KR102211689B1 - spiral wound type filter module and method for fabricating the same - Google Patents

Abstract

Provides a spiral wound filter module and manufacturing method.
The present invention is a perforated pipe having at least one inlet hole; A cylindrical filter body in which a membrane sheet and a sheet laminate in which sheets are stacked through permeate flow channels are stacked in multiple layers and wound in a spiral wound shape on the outer surface of the perforated pipe; And a joint portion for bonding the membrane sheet and the sheet through the permeate flow path. Including, wherein the bonding portion is a pair of bonding extension lines extending in parallel along both edges of the membrane sheet or the permeate flow channel, and a bonding connection line connecting the end ends of the pair of bonding extension lines facing each other, and And a bending line bent in a direction facing each other so as to be close to the inlet hole from the start end of the pair of bonding extension lines corresponding to the perforated pipe.

Description

Spiral wound type filter module and method for fabricating the same}

The present invention relates to a spiral wound filter module and a method of manufacturing the same.

In general, as water treatment technology for purified water and wastewater is developed, the direction of treatment technology is changing from a conventional sand filtration method to a membrane filtration method using a separator.

This separation membrane technology is a high-level separation filtration water treatment technology for almost completely separating and removing materials to be treated in the treated water according to the pore size, pore distribution and membrane surface charge of the membrane.

Separation membranes, which are core components, are divided according to the size of the pores, and are classified into precision filtration membranes (MF membranes), ultrafiltration membranes (UF membranes), nano separation membranes (NF membranes), and reverse osmosis membranes (RO membranes). Its application range is expanding, such as the production of industrial water, sewage/wastewater treatment and reuse, and clean production processes related to the development of a zero-discharge system.

This separation membrane technology is becoming one of the core technologies that have attracted attention in recent years in line with the trend of increasing water pollution, and in fact, the tap water supplied after being purified by the general public is reprocessed through a water purifier and used for food. For this, technology development is increasingly required.

Meanwhile, the water purifier system is composed of a separator module, a pre- and post-treatment filter, a pump, a pipe, a tank, and other auxiliary devices, and the most important component of such a system is a separator module.

As for the types of these membrane modules, flat, hollow fiber, tubular, and spiral wound types are commercialized, and research on spiral wound membrane modules capable of removing ions from water with high separator insertion density per unit area is mainly conducted. Has become.

As shown in Fig. 1, as shown in Fig. 1, the sheet stacked body 20 wound in a spiral wound shape is bonded and fixed to separate the flow paths of concentrated water and production water using an adhesive made of polyurethane. It is wound in a roll form, which is a roll, and recently, low viscosity adhesives are mainly used.

That is, the process of manufacturing a spiral wound filter module includes placing the perforated pipe 10 having an inlet hole through one end of the membrane sheet 21 having a separator, and excluding one side corresponding to the perforated pipe on the membrane sheet. Membrane sheet and production water flow path by repeating the process of laminating and bonding the sheets with permeate flow and laminating and bonding the other membrane sheets and sheets with permeate flow channels after applying a bonding line linearly with adhesive on both sides and the other side. A sheet laminate made of sheets is laminated in multiple layers.

Then, by applying a pressure of 0~100kgf/cm2, winding the adhesive in the bonding line for about 1 to 60 minutes until the adhesive in the bonding line is cured enough to fix the shape of the spiral wound filter module to manufacture a cylindrical filter body, and then bonding Age approximately 10 minutes to 24 hours until the line adhesive is completely cured.

However, the bonding agent of the bonding line inevitably leaks to the outside due to an external force generated in the process of winding the laminated sheet laminate in the form of a roll through the bonding line centering on the perforated pipe. In the case, the adhesive does not maintain the applied state as it is, and flows out of the outer end portions of both sides.

At this time, holes are mainly generated in the adhesive portion of the sheet laminate corresponding to the vicinity of the outer diameter of the perforated pipe by the adhesive that flows out and exits from both end surfaces of the spiral wound filter module wound in a roll shape.

