TW200948463A - A manufacturing method for a hollow fiber module for degassing - Google Patents

Abstract

A manufacturing method for a hollow fiber module for degassing without a center core, comprising the steps of: winding a sheet including numerous hollow fibers around a temporary core; holding the sheet wound around the temporary core so as to form the sheet in a cylindrical manner; and removing the temporary core with the sheet remaining in the cylindrical manner.

Description

。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 。 A method of manufacturing a gas hollow fiber module. [Prior Art] The hollow fiber module for exhaust gas manufactured by the present invention can be used, for example, for oxygen-exhausting water for boiler feed water, oxygen removal, carbonation, and discharge for ultrapure water production in a semiconductor manufacturing process. Ultra-exhaust gas such as nitrogen, protective liquid during lithography, venting of photographic liquid, rust water exhaust in buildings or apartments, medical water exhaust, ink jet venting, defoaming, etc. In recent years, with the increase in the precision of ink jet printers, it has been eagerly expected to exhaust a hollow fiber mold for exhausting and defoaming (removing bubbles in ink) from a liquid such as an ink jet. For example, in the following patent documents 1 and 2, the ink is passed through the inside of the hollow fiber, and the so-called internal perfusion type exhaust gas for exhausting the outside of the hollow fiber is hollow. ® wire module. In the case of the general exhaust gas, for example, Patent Document 3, 4, and 5, which will be described later, the so-called external perfusion type in which the liquid is brought into contact with the outside of the hollow fiber to decompress the inside of the hollow fiber is removed. Gas has excellent properties. In the case of the external perfusion type, the hollow fiber module for exhaust gas is supplied while the ink containing the bubble can be brought into contact with the outer side of the hollow fiber, and the inside of the hollow fiber is sucked to the vacuum on one side. The bubbles contained in the ink are transmitted through the film by the pressure difference between the inside and outside of the hollow wire, and are removed on the low pressure side. After the bubbles are removed, the ink of '200948463' does not pass through the hollow fiber and is discharged by the module. In the case of the exhaust of the ink jet, it is possible to use the external perfusion type from the point of exhaust efficiency and pressure loss per unit membrane area, which is more preferable than the internal perfusion type. When the hollow fiber used in the present invention is a hollow fiber-shaped film that does not allow liquid to permeate through a gas, the raw material, the film shape, and the film form are arbitrary, and the hollow fiber mold used for exhaust gas can be used from the past. Group of hollow wires. For example, the raw material of the hollow fiber may be a polyalkylene resin such as polypropylene or poly(4-methylpentan-1), a sand resin such as polyoxyalkylene or a copolymer thereof, or PTFE. A fluorine-based resin such as a fluorinated vinyl fork. As the shape of the side wall (film) of the hollow fiber, any of a porous membrane, a microporous membrane, and a homogeneous membrane (non-porous membrane) having no porous material can be used. As a film form, the chemical or physical structure of the film as a whole is a homogeneous symmetric film (homogeneous film). The chemical or physical structure of the film is different from the asymmetric film (heterogeneous film) due to the part of the film. Any one can be used. The asymmetric membrane, that is, the so-called heterogeneous membrane has a non-porous dense layer and a porous membrane, but the dense layer is the surface layer portion of the membrane, or as the so-called porous membrane inside, is formed at any part of the membrane. can. Here, the heterogeneous film also includes a so-called composite film having a different chemical structure, and a multilayer structure film having a three-layer structure is also included. In particular, an inhomogeneous film using a poly(4-methylpentene-1) resin is particularly preferred because it has a dense layer that blocks liquid, and a liquid other than water, such as ink. Further, in the case of the external perfusion type hollow fiber, it is preferable that the dense layer is formed on the outer surface of the hollow fiber. A hollow fiber module for exhaust gas, which is disclosed in the following Patent Document 6, 200948463, and 8, has a cylindrical core and a plurality of hollow fibers bundled around it. The cylindrical core system ensures the rigidity of the hollow fiber module for exhaust gas, and has a function of supporting a plurality of hollow fiber substrates in the manufacture of the module. Further, although there is a task as a liquid supply flow path for controlling the flow of the fluid, it also becomes a