean Patent Publication No. 10-2012-0133600 Registered Utility Model No. 20-0402163 Korean Patent No. 10-1461048 Korean Patent No. 10-1281642

Disclosure of Invention Technical Problem [8] The present invention is to solve the above-mentioned problems, and it is intended to prevent the lateral displacement of the header portion of the hollow fiber membrane module and prevent the header from being damaged or damaged by external impact applied to the header portion. It is also intended to provide a separation membrane unit for a submerged membrane separator which can resist the structural deformation of the membrane frame and actively cope with the already generated structural deformation.

In order to achieve the above object, the present invention provides a separation membrane unit for a submerged membrane separation device, comprising: a separation membrane frame; a module support frame connected to the upper and lower portions of the separation membrane frame by horizontally connecting them to each other; A control bolt for forming a vertical slot in the module frame and the corresponding module support frame portion of the module and coupling the upper module support frame to the upper module support frame and adjusting the height of the upper module support frame in the vertical slot, A pressure bar for pressing the header formed at the upper and lower ends of the hollow fiber membrane module to press the one side of the header against the module supporting frame to prevent the vertical movement of the header, So that both ends are fixed to the separation membrane frame When the left and right anti-flow bars are closely attached to the header side of the hollow fiber membrane module, the relatively low hardness headers are prevented from being fatigued or damaged by momentary and repetitive flow forces as compared with the left and right anti- A shock absorbing member inserted between the header and the steel plate and made of a material having a relatively lower hardness than the steel sheet; a shock absorbing member inserted vertically between the module supporting frames to resist a deformation when an external force is applied, And the stator bar can be vertically and horizontally moved so that the separation frame and the module support frame can readjust the fixed position when a deformation exceeding a specified amount comes and prevent the twisting stress from acting in a specific direction Hollow fiber membrane module damage A flow-preventing separator unit for preventing flow is provided.

In addition, the module support frame to which the stay bar is coupled is formed with a horizontal slot having a length of 1 to 3 cm longer than the width direction, to which the stay bar is coupled, and a threaded portion is formed at the upper and lower ends of the stay, And the height and horizontal position of the stay bar are adjusted while the nuts are loosened and tightened by tightening the nuts on the inside and the outside of the frame. The left and right flow restraining bars are formed with a plurality of bolt holes, Wherein a plurality of bolt holes are formed to allow the shock absorber to be replaced when the shock absorber is worn or damaged by the bolt connection of the left and right flow restraints and the shock absorber, wherein the shock absorber member is made of polyethylene .

According to the present invention, it is possible to prevent the vertical movement of the hollow fiber membrane module through the pressure bar and to prevent the lateral movement of the hollow fiber membrane module as a whole through the left and right flow prevention bars, thereby minimizing the flow of the hollow fiber membrane module during aeration through the air diffuser When the hollow fiber membrane module is in direct contact with the left and right fluid flow prevention frames, the synthetic resin header having a relatively low hardness may be fatigued or damaged. However, the impact absorbing member capable of absorbing the impact force in the flow process is medium So that it is possible to prevent fatigue breakage and damage of the header while preventing lateral flow. In addition, when the separator frame is deformed by residual stress during manufacturing or by external force during use, a stay bar that can resist the deformation is formed, so that deformation of the separator unit can be prevented. Nevertheless, It is possible to readjust the position of the stay bar so as not to cause distortion of the separator frame due to the deformation.

1 is an assembled perspective view of a separation membrane unit according to the present invention.
2 is an exploded perspective view of a main part of a separation membrane unit according to the present invention.
3 is a perspective view showing a main part of a separation membrane unit according to the present invention.
FIG. 4 is a view showing a coupling relationship between the left and right flow restraining members and the shock absorbing member according to the present invention.
Figure 5 shows the combination of the stay bar and the module support frame according to the invention.
6 is a cross-sectional view of the stator bar according to the present invention coupled to the module support frame.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 1 to 6, a structure formed by mutual welding is provided with a separator frame 110, which is integrated with a bolt that is easy to disassemble and disassemble, thereby forming a ceiling exemption form.

At the upper and lower ends of the separation membrane frame 110, a module support frame 120 is formed which connects both sides of the separation membrane frame. The module support frame reinforces the structure by connecting both sides across the membrane frame.