If the spiral wound filter module in which such holes are generated is applied to the water purifier as it is, it acts as a major cause of crevice leakage, which is a phenomenon in which concentrated water partially flows into the produced water through the hole generated on the end face, reducing the quality of purified water. , It lowers the product reliability for the filter module.

Accordingly, the present invention is to solve the above-described problems, the object of which is to increase the amount of adhesive applied at the starting end of the joint adjacent to the perforated pipe relative to the rest of the joint to increase the retention and maintenance rate of the adhesive, and the adhesive during the winding process It is intended to provide a spiral wound filter module and a manufacturing method capable of preventing the occurrence of holes in the vicinity of the outer diameter of the perforated pipe due to external leakage of the perforated pipe and preventing gap leakage.

The technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems that are not mentioned will be clearly understood by those of ordinary skill in the technical field to which the present invention belongs from the following description. I will be able to.

An embodiment of the present invention as a specific means for achieving the above object, a perforated pipe having at least one inlet hole; A cylindrical filter body in which a membrane sheet and a sheet laminate in which sheets are stacked through permeate flow channels are stacked in multiple layers and wound in a spiral wound shape on the outer surface of the perforated pipe; And a joint portion for bonding the membrane sheet and the sheet through the permeate flow path. Including, The bonding portion is a pair of bonding extension lines extending side by side along both edges of the membrane sheet or the permeate flow channel, and a bonding connection line connecting the end ends of the pair of bonding extension lines facing each other, and It provides a spiral wound filter module comprising a bending line bent in a direction facing each other so as to be close to the inlet hole from the start end of the pair of bonding extension lines corresponding to the perforated pipe.

Preferably, the bending line may be provided in a straight line parallel to the perforated pipe.

Preferably, the bending line may be provided to be inclined at a predetermined angle in a direction approaching or away from the perforated pipe.

Preferably, a fusion portion for temporarily fixing the membrane sheet and the sheet through the permeate flow path may be included at a position corresponding to a position between the outer edge of the cylindrical filter body and the bonding extension line.

Preferably, it may include a fusion portion for temporarily fixing the permeate channel sheet and the other permeate channel sheet laminated thereto at a position corresponding to the outer edge of the cylindrical filter body and the bonding extension line.

Preferably, the outer surfaces of both ends of the perforated pipe may include at least one groove in which a part of the adhesive linearly interposed between the membrane sheet and the permeate channel sheet is accommodated.

More preferably, the groove may be provided at a position corresponding to between the outer edge of the cylindrical filter body and the bonding extension line.

More preferably, the groove may include an absorbent member that absorbs a part of the adhesive.

In addition, another embodiment of the present invention, a preparatory step of arranging a perforated pipe through which at least one inlet hole is formed at one end of the membrane sheet or the permeate channel sheet; Corresponds with a pair of bonding extension lines extending linearly and parallel to each side of the membrane sheet or permeate flow channel, and a bonding connection line connecting the end ends of a pair of bonding extension lines facing each other, and the perforated pipe A junction forming step of forming a junction formed of a bending line that is bent in a direction facing each other from the start end of the pair of junction extension lines; A lamination step of repeatedly laminating the sheet laminate in which the membrane sheet and the sheet are bonded with permeate flow through the joint portion on another sheet laminate; A winding step of forming a cylindrical filter body in which the sheet laminate is wound in the form of a roll by rotating the perforated pipe in one direction around a rotation center; And a cutting step of manufacturing a filter module by cutting to separate and remove portions of both ends of the cylindrical filter body by a cutting wheel disposed in correspondence with the pair of bonding extension lines. It provides a method for manufacturing a spiral wound filter module comprising a.

Preferably, in the joining part forming step, a bending line may be formed in a straight line parallel to the perforated pipe from the start end of the joining extension line.

Preferably, in the joining part forming step, the bending line may be formed at an angle inclined toward or away from the start end of the joining extension line toward the perforated pipe.

Preferably, the laminating step may include forming a fusion portion for temporarily fixing the membrane sheet and the sheet through the permeate flow channel at a position corresponding to between the outer edge of the cylindrical filter body and the bonding extension line. .

