JPH1057782A - Hollow fiber sheet material, its production and production of hollow fiber membrane module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a production method of a hollow fiber membrane module so as to always obtain a product of uniform performance and high quality. SOLUTION: Hollow fibers (a) comprising a thermoplastic resin are substantially arranged parallel to each other as wefts. The arrangement of the wefts is held by filaments (b) as warps of a sheet to obtain a sheet-type hollow fiber fabric. The sheet-type hollow fiber fabric is continuously traveled parallel to the warps, while a thin film type fused thermoplastic resin is applied in the area on one or both ends of the sheet parallel to the filaments (b) within 10cm distance from the edges to form a thermoplastic resin joining part (c). Thus, a hollow fiber sheet material 9 is produced, which is formed into a cylinder, column or sheet to obtain a hollow fiber membrane module.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hollow fiber sheet and a hollow fiber membrane module useful for purposes such as separation and purification of a fluid, and more particularly to a hollow fiber membrane module capable of improving the strength of a hollow fiber membrane module. The present invention relates to a fibrous sheet, a method for producing the same, and a method for producing a hollow fiber membrane module using the same.

[0002]

2. Description of the Related Art Hollow fiber membrane modules are used in the fields of producing sterile water, drinking water and high-purity water, purifying air, washing and purifying solvents used in the field of semiconductors, and the like. The hollow fiber membrane module is a module in which a hollow fiber bundle consisting of a plurality of hollow fibers is fixed to a housing with a potting resin and integrated, and in addition to a cylindrical or columnar module, the module may be in the form of a sheet or the like. There are types.

[0003] The hollow fiber membrane module has a uniform separation performance,
In addition to filtration performance, mechanical properties and solvent resistance are required, and development for optimizing these properties has been continued.
However, various problems that occur at the time of potting in which the hollow fiber bundle is fixed to the housing with a potting resin and integrated are one of the factors that limit the performance of the hollow fiber membrane module. Heretofore, gravity potting, centrifugal potting and the like have been well known as this potting method.

[0004] In the gravity potting method, hollow fibers are housed in a housing, and potting resin is filled into the ends thereof.
This is a method in which a potting resin is permeated, filled, and immobilized by gravity into the end of the hollow fiber bundle. In the centrifugal potting method, the hollow fiber bundle is inserted into the housing, the assembly is rotated at an intermediate point to generate a centrifugal force, and the potting resin is introduced into the outer side space near both ends of the hollow fiber bundle. This is a method of immobilization.

[0005]

The gravity potting method and the centrifugal potting method have various problems, for example, as follows. That is, there is a manual operation that requires labor. In addition, individual performance varies, and it is difficult to always obtain a product with uniform performance with high quality. Further, the potting resin tends to be sucked up along the dry portion of the hollow fiber, particularly during the dipping process, and it is difficult to arrange the potting resin at the always required potting position.

The present invention has been made in view of the above circumstances, and has as its object to manufacture a hollow fiber membrane module capable of always obtaining high quality products with uniform performance by minimizing laborious manual operations. And

[0007]

According to the present invention, there is provided a sheet-shaped hollow fiber in which hollow fibers are arranged as wefts substantially in parallel with each other, and the arrangement interval of the hollow fibers is maintained by filaments constituting warp yarns. A hollow fiber sheet-like material provided with a thermoplastic resin joint having a width of 10 cm or less from one end or both ends of the fiber woven fabric in parallel with the warp yarn by a method as shown below. The means for solving the above-mentioned problem is that the hollow fiber sheet is manufactured and made into a hollow fiber membrane module having a cylindrical shape, a column shape, a sheet shape, or the like by using a fixing resin made of a thermoplastic resin. That is, the thermoplastic resin joint portion of the hollow fiber sheet is potted at a predetermined position in the cartridge housing with a fixing resin to form a hollow fiber membrane module.

The hollow fiber sheet can be manufactured by the following method. That is, the sheet-like hollow fiber woven fabric in which the intervals between the hollow fibers arranged as the weft are held at a constant interval by the filaments arranged as the warp is continuously transferred in a direction parallel to the warp (filament). A thin-film molten thermoplastic resin (hereinafter abbreviated as a thin-film molten resin) is supplied to one or both of the ends parallel to the warp of the hollow fiber woven fabric within a range of 10 cm or less from this end. Then, the ends of the sheet-like hollow fiber fabric are joined to form a thermoplastic resin joint (hereinafter abbreviated as a resin joint) to form a hollow fiber sheet. At this time, the melt flow rate of the thin-film molten resin is preferably 20 to 150. Further, it is preferable that the temperature of the thin-film molten resin at the time of contact with the sheet-like hollow fiber fabric is equal to or higher than the melting point of the hollow fiber material, because the state of adhesion between them is good. In addition, the above-mentioned thin film molten resin is
It can be supplied to one or both sides of the sheet-like hollow fiber fabric.

