KR20140066471A - Hollow fiber, and sealing and coating equipment of it - Google Patents

Abstract

The present invention relates to a hollow fiber membrane used for filtering in various fields which, more specifically, relates to the hollow fiber membrane having a side concreted onto a housing of a module of the hollow fiber membrane by the use of a hardening agent and the other side moving freely. Furthermore, the present invention relates to a processing equipment to manufacture the hollow fiber membrane which, more specifically, relates to a sealing and coating equipment of the hollow fiber membrane used to coat a stiffening member on the surface of an end of the hollow fiber membrane and to seal the other end.

Description

HOLLOW FIBER, AND SEALING AND COATING EQUIPMENT OF IT,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hollow fiber membrane used for filtration in various fields, and more particularly to a hollow fiber membrane in which one end is hardened in a housing of a hollow fiber membrane module as a hardener and the other end is freely moved.

The present invention relates to a processing apparatus for processing a hollow fiber membrane, and more particularly, to a hollow fiber membrane sealing and coating apparatus for coating a reinforcing agent on one end surface of a hollow fiber membrane and sealing the other end.

The hollow fiber membrane module is a filtration treatment apparatus using a hollow fiber as a separation membrane. The hollow fiber membrane module is used in various fields such as water treatment field, blood treatment field, and the like.

The hollow fiber membrane modules are mostly upright, and the upper and lower ends of the membrane are fixed with a housing hardener. A hollow fiber membrane module of this type is disclosed in Korean Patent Publication No. 2012-0090125 (hereinafter referred to as "prior art document") under the name of a polyurethane resin-forming composition and a hollow fiber membrane module.

The hollow fiber membrane module according to the prior art is manufactured by inserting a plurality of strands of hollow fiber membranes in a hollow housing and curing the upper and lower ends of the hollow fiber membranes respectively by using a hardener on the upper and lower portions of the housing.

According to the hollow fiber membrane module according to the prior art, since the upper and lower ends of the hollow fiber membrane are both fixed to the housing, the shaking of the membrane is limited. Therefore, when the air is sprayed to the hollow fiber membrane to separate the foreign matter present on the surface of the hollow fiber membrane from the hollow fiber membrane, the effect of the hair is poor. That is, when the hollow fiber membrane is shaken by the air during the air injection, the efficiency of separation of foreign matters increases. However, in the prior art, since the both ends of the hollow fiber membrane are fixed, the efficiency of separating foreign matters is decreased.

In order to solve such a problem, a module form capable of increasing the radius of motion of the membrane by increasing the radial movement of the membrane has been developed and applied by fixing only the upper or lower end of the hollow fiber membrane to the housing with a hardening agent and the opposite side to be freely shaken by air.

However, when only one end of the hollow fiber membrane is fixed with a curing agent, fatigue is accumulated on the interface between the hollow fiber membrane and the curing agent due to excessive shaking of the membrane, resulting in a problem that the membrane is singly wound.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the conventional problems as described above, and it is an object of the present invention to provide a hollow fiber membrane capable of minimizing the single yarn problem due to fatigue by coating a reinforcing agent for reinforcing strength on the surface of one end portion, .

Another object of the present invention is to provide a hollow fiber membrane sealing and coating apparatus capable of minimizing the problem that the hollow fiber membrane is united by fatigue even if only one end of the hollow fiber membrane is fixed to the housing with the hardener.

The hollow fiber membrane according to the present invention has a structure in which one end is hardened in the housing of the hollow fiber membrane module and the other end is freely moved by a hardening agent, and one end surface is coated with a reinforcing agent for strength reinforcement and the other end is sealed.

The other end of the hollow fiber membrane is press-sealed after the adhesive is injected inside.

When one end of the hollow fiber membrane is fixed to the housing with a hardener, the coating part is partially exposed to the outside.

The other end of the hollow fiber membrane is pressed on both sides to form two pressing surfaces, the pressing surfaces being rounded, and the gap between the two pressing surfaces narrowing to the ends.

A hollow fiber membrane sealing and coating apparatus according to the present invention comprises: a membrane feeder for feeding a hollow fiber membrane; A sealing device sealing the other end of the hollow fiber membrane configured to be freely moved in the hollow fiber membrane module; And a coating apparatus for coating a reinforcing agent on the surface of one end of the hollow fiber membrane fixed to the housing in the hollow fiber membrane module.