Preferably, in the laminating step, a fusion portion for temporarily fixing the permeate flow path sheet and the sheet through the other permeate flow paths stacked thereon is formed at a position corresponding to between the outer edge of the cylindrical filter body and the bonding extension line. It may include steps.

Preferably, in the winding step, when winding the cylindrical filter body, part of the adhesive of the bending line may be temporarily accommodated in at least one recess formed in the outer surfaces of both ends of the perforated pipe.

Preferably, in the winding step, an absorbent member is provided in the groove to absorb the adhesive temporarily accommodated.

Preferably, the cutting step separates and removes the cut product obtained by cutting a part of both ends of the cylindrical filter body, and a fusion part for temporarily fixing the membrane sheet and the sheet through permeate flow or the adhesive of the joint is temporarily accommodated. It may include a groove that becomes.

According to the preferred embodiment of the present invention as described above has the following effects.

By forming a bending line that bends and extends inward at the junction close to the outer diameter of the perforated pipe, the outer of the perforated pipe is taken into account by the amount of outflow of the adhesive from the joint due to the external force generated from the outer diameter of the perforated pipe when the sheet stack is wound. Since the amount of adhesive applied to the joint close to the neck can be relatively increased, the occurrence of holes in the vicinity of the outer diameter of the perforated pipe due to excessive leakage of the adhesive to the short side of the cylindrical filter body during winding can be prevented as much as possible. As a result, the mixing of raw water or concentrated water into the permeated water can be prevented to increase filter efficiency, increase product yield, and increase product reliability.

One side edge of the membrane sheet and one side edge of the sheet through the permeate flow channel are partially welded and temporarily fixed, and the one side edge of the sheet through the permeate flow channel and the other permeate flow channel are partially bonded to one side edge of the sheet to temporarily fix the cylindrical shape. Since it is formed in the area between the both edges of the filter body and the joint extension line, the outflow of the adhesive from the vicinity of the outer diameter of the perforated pipe to the short side of the cylindrical filter body can be blocked by external force generated during winding. It is possible to reduce the amount and increase the amount of adhesive remaining in the vicinity of the outer diameter of the perforated pipe, thereby preventing the occurrence of holes in both short sides of the filter module.

By forming grooves that are recessed in the form of annular rings on the outer surfaces of both ends of the perforated pipe, the adhesive can be temporarily accommodated or absorbed in the path of the adhesive outflow from the vicinity of the outer diameter of the perforated pipe to the short side of the cylindrical filter body by external force generated during winding. Therefore, it is possible to reduce the amount of external leakage of the adhesive, and to increase the amount of the adhesive remaining in the vicinity of the outer diameter of the perforated pipe, thereby preventing the occurrence of holes in both short sides of the filter module.

1 is an external view showing a general spiral wound filter module.
2A and 2B are perspective views and plan views illustrating a preparation step in a process of manufacturing a spiral wound filter module according to an embodiment of the present invention.
3A and 3B are perspective and plan views illustrating a step of forming a junction in a process of manufacturing a spiral wound filter module according to an embodiment of the present invention.
4A and 4B are perspective views and plan views illustrating a process of laminating a filter material while forming a junction in a process of manufacturing a spiral wound filter module according to an embodiment of the present invention.
5 is a perspective view illustrating a process of cutting a wound filter body in a process of manufacturing a spiral wound filter module according to an embodiment of the present invention.
6A and 6B are a perspective view and a plan view showing another form of a junction in a spiral wound filter module according to an embodiment of the present invention.
7A and 7B are perspective views and plan views illustrating an embodiment in which a fusion part is applied in a spiral wound filter module according to an embodiment of the present invention.
8 is a perspective view showing an embodiment in which an adhesive receiving groove is applied in a spiral wound filter module according to an embodiment of the present invention.
9 is a flowchart illustrating a method of manufacturing a spiral wound filter module according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment in which one of ordinary skill in the art to which the present invention pertains can easily implement the present invention. However, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

In addition, the same reference numerals are used for parts having similar functions and functions throughout the drawings.