cause of pressure loss. [Patent Document 1] Japanese Patent Laid-Open Publication No. Hei. No. Hei. No. Hei. No. Hei. No. Hei. No. Hei. Japanese Laid-Open Patent Publication No. Hei. No. Hei. No. Hei. No. Hei. No. Hei. No. Hei. No. Hei. No. Hei. No. Hei. [Patent No. 2005-305432] SUMMARY OF THE INVENTION [Problems to be Solved by the Invention] The above-mentioned ink jet printer is required to be exhausted and defoamed, especially in industrial printers. The hollow fiber module for exhaust gas is placed inside the printer to be exhausted during the printing process. In this case, the hollow fiber module for exhaust gas needs to be as small as possible and the pressure loss is small, and the hollow fiber module for exhaust gas tends to be downsized. However, since the cylindrical core has the function of ensuring the rigidity of the hollow fiber module for exhaust gas and the function as a support base for the hollow fiber, the pressure generated when the ink is introduced and then subjected to the exhaust and defoaming treatment is introduced. Loss becomes a big problem. The present invention has been developed in view of the above-mentioned facts, and aims to provide a hollow fiber module for exhaust gas which can be easily and accurately manufactured by providing a hollow fiber module for exhaust gas which can greatly reduce the pressure loss and can be miniaturized. Manufacturing method. [Means for Solving the Problem] The method for producing a hollow fiber module for exhaust gas according to the present invention is characterized in that a winding process is carried out around a temporary core around a sheet containing a plurality of hollow fibers; The process of holding the sheet around the temporary core in a cylindrical shape; and removing the temporary core from the sheet held in a cylindrical shape. (I) [Effect of the Invention] According to the method for producing a hollow fiber module for exhaust gas according to the present invention, a sheet containing a plurality of hollow fibers is wound around a temporary core and held in a tubular shape, and then removed from the sheet which is held in a cylindrical shape. Therefore, it is possible to satisfy the requirement of miniaturization without securing the core of the support base of the rigidity and the hollow fiber, and to manufacture the hollow fiber having a small pressure loss when the flow of the processed flow is passed, simply and with high precision. [Embodiment] ® [Best Embodiment of the Invention] An embodiment of a method for producing a hollow fiber module for exhaust gas according to the present invention will be described. The invention is characterized in that a sheet containing a plurality of hollow filaments is attached to a temporary core and held in a cylindrical shape, and a resin is supplied to one end of the sheet which is held in a cylindrical shape, and one ends of the plurality of hollow fibers which are juxtaposed with one end of the sheet are joined to each other. And sealing the hole of each hollow fiber opened at one end of the sheet at the same time, after the resin is hardened, the temporary core may also be removed from the sheet by 200948463. Although a plurality of hollow fiber sheets can be woven into a mesh-like sheet, when a liquid such as ink is circulated, the entire hollow fiber can be uniformly contacted with the liquid, and the defoaming can be efficiently handled. Preferably, the hollow fibers are arranged in a substantially parallel sheet. According to the method for producing a hollow fiber module for exhaust gas according to the present invention, the resin is supplied to the cylindrical sheet before the temporary core is removed from the sheet to be held in a cylindrical shape. One end, the one end of the plurality of hollow fibers juxtaposed with one end of the sheet is joined to each other, and the holes of the hollow fibers opened at one end of the sheet are sealed. Thereby, the plurality of hollow fibers are arranged in a substantially parallel sheet. In the case of a cylindrical sheet, a central hole parallel to the longitudinal direction of the hollow fiber can be formed. The central hole of the sheet is secured by a hollow core module for exhaust gas, but is provided as a core of the support base. In the hollow fiber module for exhaust gas of the present invention, the central hole can be easily secured without providing a core. The method for manufacturing a hollow fiber module for exhaust gas according to the present invention The resin may be provided at the other end of the sheet from which the temporary core is removed, and the other ends of the plurality of hollow fibers juxtaposed with the other end of the sheet are joined to each other, and the opening at the other end of the sheet is filled with the resin. The process of the resin. According to the present invention, after the temporary core is removed from the sheet which is held in a cylindrical shape, the resin can be supplied to the other end of the cylindrical sheet, and the