The sealing device presses the other end of the hollow fiber membrane to seal it and injects the adhesive to the other end before pressing.

The sealing apparatus includes an adhesive injection unit for injecting an adhesive into the other end of the supplied hollow fiber membrane; And a sealing part for pressing and sealing the other end of the hollow fiber membrane into which the adhesive is injected.

A hollow fiber membrane insertion groove for inserting the other end of the hollow fiber membrane is formed at one side of the adhesive injection part and an adhesive injection hole for connecting the hollow fiber membrane insertion groove to the other side of the adhesive injection part to inject the adhesive into the insertion groove.

Sectional area of the hollow fiber membrane insertion groove is formed to be larger than the cross-sectional area of the hollow fiber membrane, and the hollow fiber membrane insertion groove is formed in such a shape that the inner side surface is inclined while the cross- .

The inner diameter of the adhesive injection hole is formed smaller than the inner diameter of the hollow fiber membrane.

Inside the hollow fiber membrane insertion groove, there is formed a cylindrical fixing section which is formed with the same inner diameter so that the end portion of the hollow fiber membrane is not struck.

The sealing part is formed in a curved shape so as to press the hollow fiber membrane so that the pressing face of the hollow fiber membrane is curved.

The sealing portion includes two pressing portions for pressing one end of the hollow fiber membrane on both sides and pressing the same.

The coating apparatus includes a coating block in which the hollow fiber membrane penetrates and coating of the reinforcing agent is performed; And a finger installed at the front and back of the coating block to move the hollow fiber membrane back and forth while maintaining the tension of the hollow fiber membrane.

The coating block has a hollow fiber membrane through hole through which the hollow fiber membrane passes, and a reinforcing agent injection hole connected to the hollow fiber membrane through hole to inject a reinforcing agent to be coated.

Wherein the hollow fiber membrane through hole has a front end portion formed in such a shape that an inner side surface is inclined and a cross sectional area is reduced from the front end where the hollow fiber membrane is inserted to the center, And a rear end portion extending from the center to the rear end, the inner end being inclined and the sectional area being expanded.

The reinforcing fill hole is connected to the rear end.

One end of the hollow fiber membrane enters the hollow fiber membrane through hole and penetrates through the hollow fiber membrane through hole, and then the reinforcing agent injected through the reinforcing agent injection hole is coated on the surface during the backward movement.

When the reinforcing agent is coated on the surface of the hollow fiber membrane, the reinforcing agent is scraped by the neck portion between the front end portion and the rear end portion, and the reinforcing agent is uniformly coated on the surface of the hollow fiber membrane.

The hollow fiber membrane is coated while being moved in the horizontal direction, and the center line of the hollow fiber membrane is aligned with the center line of the hollow fiber membrane through hole while the tension is maintained by the finger.

The hollow fiber membrane sealing and coating apparatus of the present invention further includes an aligning device for aligning and transporting the hollow fiber membrane, which is positioned on the front side of the coating apparatus and is subjected to the surface coating.

The aligning device comprises: a conveyor positioned at a front lower side of the coating apparatus and sequentially moving when the surface-coated hollow fiber membrane is seated, thereby aligning the hollow fiber membrane uniformly; A punch for vertically moving the hollow fiber membrane discharged from the coating apparatus to the top of the coating apparatus to be lowered to the conveyor; And a bonding portion provided on the upper surface of the conveyor and bonded to the hollow fiber membrane that is seated on the conveyor.

The hollow fiber membrane of the present invention has the following effects.

First, the reinforcing agent for reinforcing the strength is coated on one end of the housing which is hardened by the hardener, thereby reinforcing the strength of one end of the hollow fiber membrane, thereby minimizing the single threading problem due to fatigue accumulation which may occur at the interface between the hollow fiber membrane and the hardener .

Secondly, since both ends of the free end of the hollow fiber membrane are pressed to form a press face, the press face is rounded, and the gap between the two press faces is narrowed to the end, The fatigue applied to one end of the hollow fiber membrane fixed to the housing can be reduced.

The hollow fiber membrane sealing and coating apparatus of the present invention has the following effects.

First, the other end of the hollow fiber membrane is sealed by using a sealing device, and a reinforcing agent is coated on the surface of the end of the hollow fiber membrane by using a coating device, so that only one end of the hollow fiber membrane is fixed to the housing and the other end is free- Since the strength of one end of the hollow fiber membrane is reinforced in the structure, it is possible to minimize the problem that the interface between the hollow fiber membrane and the curing agent is unified during the waxing process.