In addition, throughout the specification, when a part is said to be'connected' to another part, it is not only'directly connected', but also'indirectly connected' with another element in the middle. Include. In addition, "including" a certain component means that other components may be further included, rather than excluding other components unless specifically stated to the contrary.

The process of manufacturing the spiral-wound filter module according to the embodiment of the present invention, as shown in FIGS. 2A to 5 and 9, the perforated pipe preparation step (S1), the junction forming step (S2), the lamination step (S3), Including the winding step (S4) and the cutting step (S5) to manufacture the filter module 100 having the perforated pipe 10 and the junction 30.

In the preparation step (S1), as shown in FIGS. 2A and 2B, at least one perforated pipe 10 and a membrane sheet 21 or a permeate channel sheet 22 are prepared, and the perforated pipe is converted into the membrane sheet 21 ) Or the permeate channel is disposed at one end of the sheet 22.

The perforated pipe 10 may be formed of a hollow pipe member having a predetermined length through at least one inlet hole 12 through which one or both ends of the both ends are opened and produced water is introduced in the middle of the length.

The membrane sheet 21 may be at least one selected from a polyamide-based separation membrane, a polyimide-based separation membrane, a polysulfone-based separation membrane, and a polyether sulfone-based separation membrane, preferably a polyamide-based separation membrane, and permeate flow path sheet (22) may be a tricot paper formed by combining the fiber yarns in the form of felt, paper, non-woven fabric, or the like, or by weaving the fiber yarns with each other with a transverse and a wire.

The sheet stacked body 20 consisting of the membrane sheet 21 and the permeate channel sheet 22 is laminated and bonded through a joint to be described later and wound in a roll form on the outer surface of the perforated pipe in a multi-layered state. It is being wound up.

In this case, the perforated pipe 10 has been illustrated and described as being disposed at one end of the membrane sheet, but is not limited thereto, and may be prepared by being disposed at one end of the sheet through the permeate passage.

In the bonding part forming step (S2), as shown in FIGS. 3A and 3B, a bonding agent is applied linearly along both edges of one side of the membrane sheet 21, and a pair of left and right bonding extension lines having a width of a predetermined size. 31 is formed, and a bonding agent is applied linearly to connect the ends of the pair of bonding extension lines 31 facing each other to form a bonding connection line 32.

In addition, by forming a bending line 33 that is bent in a direction facing each other from each start end of a pair of bonding extension lines corresponding to the perforated pipe 10 to extend a predetermined length, the pair of bonding extension lines 31, bonding A junction 30 made of a connection line and a bending line 33 is formed.

In this case, the bonding portion 30 interposed between the membrane sheet 21 and the permeate channel sheet 22 to bond them is formed by the pair of bonding extension lines 31, bonding connection lines 32, and bending By forming a substantially C-shaped bonding line that is opened to the perforated pipe side by the line 33, the permeated water passing through the membrane sheet 21 forms a permeated water passage flowing into the inlet hole of the perforated pipe.

In the process of forming such a bonding part on one side of the membrane sheet, the bonding agent aeration is moved at a constant speed in the longitudinal direction of the sheet while a bonding agent aeration (not shown) is arranged so as to correspond to one side of the membrane sheet spread on the bottom surface. While discharging the bonding agent in a linear fashion, the bonding extension line is formed by the bonding agent discharged from the discharge port of the bonding agent aeration facing the membrane sheet, and by a discharge port that is moved in the longitudinal direction from the moved or stopped bonding agent aeration A junction connection line connecting the end ends of the pair of junction extension lines is formed, and a bending line that is bent in a direction facing each other at each end end of the pair of junction extension lines is formed.

In the lamination step (S3), as shown in FIGS. 4A and 4B, the membrane sheet 21 and the permeate channel sheet ( 22) is laminated to form the laminated sheet 20, and at the same time, the sheet laminate 20 is formed by placing another membrane sheet or a sheet with permeate flow on the lower sheet laminate 20 to form a junction. By repeating the above process, the sheet laminate is laminated in multiple layers.