other ends of the plurality of hollow fibers juxtaposed with the other end of the sheet are joined to each other. At the same time, the other end of the hole (the above-mentioned central hole) which is open at the other end of the sheet may be filled with resin. The other end of the central hole of the sheet is used as a support matrix by a core. Closed, but in the 200948463 air-wire module for exhaust gas according to the present invention, the other end of the central hole can be simply closed even if the core is not provided. [Embodiment] The hollow fiber module for exhaust gas of the present invention is The implementation of the manufacturing method will be described with reference to the drawings. First, in Figs. 1 and 2, the structure of the hollow fiber module in which the cylindrical core is not held is shown. The coreless exhaust hollow fiber module 1, the plurality of bundles of hollow fibers 3, and the bundle 3 formed by the structure 5 for receiving the tow 3, as shown in Fig. 5, will be arranged in a plurality of hollows of the same The sheet 4 knitted by the filament 2b is wound into a cylindrical shape with the axis of the length of the plurality of hollow filaments 2 as a center. Further, in the center of the cross section orthogonal to the direction of the tow 3, a center hole 3a parallel to the longitudinal direction of the hollow fiber 2 is provided. As shown in Fig. 3, one end of the wire 2 which is juxtaposed with one end (lower end) of the tow 3 is joined to each other through a sealing resin (e.g., epoxy resin, urethane tree ultraviolet curable resin, etc.) E1. The sealing resin E1 W is filled in the holes 2a of the respective hollow fibers 2 which are open at one end of the tow 3, and is sealed by the sealing resin E1 which is filled therein. However, the seal E1 does not fill the opening on one end side of the center hole 3a. As shown in Fig. 4, the other end (the upper end) of the tow 3 is lined up with the other end of the filament 2, and is adhered to each other through a sealing resin (for example, an epoxy resin, a resin, an ultraviolet curable resin, or the like) E2. Sealing resin The hole 2a of each hollow fiber 2 opened at the other end of the tow 3 is not opened by the tomb 2a. However, the sealing resin E2 is filled in the middle of the case, and the gas is used. The filament is hollow in the warp direction, and the fat is also sealed by the FL 2 a resin in the urinary E2, the filling, the central hole-10-200948463 3a, and the opening on the other end side of the central hole 3a is sealed by the filling. The resin E 2 was sealed. That is, the center hole 3a is opened only at one end of the tow 3, and is closed at the other end of the tow 3. As shown in FIGS. 1 and 2, the structure 5 is composed of a cylindrical frame body 5a' and a first cover 5b' which is next to one end (lower end) of the frame body 5a and is then placed in the frame body 5a. The second cover 5c of the other end (upper end) is formed. In the frame body 5a', the ink discharge port 6 is formed in a direction orthogonal to the longitudinal direction of the frame body 5a. © On the outer circumferential surface of one end of the frame body 5a, a rounded portion 7 for fixing the first cover 5b is formed in the circumferential direction. On the other hand, when the first cover 5b is next to one end of the frame body 5a, the claws 8 that are locked to the rounded portion 7 are formed. The first cover 5b is fixed to one end of the frame body 5a by the claw 8 being locked to the rounded portion 7. Further, a supplementary adhesive is also provided between the first cover 5b and one end of the frame body 5a. At the outer circumferential surface of the other end of the frame body 5a, a rounded portion 7 for fixing the second cover 5c is also formed in the circumferential direction. On the other hand, in the second cover 5c, the claw 8 which is locked to the rounded portion 7 is formed at the other end of the frame body 5a. The second cover 5c is fixed to the other end of the frame body 5a by the claw 8 being locked to the rounded portion 7. Here, there is also a supplementary adhesive between the second cover 5c and the other end of the frame body 5a. Further, in order to increase the fixing strength of the frame main body 5a and the first and second covers 5b and 5c, instead of the locking structure of the claw 8 and the rounded portion 7, a screwing structure of a male screw and a female screw may be employed. In the center of the first cover 5b, the ink (including air bubbles) is introduced into the inlet port 9 of the -11-.200948463 exhaust hollow fiber module 1, and is formed in the longitudinal direction of the frame body 5a' in the second The center of the cover 5c is a suction port 10 for drawing the vacuum hollow fiber module 1 to the vacuum, and is formed in the longitudinal direction of the frame body 5a. When the defoaming by the hollow fiber module 1 for exhaust gas is briefly explained, the ink containing bubbles is guided into the frame 5 through