Secondly, in the process of inserting the other end of the hollow fiber membrane into the adhesive injection unit for injecting the adhesive into the other end of the hollow fiber membrane, the inlet side cross-sectional area of the hollow fiber membrane insertion groove is made larger than the inside, Can be inserted. In addition, since the embedding hole is formed inside the hollow fiber membrane insertion groove so that the other end of the hollow fiber membrane is not struck and the inner diameter of the adhesive injection hole is formed smaller than the inner diameter of the hollow fiber membrane, the adhesive does not leak to the outside, .

Third, the tension of the hollow fiber membrane is maintained by the finger while the hollow fiber membrane is horizontally moved forward and backward to penetrate the coating block, so that the center line of the hollow fiber membrane coincides with the center line of the hollow fiber membrane through hole formed in the coating block. , The coating can be uniformly performed on the surface of the hollow fiber membrane.

1 is a view showing an example of a hollow fiber membrane module to which a hollow fiber membrane according to the present invention is applied.
2 is a perspective view showing a hollow fiber membrane according to the present invention.
Figure 3 is a front view of Figure 2;
4 is a schematic view showing the structure of a hollow fiber membrane sealing and coating apparatus according to the present invention.
5 is a configuration diagram of a sealing device.
6 is a sectional view showing the internal structure of the adhesive injection unit shown in Fig.
FIG. 7 is a cross-sectional view showing a state in which an adhesive is injected into the other end of the hollow fiber membrane through the adhesive injection unit of FIG. 6;
FIG. 8 is a perspective view showing a state in which the other end of the hollow fiber membrane is sealed by the sealing part shown in FIG. 5;
9 is a schematic view of a coating apparatus.
10 is a cross-sectional view showing the internal structure of the coating block shown in FIG.
11 is a cross-sectional view showing a state in which a hollow fiber membrane is coated.
12 is a configuration diagram of the alignment section.
13 is a view showing a state in which a hollow fiber membrane is aligned on a conveyor of an alignment unit.

Hereinafter, the hollow fiber membrane of the present invention and its sealing and coating apparatus will be described in detail with reference to the accompanying drawings.

FIG. 1 is a view showing an example of a hollow fiber membrane module to which a hollow fiber membrane according to the present invention is applied, FIG. 2 is a perspective view showing a hollow fiber membrane according to the present invention, and FIG. 3 is a front view of FIG.

1, the hollow fiber membrane 10 according to the present invention is fixed to the housing 20 only at one end (upper end or lower end) by the curing agent 30. The other end of the hollow fiber membrane 10 is sealed to prevent inflow of the treated water. When only one end of the hollow fiber membrane 10 is fixed to the housing 20, the hollow fiber membrane 10 can flow, so that the effect of the foreign matter remaining on the surface of the hollow fiber membrane 10 is improved.

At this time, the hollow fiber membrane material can be used without limitation as long as it can be used as a separation membrane material. For example, the polymer may be selected from the group consisting of polycarbonate, polyvinylidene fluoride, polytetrafluoroethylene, polypropylene, polyamide, cellulose-esters, polysulfone, polyetherimide, polyetheretherketone, polyethersulfone, polyacrylonitrile, polyimide, and the like.

On the other hand, the reinforcing agent may be coated on one end surface of the hollow fiber membrane 10 fixed to the housing 20 to increase the rigidity of the hollow fiber membrane 10. It is possible to minimize the single yarn problem of the hollow fiber membrane 10 which may be generated due to fatigue accumulation at the interface between the hollow fiber membrane 10 and the curing agent in the process of blowing air through the hollow fiber membrane 10 to shake the hollow fiber membrane 10.

Particularly, when the hollow fiber membrane 10 is fixed to the housing 20 by the hardening agent, the coating portion 11 is partially exposed to the outside.

The other end of the hollow fiber membrane 10 to be freely moved is sealed by being pressed on both sides after the adhesive is injected into the other end thereof. The sealing portion 12 is formed in a smooth curved shape in which the width between the two pressed surfaces becomes gradually narrower toward the end. Since the other end of the hollow fiber membrane 10 is formed in this manner, the other end of the hollow fiber membrane 10 is less influenced by the air injection for the flow of the fluid and the acid. It is possible to reduce the fatigue once applied to the part.