At this time, it is preferable that the end portion of the sheet stack facing the perforated pipe is not stacked in a vertical direction but is stacked to form a step shape.

And, between the membrane sheets stacked adjacent to each other, a mesh-like sheet is interposed so as to form a flow path through which raw water is supplied.

Here, the membrane sheet 21 may be made of a filter material in which a mesh sheet, which is a raw water channel material, is inserted and arranged between sheet materials whose length is folded in half to form a flow path through which raw water is introduced and concentrated water is discharged.

In the winding step (S4), as shown in FIGS. 5A and 5B, the drive shaft of the winding chuck (not shown), which is a rotation driving means, is connected to both open ends of the perforated pipe 10.

Subsequently, by rotating the perforated pipe 10 in one direction by the winding chuck, the sheet laminate 20 is wound on the outer surface of the perforated pipe 10 in the form of a roll to form a cylindrical filter body 40 having the perforated pipe in the center of the body. ) To form.

Here, in the process of winding with the cylindrical filter body 40, the adhesive of the bonding portion 30 that bonds the membrane sheet of the sheet laminate 20 and the sheet through the permeate flow channel is not completely cured, but is in a semi-cured or reactive solid state. Therefore, it is spread by an external force generated during winding between the stacked sheets.

At this time, the bending line 33 of the bonding portion 30 is formed by bending in a direction facing each other from the start end of the bonding extension line, so that the adhesive flows out to the short side of the cylindrical filter body due to external force generated during winding. Considering the amount of external leakage, since it is applied to relatively increase the amount of adhesive applied per unit area at the beginning of the joint close to the outer diameter of the perforated pipe, the adhesive applied at the beginning of the joint close to the outer diameter of the perforated pipe is maintained. The amount can be preserved, and the phenomenon that holes are generated on the short side of the cylindrical filter body due to excessive leakage of adhesive can be suppressed and prevented as much as possible.

In addition, the bending line 33 is applied by extending from the start end of the bonding extension line 31 in a direction facing each other, so that it does not spread to the short side of the cylindrical filter body 40 by an external force generated during winding. Since it spreads inward, it is possible to prevent, while suppressing, as much as possible, a phenomenon in which the adhesive of the joint portion is excessively leaked to the outside of the short side of the cylindrical filter body, and holes are generated at the short side of the cylindrical filter body due to excessive leakage of the adhesive.

As shown in FIGS. 3A and 3B, the bending line 33 may be formed to be bent at a substantially right angle to the start end of the bonding extension line to extend a predetermined length in parallel with the perforated tube, but is not limited thereto. As shown in FIG. 6B, it is provided at a certain angle (θ) inclined in a direction away from or close to the perforated pipe 10, so that the amount of adhesive applied at the start of the joint adjacent to the perforated pipe 10 can be increased. .

The extension length (L) of the bending line 33 may be set to 0.1 to 50 mm to apply the adhesive, and more preferably set to 5 to 20 mm to apply the adhesive.

A certain angle θ of the bending line that is formed to be inclined away from or close to the perforated pipe 10 has been illustrated and described as being formed at an obtuse angle greater than a right angle based on the junction extension line, but is not limited thereto, and an acute angle smaller than a right angle It can be formed as

On the other hand, in order to prevent excessive leakage of the adhesive at the junction adjacent to the outer diameter of the perforated pipe when winding the cylindrical filter body by the winding process of the sheet laminate, the membrane sheet and the sheet are welded through the permeate flow channel. A concave groove 15 for temporarily accommodating an adhesive may be provided at both ends of the perforated pipe to limit the position of the fusion portion F to be temporarily fixed.

That is, in the laminating step, the fusion part F for temporarily fixing by partially welding one edge of the membrane sheet 21 corresponding to the perforated pipe and one edge of the permeate channel sheet 22 is shown in FIGS. 7A and 7B. As shown, it is preferable that the cylindrical filter body is partially formed at a position between the outer edge of the cylindrical filter body and the bonding extension line.