The module support frame 120 may be welded to the separator frame, but it is preferable that the module support frame 120 is fastened by a bolt / nut method to facilitate replacement when it is damaged or damaged.

The module supporting frame 120 coupled to the upper end of the separator frame 110 is vertically and vertically coupled. A pair of vertical slots vh are formed on both sides of the upper end of the separation membrane frame 110 and a pair of vertical slots vh corresponding to the vertical slots vh are formed in the module support frame 120 to fit the adjustment bolts into the vertical slots vh And the nut (N) is tightened on the opposite side to join the membrane frame (110) and the upper module supporting frame (120). Thus, the upper module support frame 120 can adjust the height within the vertical slot by unscrewing and tightening the adjustment bolt 125. The number of vertical slots can be increased or decreased in consideration of the structural strength, but it is preferable that the number of vertical slots is one in terms of assembly workability and archival stability.

Modular support frames 120 formed at both sides of the upper part of the separation membrane frame 110 and module supporting frames 120 formed at both sides of the lower part are provided with module grippers 130 for holding the header of the hollow fiber membrane module Are formed at regular intervals. A bolt hole is formed at the center of the module grip 130 and a bolt hole corresponding to the module support frame 120 is formed. The module grip 120 is coupled to the module grip frame 120 at predetermined intervals by fastening bolts.

A plurality of bolt holes are formed in the pressing bar at regular intervals and a plurality of bolt holes are formed in the pressing bar so as not to interfere with the module grip 130 on the outer edge of the module supporting frame 120, A plurality of bolt holes are formed, an adjusting bolt is inserted therebetween, and the screw is tightened or loosened with a nut to adjust the height of the pressing bar so that the hollow fiber membrane module can be pressed.

A hollow fiber membrane module 150 is installed between the upper and lower module support frames. The hollow fiber membrane module is formed by joining both ends of a hollow fiber membrane to a header 154. A flow path for the filtered water to flow through the hollow fiber membrane 152 is formed in the header 154, 154 are connected and fixed to each other.

After the hollow fiber membrane module 150 is installed, the adjustment bolt 125 coupling the module support frame 120 is unfastened and the module support frame 120 is pressed upward to press the header 154 of the hollow fiber membrane module 150, The fine spacing that may be formed between the frame 120 is reduced and the adjustment bolt 125 is tightened again to minimize the clearance between the hollow fiber membrane module 150 and the module support frame 120.

The hollow fiber membrane module 150 is manufactured in advance in accordance with the interval between the module support frames 120 formed at the upper and lower ends of the separation membrane frame. However, the hollow fiber membrane module 150 is free from any clearance. When the pressure bar 140 is attached to the module supporting frame 120 after the hollow fiber membrane module 150 is assembled and then tightened with the nut, the pressure bar 140 is attached to the module support frame 120. [ Thereby preventing the hollow fiber membrane module 150 from being lifted or vibrated in the vertical direction.

Left and right flow restraints 160 are formed on the front and rear of the membrane frame 110 to prevent the header 154 of the hollow fiber membrane module 150 from flowing in the left and right directions. The left and right flow restraints are coupled by bolting (bolt / nut) the brackets 170 to both sides of the separation membrane frame 110, and the left and right flow restraints 160 are bolted between the brackets. It is preferable to use a stainless steel sheet which has high structural rigidity but does not rust, instead of a steel sheet or a stainless steel sheet, which can be made of an alloy or other metal having high hardness and excellent structural rigidity.

The left and right flow restraining bands 160 may be directly connected to the side surfaces of the header 154. However, when the material is a steel sheet and has a high hardness and thus is in direct contact with the side surface of the synthetic resin header 154, Since the low-hardness header may be fatigued or the surface may be damaged, the impact absorbing member 180 may be attached to the left and right anti-motion bar 160 with a lower or similar hardness than the header, 160 and the header 154. [ The length of the shock absorbing member 180 is approximately equal to the length of the left oil flow preventing frame 160 so that the entire headers 154 can be supported by one shock absorbing member 180.

Although the impact absorbing member 180 may be used when bonding the left and right flow restraining bands 160 to each other, the adhesive may be deteriorated if it is used for a long time in water, so that a plurality of bolt holes are formed in the impact absorbing member 160 at regular intervals A bolt hole corresponding to the left and right flow restraints 160 is formed and tightened with bolts / nuts so that the shock absorbing member 180 is firmly engaged with the left and right flow restraints 160. It is possible to form the bolt head in the staggered portion where the header does not come in direct contact with the header 154 when the bolt hole is formed in the shock absorbing member 180, It is preferable that the bolt head is not brought into direct contact with the header even if the impact absorbing member 180 is brought into close contact with the header.