At this time, the reinforcing agent and the adhesive are materials to be melted at a high temperature, and polyurethane, polyester, ethylene-vinyl acetate, and blends of two or more of them are preferably used.

4 is a schematic view showing the structure of the hollow fiber membrane sealing and coating apparatus of the present invention.

As described above, the hollow fiber membrane sealing and coating apparatus according to the present invention is for coating a reinforcing agent on the surface of one end of the hollow fiber membrane 10 and sealing the other end. The membrane feeder 100, the membrane transfer device 200, (300), a coating apparatus (400), and an alignment apparatus (500).

The membrane feeder 100 feeds the hollow fiber membrane 10 one by one to the membrane transfer device 200. During the supply of the hollow fiber membrane 10, the hollow fiber membrane 10 is supplied with the tension so that the hollow fiber membrane 10 is not caught by the robot finger.

The membrane transfer apparatus 200 is for positioning the hollow fiber membrane 10 supplied from the membrane feeder 100 at a sealing position and a coating position. The hollow fiber membrane 10 to be fed is held by two robot fingers And is rotated 180 degrees to move the end of the hollow fiber membrane 10 to the sealing position.

The sealing apparatus 300 is configured such that a fluid to be treated flows through the other end of the hollow fiber membrane 10 by injecting an adhesive agent into the other end of the hollow fiber membrane 10 transferred by the membrane transfer apparatus 200, .

The coating apparatus 400 coats the surface of one end of the hollow fiber membrane 10 fixed to the housing 20 with a reinforcing agent.

The aligning apparatus 500 aligns and transports the sealed and coated hollow fiber membranes 10 side by side.

5 is a configuration diagram of the sealing apparatus.

The sealing apparatus 300 includes an adhesive injection unit 310 for injecting an adhesive into the other end of the supplied hollow fiber membrane 10 at an end of the supplied hollow fiber membrane 10 and an end of the hollow fiber membrane 10 into which the adhesive is injected, And a sealing part 320 for pressing and sealing.

When the hollow fiber membrane 10 is transported by the membrane transfer apparatus 200, the adhesive injection unit 310 advances to insert the other end of the hollow fiber membrane 10, and in this state, A predetermined amount (for example, 1 to 5 mg) of an adhesive is injected into the other end of the adhesive layer. After the injection of the adhesive, the hollow fiber membrane 10 is separated from the hollow fiber membrane 10 by backward movement.

The sealing part 320 is installed so as to be able to move up and down. When the adhesive injection is completed and the adhesive injection part 310 is moved backward, the sealing part 320 rises and presses the other end of the hollow fiber membrane 10 by a predetermined part (e.g. When the sealing is completed, the sealing part 320 is lowered.

FIG. 6 is a cross-sectional view illustrating an internal structure of the adhesive injection unit shown in FIG. 5, and FIG. 7 is a cross-sectional view illustrating a state where an adhesive is injected into the other end of the hollow fiber membrane through the adhesive injection unit of FIG.

6, a hollow fiber membrane insertion groove 311 in which the other end of the hollow fiber membrane 10 is inserted is formed at one side of the adhesive injection unit 310, and a hollow fiber membrane insertion hole 311 is formed at the other side of the adhesive injection unit 310. [ An adhesive injection hole 312 is formed which is connected to the insertion groove 311 and injects the adhesive into the hollow fiber membrane insertion groove 311 side.

The inlet side sectional area of the hollow fiber membrane insertion groove 311 is formed to be larger than the cross sectional area of the hollow fiber membrane 10 and the hollow fiber membrane insertion groove 311 is formed such that the inner side surface is inclined and the cross- The hollow fiber membrane 10 can be easily inserted into the hollow fiber membrane insertion groove 311 when the adhesive injection unit 310 is advanced. The hollow fiber membrane insertion groove 311 is formed in a triangular pyramidal shape or a conical shape as a whole.

The inner diameter of the adhesive injection hole 312 is smaller than the inner diameter of the hollow fiber membrane 10. An adhesive injection port (not shown) in the form of a triangular pyramid is connected to the inlet side of the adhesive injection hole 312.

An embedding section 313 is formed inside the hollow fiber membrane insertion groove 311 in a cylindrical shape having the same inner diameter so that the end portion of the hollow fiber membrane 10 is closely attached to the adhesive injection hole 312 and is not struck.