the inlet port 9, as shown in Fig. 6. The ink introduced into the frame 5 is supplied to the tow 3 through the center hole 3a, and is in contact with the outside of each of the hollow fibers 2, and is discharged through the ink discharge port 6 and discharged from the frame 5. While continuing to introduce the ink into the structure 5, when the vacuum is attracted to the inside of the frame 5 through the suction port 1 , the inner side of each hollow fiber 2 is reduced by the hole 2a of each hollow fiber 2 opened at the other end of the tow 3 Pressure. Once the inner side of each hollow fiber 2 is decompressed, the ink and the gas contained in the ink move toward the inside of the hollow fiber having a low partial pressure. However, due to the presence of the hollow fiber, the ink itself does not move inside the hollow fiber, so only the gas moves inside the hollow fiber, and the gas can be removed from the ink. In addition, the tasks of the inlet 9 and the outlet 6 can be replaced, and the ® will affect the removal performance. Next, the manufacturing method of the hollow fiber module 1 for exhaust gas having the above configuration will be specifically described with reference to Figs. 7 to 15 . (Cutting of hollow fiber sheet) A hollow fiber 2 having an inner diameter of a side wall (film) having an inhomogeneous structure of 1 0 0 // m and an outer diameter of 1 8 〇 # m prepared by using polytetramethylpentene-1 as a raw material The hollow fiber sheets 4 (see FIGS. 5 and 7) which are woven by a plurality of hollow fibers 2 in the same direction and which are woven in the warp 2b are loaded into an appropriate size. Hollow wire-12- 200948463 The width of the sheet 4 (the dimension in the direction of the hollow fiber 2) is 'several multiple of the length of the frame body 5a of the receiving tow 3' and the length of the hollow fiber sheet 4 (the direction of the filament 2b) The size) is such that when the hollow fiber sheet 4 which is cut is stretched while being stretched by an appropriate tensile force and attached to a temporary core to be described later, the outer diameter of the original roller is made smaller than the inner diameter of the frame body 5a. Further, in the present embodiment, the unit roll is obtained in order to cut the original roll into two pieces. Although the width of the hollow fiber sheet 4 is made to be twice as long as the length of the frame body 5a, the production of the original roll is omitted. When the unit roller is produced from the beginning, the width of the hollow fiber sheet 4 may be longer than the width of the frame body 5a. In this case, the cutting process of the original roller described later may be omitted. (Rolling of Hollow Wire Sheet) A resin tube (temporary core) 11 having a longer width than the hollow fiber sheet 4 is prepared. Further, as shown in Fig. 7, after the longitudinal direction of the resin tube 11 is aligned with the width direction of the hollow fiber sheet 4 and the end of the resin tube 11 is slightly left, the hollow fiber sheet 4 is pulled with an appropriate pulling force. The stretched roll is attached to the resin tube 11». In addition, the number of times of attachment is only one, but the effective film area of the tow 3 in the frame body 5a (hollowed to the liquid) is practically observed. The total area of the surface of the wire 2 is preferably from 0.005 m2 to 1.0 m2, and more preferably from 0.01 m2 to 0.5 m2. Further, as the 塡 charging rate (the difference between the sectional area of the main body 5a and the area of the central hole 3a, divided by the sum of the sectional areas of the respective hollow fibers 2, expressed as a percentage), it becomes 5% to 50%. Preferably, it is preferably 10% to 40%, and particularly preferably 20% to 30%. (Temporary fixation of hollow fiber sheet) 200948463 A temporary resin-made temporary fixing sheet 12 is prepared. Further, as shown in Fig. 8, the temporary fixing sheet 12 is wound and adhered to the outer periphery of the hollow fiber sheet 4 which is wound around the resin tube 11 without any clearance. When the temporary fixing sheet 12 is wound around the outer periphery of the hollow fiber sheet 4, the end of the temporary fixing sheet 12 is joined to the temporary fixing sheet 12 itself so that the hollow fiber sheet 4 does not separate from the resin tube 11. Thereafter, it is placed in a predetermined temperature environment for a predetermined period of time. (Cutting of the original roll) © Regarding the original roll of the hollow fiber sheet 4 wound around the resin tube 11, as shown in Fig. 9, the resin tube 1 1 is slightly shifted from the hollow fiber sheet 4, and then a tube cutter is used. The hollow fiber sheet 4 is cut. At this time, the width of the hollow fiber sheet 4 is made longer than the frame body 5a of the receiving tow 3. The above-described cutting operation was repeated, and the hollow fiber sheet 4 was wound around the original roll of the resin tube 1 1 and cut into a plurality of unit rolls