The shock-absorbing member 180 is coupled with a bolt, so that the shock-absorbing member 180 can be easily attached and detached as needed. As the material of the shock absorbing member 180 is made of polyethylene, since the hardness is designed to be lower than that of the header 154, the cross section is reduced and restored when the shock is absorbed. The function of the member is weakened. In this case, the bolt is loosened so that the shock absorbing member 180 can be removed and replaced.

Stable bars 210 are connected to each other between module supporting frames 120 formed above and below the separator frame 110. The stay bar 210 prevents the separation membrane frame 110 from being deformed by resisting stress generated when the separation membrane frame 110 is manufactured or resistance to deformation of the separation membrane frame due to external force during use.

Four stave bars 210 are formed at a predetermined interval in one module supporting frame 120 and are formed in a space behind the module frame 130 in which the header does not pass since the modules are not to interfere with the header 154 of the hollow fiber membrane module . Even if the stay bar 210 is formed in the rear space of the module magazine 130, if the width and / or the diameter of the stay bar 210 is large and is deviated outside the module magazine 130, interference with the header 154 may occur. The diameter should be small. Although the number of the stay bars 210 can be increased or decreased according to the size of the separation membrane frame, even if only four of the stay bars 210 are formed at regular intervals, the function of the stay bar 210 as a resistance against deformation can be sufficiently performed.

The stay bar 210 has a net effect of preventing the membrane frame 110 from being deformed, but if it is installed for a long period of time, it imparts a direction of deformation in a specific direction, thereby generating a side effect that induces excessive deformation only in one direction. In order to prevent such a side effect, the deformation amount of the separation membrane frame 110 is measured during use and if the deformation more than the reference value occurs, the stay bar 210 should be readjusted to conform to the deformation. A horizontal slot hh is formed in upper and lower module support frames 120 to which the stay bar 210 is fixed to readjust the stay bar 210. [ The width of the horizontal slot hh is set to be approximately equal to the diameter of the stay bar 210 so that there is no flow in the width direction after the stay bar 210 is inserted, but the length is longer than the width by about 1 to 3 cm, 210 can be moved.

 A threaded portion 212 is formed at the upper and lower ends of the stay bar 210. A threaded portion 212 of the stay bar 210 is inserted into the horizontal slot hh, 212, and a nut is fastened to a portion of the screw portion 212 positioned inside the module support frame 120 to tighten the nut, and the stay bar 210 is fixed to the module supporting frame between the nut and the nut . To move the position of the fixed stay bar, loosen the nut fastened to the inside and outside of the module support frame, adjust the position of the stay bar in the vertical and horizontal directions, tighten the nut and securely fix the adjusted position .

The bottom of the separator unit is provided with an air diffuser (S) for blowing air compressed above and below the hollow fiber membrane module through a pump. The air diffusing pipe is installed on the bottom of the separating membrane unit in the form of a hollow pipe, and a plurality of air holes are formed at regular intervals to discharge compressed air to the hollow fiber membrane module through the pump.

The air diffuser is designed to remove pollutants adhering to the micropores of the hollow fiber membrane. The air diffuser is aerated at regular intervals since it is not removed well when it is continuously sprayed at a uniform pressure. That is, by blowing the pulse air pressure to the hollow fiber membrane, the contaminant removal effect is enhanced.

At the upper part of the separation membrane frame, a discharge pipe communicating with the header is connected to the discharge pipe, and a discharge port is formed at the discharge pipe. The discharge pipe is connected to the pump to generate negative pressure, and the purified water is sucked through the hollow fiber membrane module.

Hereinafter, the operation of the present invention will be described.

When the apparatus is activated, a negative pressure is formed in the discharge pipe by the pump, and the purified water is purified by flowing the purified water through the hollow fiber membrane and flowing the purified water through the discharge pipe.

In the purification process, air is aerated in the air diffuser to remove pollutants adhering to the micropores of the hollow fiber membrane 152. The fluidity of the wastewater increases due to the air pressure at this time, and the hollow fiber membrane module 150 is vibrated strongly in all directions .