As shown in FIG. 7, the other end of the hollow fiber membrane 10 is inserted into the hollow fiber membrane insertion groove (not shown) through the adhesive injection unit 310 having the above- The adhesive is filled into the other end portion of the hollow fiber membrane 10 when the adhesive is injected through the adhesive injection hole 312 in a state where the adhesive agent is completely inserted into the fixing portion 311 and the fixing portion 313.

In this process, the adhesive injection hole 312 is formed to have an inner diameter smaller than the inner diameter of the hollow fiber membrane 10, and the end of the hollow fiber membrane 10 is fixed to the mounting section 313, So that the injected adhesive can be stably injected into the hollow fiber membrane 10 without leaking to the outside.

 8 is a perspective view showing a state where the other end of the hollow fiber membrane is sealed by the sealing part shown in FIG.

The sealing part 320 includes two pressing parts 321 so as to press the other end of the hollow fiber membrane 10 on both sides. Since the pressing surfaces of the two pressing members 321 are formed in a curved shape, the pressing face of the hollow fiber membrane 10 is curved.

That is, when the injection of the adhesive into the hollow fiber membrane 10 is completed, the sealing parts 320 are lifted in a state in which the two pressing parts 321 of the sealing part 320 are open, and the ends of the hollow fiber membrane 10 are pressed The lifting is stopped and the two pressing members 321 press both sides of the other end of the hollow fiber membrane 10.

The other end of the hollow fiber membrane 10 pressed by the sealing portion 320 is formed into a smooth curved surface shape in which the width between two pressed surfaces becomes gradually narrower toward the end as described above.

9 is a configuration diagram of a coating apparatus.

The coating apparatus 400 includes a coating block 410 through which the hollow fiber membrane 10 penetrates while being back and forth to coat the hollow fiber membrane 10 and a hollow fiber membrane 10 which is positioned before and after the coating block 410 to maintain the tension of the hollow fiber membrane 10 forward and backward. And a robot finger 413 (414).

10 is a sectional view showing the internal structure of the coating block shown in FIG.

The coating block 410 is provided with a hollow fiber membrane through hole 411 through which the hollow fiber membrane 10 penetrates and a reinforcing agent injection hole 412 connected with the hollow fiber membrane through hole 411 for injecting a reinforcing agent of a hot- .

The hollow fiber membrane through hole 411 has a front end portion 411a formed in such a manner that its inner surface is inclined and its sectional area is reduced from the front end where the hollow fiber membrane 10 is inserted, And a neck portion 411c formed between the front end portion 411a and the rear end portion 411b. The diameter of the neck portion 411c is formed in consideration of the thickness of the coating to be coated with the reinforcing agent in the hollow fiber membrane 10. The front end portion 411a and the rear end portion 411b are formed in a triangular pyramid shape or a conical shape as a whole.

The reinforcing agent injection holes 412 are formed on both sides of the hollow fiber membrane through holes 411 to inject reinforcements on both sides of the hollow fiber membrane through holes 411. The outlet of the reinforcing agent injection hole 412 is formed in the rear end portion 411b of the hollow fiber membrane through hole 411 and is positioned close to the neck portion 411c (e.g., 2 mm from the neck portion).

Meanwhile, the center c of the hollow fiber membrane through hole 411 maintains a horizontal state so that the coating of the reinforcing agent is performed while the hollow fiber membrane 10 is moved back and forth in the horizontal direction.

11 is a cross-sectional view showing the coating of the hollow fiber membrane.

After completion of the sealing operation, the hollow fiber membrane 10 is transferred to the coating block 410 for coating the reinforcing agent on one end surface thereof and coated. The coating process will be described in detail.

11 (a), the hollow fiber membrane 10 is moved toward the coating block 410 while the tension is maintained by the robot finger 413 in a state where one end of the hollow fiber membrane 10 is positioned at the front side And is inserted into the hollow fiber membrane through-hole 411. In the process of inserting the other end of the hollow fiber membrane 10 into the hollow fiber membrane through hole 411, the shape of the front end 411a of the hollow fiber membrane through hole 411 (i.e., The hollow fiber membrane 10 can be easily inserted into the hollow fiber membrane.

When the front end of the hollow fiber membrane 10 passes through the hollow fiber membrane through hole 411, the robot finger 414 positioned behind the coating block 410 as shown in FIG. 11 (b) I hold it while holding tension. At this time, the robot finger 413 positioned in front of the coating block 410 releases the force holding the hollow fiber membrane 10, and only the hollow fiber membrane 10 is supported without being struck. The length of pulling the hollow fiber membrane 10 toward the rear side of the coating block 410 by using the robot finger 414 located at the rear side is determined in consideration of the coating length.