Accordingly, in the process of winding the sheet laminate 20 to form the cylindrical filter body 40, one edge of the membrane sheet 21 and one edge of the sheet 22 through the permeate passage are partially Since the fusion part (F), which is temporarily fixed by welding, is arranged close to the outer diameter of the perforated pipe and is located outside the joint extension line, the adhesive is applied from the vicinity of the outer diameter of the perforated pipe to the short side of the cylindrical filter body by the external force generated during winding. By the fusion part (F) arranged in the outflow path, it is possible to reduce the amount of external leakage of the adhesive, and increase the amount of remaining adhesive in the vicinity of the outer diameter of the perforated pipe.

The fusion part F partially fuses one edge of the sheet 22 with the permeate flow path stacked on the membrane sheet 21 and the permeate flow path stacked thereon to temporarily fix them.

In addition, as shown in Fig. 8, the cylindrical filter has a groove 15 in which a part of the adhesive of the bending line 33, which is compressed by an external force generated during winding, on the outer surfaces of the perforated pipe 10 is temporarily received. It may be provided in the form of an annular groove recessed in the outer surface of the perforated pipe at a position corresponding to the outer edge of the sieve and the bonding extension line.

The groove 15 may include at least one absorbing member 15a, such as a sponge, which is inserted and disposed to absorb a liquid adhesive temporarily accommodated during winding. .

Accordingly, during the process of winding the sheet stacked body 20 to form the cylindrical filter body 40, the external force generated during winding is in the recessed groove 15 formed in a ring shape on the outer surfaces of both ends of the perforated pipe. As the adhesive flowing out to the short side of the cylindrical filter body near the outer diameter of the perforated pipe is temporarily accommodated, the amount of external leakage of the adhesive can be reduced or prevented by the groove 15, and the adhesive remains near the outer diameter of the perforated pipe. The amount of maintenance can be increased.

Finally, the cutting step (S5) is part of both side ends of the cylindrical filter body 40 by means of a cutting wheel (not shown) arranged in a one-to-one correspondence with the joint extension line of the joint as shown in FIGS. 6A and 7A. By cutting and removing the cut material 50, the sheet laminate 20 in which the sheet and the membrane sheet are bonded and connected through the junction through the permeate flow channel on the outer surface of the perforated pipe 10 located in the center of the body are sequentially It is to manufacture a filter module 100 in which the stacked and multilayered sheet laminate is wound in a roll form.

Here, the cut material 50 includes a fusion portion (F) for temporarily fixing the sheet by fusing the membrane sheet and the permeate flow channel or a groove 15 in which the adhesive of the bonding portion is temporarily received, and is separated together with the fusion portion or the groove. It is removed.

The operation of cutting a part of both side ends of the cylindrical filter body 40 by rotational drive of the cutting wheel may be performed while rotating the cylindrical filter body in a direction opposite to the rotation direction of the cutting wheel by the winding chuck, but limited to this. It can be performed by rotating the cutting wheel while the cylindrical filter body is stopped.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications and changes are possible within the scope of the technical spirit of the present invention. It will be obvious to those who have the knowledge of.

10: Merit Hall
12: inlet hole
21: membrane sheet
22: permeate channel sheet
20: sheet laminate
30: junction
31: joint extension line
32: joint connection line
33: bending line
40: cylindrical filter body
50: cutting material
100: filter module

Claims (16)