If the hollow fiber membrane module 150 is swung vertically, horizontally, or vertically, even if the hollow fiber membrane module 150 is pushed by the pressure bar 140, it loosens when it is repeated for a long period of time and thus the hollow fiber membrane module is slightly deviated or loosened. But can not be displaced from the fixed position by the left and right flow restraints 160 and greatly reduces the fluctuation. Even if the side surface of the header 154 is in close contact with the left and right anti-flow bands 160, minute clearances are generated due to processing errors, and when rocking occurs within the clearance, the left and right anti- The impact force is absorbed through the impact absorbing member 180 made of polyethylene having a lower hardness than that of the header 154 between the header 154 and the left and right anti- Rearward flow restraint 160 to prevent fatigue breakage or frictional damage of the header 154.

The separation membrane frame 110 may be finely deformed due to the residual stress generated in the manufacturing process or the external pressure during continuous use to damage the connection portion of the flow path such as the connection portion between the header 154 and the discharge pipe P. However, As the deformation progresses, several stay bars 210 fixed between the module support frames 120 resist and prevent deformation. If the stamper 210 is deformed more than a predetermined amount for a long period of time despite the deformation resistance of the stamper 210 because the deformation resistance by the stamper 210 is also used for a long period of time, The adjustment bolt 125 for coupling the support frame 120 is loosened to adjust the height in the vertical slot vh and the nut used to fix the stay bar 210 is loosened so that the height of the stay bar 210, (hh) to adjust the position by moving it in the longitudinal direction. After correcting or adapting the deformation, tighten the nut again to secure the readjusted position.

110: Membrane frame 120: Module support frame
125: Adjusting bolt 130: Module grip
140: pressure bar 150: hollow fiber membrane module
152: Hollow fiber membrane 154: Heather
156: Header support member 160:
170: Bracket 180: Shock absorbing member
210: stay bar 212: thread

Claims (4)

A separation membrane unit for an immersion type membrane separation device,
Membrane frame;
A module supporting frame for horizontally connecting the upper and lower portions of the separation membrane frame to reinforce the structure;
Wherein a vertical slot is formed in the separator frame of the portion to which the upper module support frame is coupled and the corresponding module support frame portion and the upper module support frame is coupled thereto, An adjustable bolt for adjusting the angle of the bolt;
A hollow fiber membrane module assembled between the module support frames;
A pressure bar for pressing the header formed at the upper and lower ends of the hollow fiber membrane module to close one surface of the header to the module supporting frame to prevent the header from flowing in the vertical direction;
A left and right flow restraining bar having both ends fixed to the separator frame so as to be able to be brought into close contact with a header side end of the hollow fiber membrane module;
In order to prevent the headers having relatively hardness lower than the left and right anti-flow bars made of steel plates from being fatigued or damaged by momentary and repetitive fluid force when the left and right anti-flow bars are closely attached to the header side of the hollow fiber membrane module, A shock absorbing member made of a material having a hardness relatively lower than that of a steel sheet inserted between the impact absorbing members;
The module frame and the module support frame can be prevented from being deformed to a fine degree and can be moved up and down and horizontally by resisting the deformation when an external force is applied to the module frame and the module support frame, A stay bar capable of restraining a fixed position when it comes and preventing a warping stress from acting in a specific direction;
Wherein the hollow fiber membrane module includes a plurality of hollow fiber membranes.
The method according to claim 1,
The module support frame to which the stay bar is coupled
A bolt hole to which the stay bar is coupled is formed into a horizontally elongated hole having a length of 1 to 3 cm longer than the width direction and a screw is formed at the upper and lower ends of the stay bar to fasten the nut to the inside and outside of the module support frame, Wherein the height of the stay bar and the horizontal position of the stay bar are adjusted while being loosened.
The method according to claim 1,
A plurality of bolt holes are formed in the left and right flow restraints and a plurality of bolt holes corresponding to the shock absorbing members are formed so that the left and right flow restraints and the shock absorbing members are bolted to each other to replace the shock absorbing members when they are worn or damaged Wherein the hollow fiber membrane module is made of a synthetic resin.
The method according to claim 1,
Wherein the material of the shock absorbing member is polyethylene. ≪ RTI ID = 0.0 > 11. < / RTI >

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