When the front end of the hollow fiber membrane 10 passes through the hollow fiber membrane through hole 411 by a predetermined length, the reinforcing agent is injected through the reinforcing agent injection hole 412 into the hollow fiber membrane through hole 411 as shown in FIG. 11 (c) And injected into the rear end portion 411b. The robot finger 413 located at the front side of the coating block 410 firmly holds the hollow fiber membrane 10 and the hollow fiber membrane 10 is coated on the coating block 410. In order to realize a gentle slope at the coating start point, (410). In this process, the reinforcing agent is coated on the surface of the hollow fiber membrane 10, and the reinforcing agent is scraped from the neck portion 411c during the process of passing the coated hollow fiber membrane 10 through the neck portion 411c, so that the final coating is performed only to a desired thickness.

11 (d), the reinforcing agent is hardened on the surface of the hollow fiber membrane 10 in the process that the other end of the hollow fiber membrane 10 passes through the neck portion 411c and moves backward.

The coating of the surface of the hollow fiber membrane 10 is made uniform so that the center of the hollow fiber membrane 10 and the center of the hollow fiber membrane through hole 411 are aligned when the hollow fiber membrane 10 is horizontally moved back and forth . The robot fingers 413 and 414 positioned at the front and back of the coating block 410 are arranged to adjust the tension of the hollow fiber membrane 10 to a predetermined value so that the center of the hollow fiber membrane 10 and the center of the hollow fiber membrane through- Keep it back and forth.

The desired coating length can be determined in consideration of the variables such as the moving speed of the hollow fiber membrane 10 using the robot fingers 413 and 414 and the injection time of the reinforcing agent.

The reinforcing agent is coated on the surface of one end of the hollow fiber membrane 10 to a predetermined thickness. When the one end of the hollow fiber membrane 10 is hardened to the housing 20 with the hardener, the coating part is partially exposed to the outside.

FIG. 12 is a view showing the arrangement of the alignment part, and FIG. 13 is a view showing a state in which the hollow fiber membrane is aligned on the conveyor of the alignment part.

The aligning apparatus 500 includes a conveyor 510, a punch 511, and an adhesive section 512.

The conveyor 510 is sequentially moved (for example, at intervals of 2 mm) when the hollow fiber membrane 10 having the surface coating is placed under the front side of the coating block 410 so that the plurality of hollow fiber membranes 10 are arranged side by side at regular intervals .

The punch 511 is vertically installed on the front side of the coating block 410 so that when the hollow fiber membrane 10 is discharged from the coating block 410, the hollow fiber membrane 10 is pressed downward and downward by the conveyor 510 .

The adhesive portion 512 is provided on the upper surface of the conveyor 510 in the form of a tape to adhere the hollow fiber membrane 10 to be placed on the conveyor 510. At this time, a portion of the one end of the hollow fiber membrane 10, which is not coated with the surface, is bonded to the bonding portion 512.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

10: hollow fiber membrane 11: coated portion
12: sealing part 20: housing
100: membrane feeder 200: membrane feeder
300: sealing apparatus 310: adhesive injection unit
320: sealing part 400: coating device
410: coating block 411: hollow fiber membrane through hole
412: reinforcing agent injection hole 413, 414: robot finger
500: alignment device 510: conveyor
511: punch 512:

Claims (22)