Ru. Thereafter, the resin tube 11 is slightly shifted from the hollow fiber sheet 4 with respect to the unit roller Ru cut into each, so that both ends of the resin tube 1 1 are slightly left from the hollow fiber sheet 4. ® (tow-end seal) After the release mold is applied with the release agent, an unhardened sealing resin (for example, urethane resin, epoxy resin, ultraviolet ray) is injected into the recess 13 3 a of the stationary mold π. Hardened resin, etc.) E1. Next, as shown in Fig. 1, the shaft 14 standing upright on the stationary mold 13 is inserted into the hole of the resin pipe 11, and the unit roller Ru is erected on the stationary mold 13. The sealing resin E1 is supplied to one end of the unit roller Ru which is erected on the stationary mold 13. At this time, the temporary fixing sheet 12 is moved upward from the -14-200948463 hollow fiber sheet 4 so that the sealing resin E1 does not adhere to the temporary fixing sheet 12. As shown in Fig. 11, after the main body 5a is erected on the single Ru cover of the stationary mold 13, the temporary sheet 12 is removed from the unit roller Ru for a predetermined period of time. During this period, the sealing resin E1 will be joined to a plurality of hollow ends of one end of the tow 3 which are hardly arranged around the resin tube 11, and the hollow holes 2a opened at one end of the tow 3 will be sealed (refer to Fig. 3). ). Furthermore, the tow 3 is integrated into the body 5a of the frame. At the other end of the structural body 5a, a process of sealing as described later is integrally formed to supply the sealing resin E2 to the other 5d of the tow 3. After the top cover 5d is finally hardened by the structural body 5a (the resin tube is removed) by the sealing resin E1, as shown in Fig. 12, the unit roller ru of the inner side of the frame body 5a is placed by the stationary mold 13® from the unit roller. Ru pulls out the resin tube 11. The inside of the resin body 11 is taken out and only the tow 3 is left inside the body 5a, and the central hole 3a is opened [(the seal at the other end of the tow). After the release of the release agent by the centrifugal sealing mold 15, the centrifugation is performed. The concave portion 15 5 of the dense 15 is injected with an uncured sealing resin (for example, a urethane epoxy resin, an ultraviolet curable resin, or the like) U. Next, as shown in the figure, the frame body 5a of the tow 3 is housed, and the other end thereof is centrifugally sealed to the mold 15. The sealing resin U is supplied to the other end of the tow 3 housed in the frame body 5a of the vertical sealing die 15. The frame body 5a to be erected on the centrifugal seal mold 15 is placed both. The roller is fixedly thinned, and the end of the wire 2 of the wire 2 is cut by the centrifugal end cap. Fixed under ί, and, after the sealing mold resin, 13 is erected after standing at the time, when the sealing resin U is hardened, as shown in Fig. 14, the sealing mold 15 will be joined. The frame body 5a is placed in a centrifugal seal. The device is supplied through the top cover 5d formed on the frame body 5a to the resin (for example, the other end of the urethane resin, the epoxy resin, the ultraviolet curing type 2 tow 3, from one end of the tow 3 toward the other The arrow symbol F at one end) causes the centrifugal force to act for a predetermined period of time. The dense 2 is hardened by being filled to the level of W in the figure, and is joined to the other end of the other plurality of hollow wires 2 of the tow 3, and the central hole 3a opened at the other end of the wire is sealed. (Refer to Fig. 4) (Resection of the top cover 5d) When the sealing resin E2 is hardened, as shown in Fig. 15, the disassembled frame body 5a is cut, and the top cover 5d and the centrifugal seal mold 15 body 5a are cut off. . Once the top cover 5d is cut, the hole 2a at the other end of each of the hollow fibers 2 at the end of the tow 3 is opened (the central hole is still sealed by the resin E2). (Installation of cover) Ο - The first cover 5b is attached to one end of the frame body 5a, and the second cover 5c is attached. If necessary, the first and second covers 5b and the body 5a are filled with an adhesive to reinforce. The hollow fiber module 1 for exhaust gas shown in Fig. 1 to Fig. 6 has been subjected to the above-mentioned "when the hollow fiber module for exhaust gas according to the present embodiment" has a plurality of hollow fibers 2 After the sheet 4 is attached to the resin tube 11 and held in a cylindrical shape, the resin tube 1 1 ' is removed from the hollow tube 4 that is held in a cylindrical shape, and the core seal is used to ensure the rigidity and the hollow fiber. (In the figure, the end of the sealing resin and the tow 3 of the bundle 3 are joined together from the other old nipple 5c and the frame is finished, and the core of the temporary core wire supporting base 16-200948463 is finished, but only In the method for manufacturing a hollow fiber module for