A perforated pipe having at least one inlet hole;
A cylindrical filter body in which a membrane sheet and a sheet laminate in which sheets are stacked through permeate flow channels are stacked in multiple layers and wound in a spiral wound shape on the outer surface of the perforated pipe; And
A joint portion for joining the membrane sheet and the sheet through the permeate flow path; Including,
The joint portion corresponds to a pair of joint extension lines extending in parallel along both edges of the membrane sheet or the permeate flow channel, a joint connection line connecting end ends of a pair of joint extension lines facing each other, and the perforated pipe And a bending line bent in a direction facing each other so as to be close to the inlet hole from the start end of the pair of bonding extension lines,
The bending line is applied in consideration of the amount of external leakage through which the adhesive flows out to the short side of the cylindrical filter body by an external force generated during winding,
Fusion bonding to temporarily fix the membrane sheet and the permeate channel sheet at a position between the outer edge of the cylindrical filter body and the bonding extension line, or temporarily fix the permeate channel sheet and the sheet through another permeate channel stacked thereon Includes wealth,
The outer surfaces of both ends of the perforated pipe include at least one groove in which a part of the adhesive interposed linearly between the membrane sheet and the permeate channel sheet is accommodated,
The concave groove is provided at a position corresponding between the outer edge of the cylindrical filter body and the bonding extension line,
Separately remove the cut product by cutting a part of both ends of the cylindrical filter body, and the cut product to be separated has a fusion part for temporarily fixing the membrane sheet and the sheet through permeate flow, and a groove in which the adhesive of the joint part is temporarily received. Spiral winding filter module comprising a. The method of claim 1,
The bending line is a spiral wound filter module, characterized in that provided in a straight line parallel to the perforated pipe. The method of claim 1,
The bending line is a spiral wound filter module, characterized in that provided to be inclined at a predetermined angle in a direction closer to or away from the perforated pipe side. delete delete delete delete The method of claim 1,
The groove is a spiral wound filter module, characterized in that it comprises an absorbent member for absorbing a portion of the adhesive. A preparatory step of disposing a perforated pipe through which at least one inlet hole is formed at one end of the membrane sheet or the permeate channel sheet;
Corresponds with a pair of bonding extension lines extending linearly and parallel to each side of the membrane sheet or permeate flow channel, and a bonding connection line connecting the end ends of a pair of bonding extension lines facing each other, and the perforated pipe A junction forming step of forming a junction formed of a bending line that is bent in a direction facing each other from the start end of the pair of junction extension lines;
A lamination step of repeatedly laminating the sheet laminate in which the membrane sheet and the sheet are bonded by permeate flow through the joint portion to another sheet laminate;
A winding step of forming a cylindrical filter body in which the sheet laminate is wound in the form of a roll by rotating the perforated pipe in one direction around a rotation center; And
A cutting step of manufacturing a filter module by cutting to separate and remove portions of both ends of the cylindrical filter body by means of a cutting wheel disposed in correspondence with the pair of bonding extension lines; Including,
The bending line is applied in consideration of the amount of external leakage through which the adhesive flows out to the short side of the cylindrical filter body by an external force generated during winding,
In the laminating step, the membrane sheet and the permeate channel sheet are fused to temporarily fix, or the permeate channel sheet and the permeate channel sheet are fused together to temporarily fix the fusion portion of the cylindrical filter body and the bonding extension. Including the step of forming at a position corresponding to between the line,
In the winding step, when winding the cylindrical filter body, at least one portion of the adhesive of the bending line is recessed into the outer surfaces of both ends of the perforated pipe corresponding to a position between the outer edge of the cylindrical filter body and the bonding extension line. Temporarily accommodated in the formed groove,
The cutting step separates and removes the cut material obtained by cutting portions of both ends of the cylindrical filter body,
A method of manufacturing a spiral wound filter module, characterized in that the cut material to be separated and removed includes a fusion unit for temporarily fixing the membrane sheet and the sheet through permeate flow, and a groove in which the adhesive of the bonding unit is temporarily received. The method of claim 9,
The bonding portion forming step is a spiral wound filter module manufacturing method, characterized in that forming a bending line in a straight line parallel to the perforated pipe from the start end of the bonding extension line. The method of claim 9,
The bonding portion forming step is a spiral wound filter module manufacturing method, characterized in that forming a bending line inclined at a predetermined angle in a direction close to or away from the start end of the bonding extension line toward the perforated pipe. delete delete delete The method of claim 9,
The winding step is a spiral wound filter module manufacturing method, characterized in that the absorbent member is provided in the groove to absorb an adhesive temporarily received. delete

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