The hollow fiber membrane being one end cured in the housing of the hollow fiber membrane module as a hardening agent and the other end being freely moved,
A reinforcing agent is coated on the surface of the one end to reinforce the strength, and the other end is sealed. The method according to claim 1,
And the other end is compressed and sealed after the adhesive is injected into the inside. 3. The method according to claim 1 or 2,
And the coating portion is partially exposed to the outside when the one end is fixed to the housing with the hardener. 3. The method according to claim 1 or 2,
Wherein the other end of the hollow fiber membrane is compressed to form two compression surfaces, the compression face is rounded, and the gap between the two compression faces becomes narrower toward the end. A membrane supply device for supplying a hollow fiber membrane;
A sealing device sealing the other end of the hollow fiber membrane configured to be freely moved in the hollow fiber membrane module; And
And a coating apparatus for coating a reinforcing agent on a surface of one end of the hollow fiber membrane fixed to the housing in the hollow fiber membrane module. 6. The method of claim 5,
Wherein the sealing device is configured to compress and seal the other end of the hollow fiber membrane, and to inject the adhesive into the other end of the hollow fiber membrane before compression and sealing. The method according to claim 6,
Wherein the sealing device comprises:
An adhesive injection unit for injecting an adhesive into the other end of the supplied hollow fiber membrane; And
And a sealing part for compressing and sealing the other end of the hollow fiber membrane into which the adhesive is injected. 8. The method of claim 7,
An adhesive injection hole is formed at one side of the adhesive injection part to insert a hollow fiber membrane insertion groove into which the other end of the hollow fiber membrane is inserted and the other side of the adhesive injection part is connected to the hollow fiber membrane insertion groove, Wherein the hollow fiber membrane sealing and coating apparatus comprises: 9. The method of claim 8,
Sectional area of the hollow fiber membrane insertion groove is formed to be larger than a cross-sectional area of the hollow fiber membrane insertion groove, the hollow fiber membrane insertion groove is formed such that the inner side surface thereof is inclined from the inlet toward the inside thereof and the sectional area thereof is reduced, Wherein the hollow fiber membrane is inserted into the hollow fiber membrane insertion groove easily. 10. The method of claim 9,
Wherein an inner diameter of the adhesive injection hole is smaller than an inner diameter of the hollow fiber membrane. 11. The method of claim 10,
Wherein the hollow fiber membrane insertion groove is formed at an inner side of the hollow fiber membrane insertion groove so as to have a cylindrical holding section for preventing the end of the hollow fiber membrane from being stuck. 12. The method according to any one of claims 7 to 11,
Wherein the sealing portion is formed in a curved shape so as to compress the hollow fiber membrane so that the compression face of the hollow fiber membrane is curved. 13. The method of claim 12,
Wherein the sealing portion includes two pressing portions for pressing one end of the hollow fiber membrane at both ends thereof and pressing the same. 6. The method of claim 5,
The coating apparatus includes:
A coating block through which the reinforcing agent is coated while passing through the hollow fiber membrane; And
And a finger installed at the front and back of the coating block to move the hollow fiber membrane forward and backward while maintaining the tension of the hollow fiber membrane. 15. The method of claim 14,
Wherein the coating block has a hollow fiber membrane through hole through which the hollow fiber membrane passes and a reinforcing agent injection hole connected to the hollow fiber membrane through hole to inject a reinforcing agent to be coated. 16. The method of claim 15,
The hollow fiber membrane-
A front end portion formed in such a shape that the inner side surface is inclined and the sectional area is reduced from the front end where the hollow fiber membrane is inserted to the center; And
And a rear end portion extending from the center to the rear end of the hollow fiber membrane, the inner side of the hollow portion being inclined and extending in a cross-sectional area. 17. The method of claim 16,
Wherein the reinforcing agent injection hole is connected to the rear end portion of the hollow fiber membrane sealing and coating apparatus. 18. The method of claim 17,
Wherein one end of the hollow fiber membrane enters the hollow fiber membrane through hole and penetrates through the hollow fiber membrane through hole and then is coated on the surface of the reinforcing agent injected through the reinforcing agent injection hole in the course of backward movement. Device. 19. The method of claim 18,
Wherein a reinforcing agent is scraped by a neck portion between the front end portion and the rear end portion when the reinforcing agent is coated on the surface of the hollow fiber membrane so that the reinforcing agent is uniformly coated on the surface of the hollow fiber membrane. . 20. The method according to any one of claims 15 to 19,
Wherein the hollow fiber membrane is coated while being moved in the horizontal direction, and the center line of the hollow fiber membrane is aligned with the centerline of the hollow fiber membrane through-hole while the tension is maintained by the finger. 6. The method of claim 5,
Further comprising an aligning device for aligning and transporting the surface-coated hollow fiber membrane positioned in front of the coating device. 22. The method of claim 21,
The alignment apparatus may further comprise:
A conveyor for sequentially aligning the hollow fiber membranes and aligning the hollow fiber membranes;
A punch for vertically movably installed on the front side of the coating apparatus and pressing the hollow fiber membrane discharged from the coating apparatus downward to the conveyor; And
And a bonding portion provided on an upper surface of the conveyor to adhere the hollow fiber membrane to be mounted on the conveyor.

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