exhaust gas according to the present embodiment, the hollow fiber sheet 4 is held in a cylindrical shape. Before the resin tube 11 is removed, the sealing resin E1 is supplied to one end of the hollow hollow fiber sheet 4, and one end of the plurality of hollow fibers 2 juxtaposed with one end of the hollow fiber sheet 4 is joined to each other while being placed on the hollow fiber sheet 4. The hole 2a of each hollow fiber 2 that is open at one end is dense Thereby, the cylindrical hollow fiber sheet 4 can form a central hole 3a parallel to the longitudinal direction of the hollow fiber 2. The central hole 3a of the hollow fiber sheet 4 is known in the conventional hollow fiber module for exhaust gas. In the hollow fiber module 1 for exhaust gas of the present embodiment which does not have a core, the central hole 3a can be easily secured by the above-described method. In the method for producing a hollow fiber module for exhaust gas, after the resin tube 1 is removed from the hollow fiber sheet 4 held by the cylindrical shape, the sealing resin E2 is supplied to the other end of the hollow hollow fiber sheet 4, and the hollow fiber is used. The other end of the plurality of hollow fibers 2 arranged side by side at the other end of the sheet 4 is joined to each other, and the other end of the central opening 3a opening at the other end of the hollow fiber sheet 4 may be filled with the sealing resin E2. The center of the hollow fiber sheet 4 The other end of the hole 3a is a hollow fiber module for exhaust gas which is sealed by a core as a support base. However, the hollow fiber module 1 for exhaust gas of the present embodiment which does not have a core may be used. Simply close the other end of the central hole 3 a. In the above embodiment, one end of the tow 3 is left to be sealed and the other end is a centrifugal seal, but the method of sealing is not required to be left standing or centrifuged. For example, one end of the unit roller may be centrifugally sealed and the other end may be left to stand. Sealing -1 7 - 200948463 Further, both ends of the unit roller may be statically sealed, and both ends may be centrifugally sealed. Next, a modification of the above embodiment will be described. (Modification 1) In the modification 1. As shown in Fig. 16, a plurality of through holes 16 are formed in the wall of the resin tube 11. Further, the inside of the resin tube 11 is attracted to a vacuum, and the hollow fiber sheet 4 is lifted through the through hole 16. The end is adsorbed to the resin tube 1 1. Thereby, the hollow fiber sheet 4 can be simply wound around the resin tube 11 . (Variation 2) In the second modification, as shown in Fig. 17, a plurality of claws 17 are formed on one of the outer circumferential surfaces of the resin tube 11 in the circumferential direction. Further, after the hollow fiber sheet 4 is hooked on the claw, the resin tube 11 can be wound around the resin tube 11 in a rotating manner in the direction of the claw 17. After the winding is completed, the resin tube 11 is slowly pulled out from the hollow fiber sheet 4 so that the resin tube 1 1 can be rotated in the reverse direction. Thereby, the hollow fiber sheet 4 can be simply wound around the resin tube 11. Further, the claws 17 can also be mechanically inserted and exited from the outer circumference of the resin tube 11. When the hollow fiber sheet 4 is wound around the resin tube 11, the claw 17 is protruded from the outer circumferential surface of the resin tube 11 to hook the hollow fiber sheet 4, and when the resin tube 11 is taken out from the hollow fiber sheet 4, the claw 17 is put into the resin tube. In the case of 1 1, the claws 17 can be taken out without interfering with the hollow fiber sheet 4, so that the hollow fiber sheet 4 is not injured. Although the preferred embodiments of the present invention have been described above, the present invention is not limited to the above embodiments. Additions, omissions, substitutions, and other changes may be made without departing from the scope of the invention. </ RTI> 18-.200948463 [Industrial use field] The present invention relates to a method for producing a hollow fiber module for exhaust gas which does not have a core, and relates to a method for producing a hollow fiber module for exhaust gas, which is provided with The periphery of the temporary core surrounds a process of a sheet containing a plurality of hollow filaments; a process of holding the sheet around the temporary core in a cylindrical shape; and a process of removing the temporary core from the sheet held in a cylindrical shape. According to the method for producing a hollow fiber module for exhaust gas according to the present invention, it is possible to satisfy the requirement of miniaturization by not holding a core as a support for securing rigidity and a hollow fiber, and at the same time, it can be manufactured simply and with high precision. A hollow fiber module for exhaust gas having a small pressure loss generated when a material to be processed is distributed. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a cross-sectional view showing a hollow fiber module for exhaust gas produced by the present invention, showing an embodiment of a method for producing a hollow fiber module for exhaust gas according to the present invention. Fig. 2 is a cross-sectional view showing the hollow fiber module for exhaust gas shown in Fig. 1. Figure 3 is an enlarged cross-sectional view of the lower end of the tow shown in Figure 1. Fig. 4 is an enlarged cross-sectional view showing the upper end of the tow shown in Fig. 1. Fig. 5 is an enlarged perspective view showing the hollow fiber sheet which becomes the root of the tow shown in Fig. 1. Fig. 6 is a schematic view for explaining the action of the hollow fiber mold group for exhaust gas shown in Fig. 1. Fig. 7 is a perspective view showing an embodiment of a method for producing a hollow fiber module for exhaust gas according to the present invention, in order to explain a process of attaching a sheet of a hollow fiber to a resin tube -19-200948463. Fig. 8 is a perspective view showing an embodiment of a method for producing a hollow fiber module for exhaust gas according to the present invention, in order to explain a temporary fixing process of a temporary fixing sheet by a hollow fiber sheet. Fig. 9 is a perspective view showing an embodiment of a method for producing a hollow fiber module for exhaust gas according to the present invention, in order to explain a process of cutting the original roller. Fig. 10 is a view showing an embodiment of a method for producing a hollow fiber module for exhaust gas according to the present invention, in order to explain the standing view of the static sealing process at one end of the tow. Fig. 1 is the same as Fig. 10, in order to explain a perspective view of the static sealing process at one end of the tow. Fig. 1 is a perspective view showing an embodiment of a method for producing a hollow fiber module for exhaust gas according to the present invention, in order to explain a process of extracting a unit roll from a resin tube. Fig. 1 is a view showing an embodiment of a method for producing a hollow fiber module for exhaust gas according to the present invention, and is a perspective view showing a centrifugal sealing process at the other end of the tow. Fig. 14 is the same as Fig. 3 to illustrate a perspective view of the centrifugal sealing process at the other end of the tow. Fig. 15 is a view showing an embodiment of a method of manufacturing the hollow fiber module for exhaust gas of the present invention, in order to explain the ηι» ΓαΤ body diagram of the process of cutting the top cover from the structure body. Fig. 16 is a view showing a modification 1 of the method for producing a hollow fiber module for exhaust gas according to the present invention, in order to explain a process of winding a hollow fiber sheet to a resin sheet -20-200948463. Fig. 17 is a view showing a modification 2 of the method for producing a hollow fiber module for exhaust gas according to the present invention, and is a perspective view for explaining a process of winding a hollow fiber sheet into a resin sheet. [Main component symbol description]

1 hollow fiber module 2 hollow wire 2a hole 2b warp (warp) 3 tow 3a central hole 4 hollow wire sheet 5 'frame 5 a frame body 5b, 5 c cover 5d top cover 6 ink discharge port 7 round 8 Claw 9 Ink introduction port 10 Suction port 11 Resin tube 12 Temporary fixing sheet 13 Resting mold - 21 - 200948463 14 Shaft 15 Centrifugal sealing mold El, E2, U Sealing resin ❹

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Claims (1)

200948463 X. Patent application scope: 1. A method for manufacturing a hollow fiber module for exhaust gas, characterized in that: a winding process is performed, around a temporary core, a sheet containing a plurality of hollow fibers is wound; The sheet wound around the temporary core is held in a cylindrical shape; and a removal process is performed to remove the temporary core from the sheet held in a cylindrical shape. 2. The method of manufacturing a hollow fiber module for exhaust gas according to the first aspect of the invention, wherein the resin is supplied to one end of the sheet held in a cylindrical shape, and the plurality of strips are juxtaposed with one end of the sheet. One end of the wire is joined to each other while the hole of each hollow fiber opening at one end of the sheet is sealed, and after the resin is hardened, the temporary core is removed from the sheet. 3. The method for producing a hollow fiber module for exhaust gas according to the first or second aspect of the invention, wherein the resin is supplied to the other end of the sheet from which the temporary core is removed, and the plurality of sheets are juxtaposed with the other end of the sheet. The other ends of the hollow fibers are joined to each other while the opening at the other end of the sheet is filled with the resin. -twenty three -