Further, when the thin-film molten resin is supplied to the sheet-like hollow fiber woven fabric, if the relationship represented by the following formula I is satisfied, the heat capacity of the thin-film molten resin is set to be equal to or less than the heat capacity of the hollow fiber. Therefore, heat shock when the thin film-shaped molten resin comes into contact with the hollow fiber is small and damage to the hollow fiber is small, which is preferable. W1 · C1 (T−T1) ≧ W2 · C2 (T2−T) (I) Here, the symbols in the above formula I represent the following. C1: Material specific heat of hollow fiber material T: Melting point of hollow fiber material W1: Unit weight of hollow fiber C2: Material specific heat of molten thermoplastic resin W2: Unit weight of molten thermoplastic resin T1: Melt thermoplastic resin and hollow fiber T2: Temperature of the molten thermoplastic resin when the melted thermoplastic resin and the hollow fiber come into contact with each other.

A hollow fiber membrane module using such a hollow fiber sheet can be manufactured by the following method. That is, the above-mentioned hollow fiber sheet-like material is housed so that the resin joint thereof penetrates the potting portion in the cartridge housing, and the fixing resin made of a thermoplastic resin is sealed and fixed in the potting portion of the cartridge housing. Then, perpendicular to the hollow fibers constituting the hollow fiber sheet, and cut the potting portion penetrating end of the hollow fiber sheet so as to cross the resin joint, to open the hollow fiber It is a hollow fiber membrane module.

[0011]

FIG. 1 shows an example of a process for producing a hollow fiber sheet according to the present invention. FIG.
Shows an example of a sheet-like hollow fiber woven fabric used for producing the hollow fiber sheet-like material of the present invention. FIG. 3 shows an example of the hollow fiber sheet material of the present invention in which a resin joint is provided on the sheet hollow fiber fabric shown in FIG.
FIG. 4 is a cross-sectional view taken along line AA ′ shown in FIG.

In FIG. 1, reference numeral 1 denotes a sheet-like hollow fiber woven fabric. As shown in FIG. 2, the sheet-like hollow fiber woven fabric 1 has hollow fibers a made of a plurality of thermoplastic resins arranged in parallel. Are weft yarns, and the spacing between the hollow fibers a is held by filaments b constituting warp yarns. In addition, a hollow fiber is folded a plurality of times at both ends parallel to the warp, arranged substantially in parallel to form a weft, and the weft is held together by filaments constituting the warp. It can also be used.

As the hollow fiber a, a general one made of a polyolefin resin such as polyethylene, polypropylene, poly-4-methylpentene-1, a polyester resin, a polycarbonate resin, a polyacrylonitrile resin, a polysulfone resin or the like is used. It is possible to select a material suitable for the characteristics of the separation substance or other required characteristics in the intended use of the hollow fiber membrane module. The shape of this hollow fiber a
The diameter, porosity, film thickness, outer diameter and the like are not particularly limited and are appropriately selected. Further, as a holding method using the filament b for forming the hollow fiber a into a sheet shape, for example, a known method using a monofilament or multifilament polyester fiber or the like can be appropriately used.

In manufacturing the hollow fiber sheet material, as shown in FIG. 1, it is preferable that the sheet fiber hollow fiber fabric 1 is previously wound so that the hollow fiber a is not bent. . On the other hand, on the upstream side of the drive roll 2, there are provided two series of thin-film molten resin supply means including a resin fixed amount supply device 3, a resin liquid supply pipe 4, and a discharge die 5. Only one series). The discharge dies 5 constituting these thin-film molten resin supply means are arranged in parallel to the rotation axis direction of the bottom roll 7 so that two rows of the thin-film molten resin 6 are fed onto the bottom roll 7. It has become. That is,
The thin-film molten resin supply means includes a filament for the sheet-like hollow fiber fabric 1 in which the two rows of thin-film molten resin 6 are supplied onto the thin-film molten resin 6 on the bottom roll 7 in a later step. (Warp) 1 each from both ends parallel to b
It is arranged to be supplied within 0 cm, substantially up to a position of 4 to 10 cm. Sheet-shaped hollow fiber fabric 1
In the case where the thin film molten resin 6 is supplied to only one end, only one thin film molten resin supply means may be provided.

First, the sheet-like hollow fiber fabric 1 is
It is pulled out by a pair of drive rolls 2 having a constant peripheral speed.
The drawing method is not limited, and any structure that does not adversely affect the performance required for the hollow fiber sheet material 9 can be used. On the other hand, in the two series of thin film molten resin supply means, the material of the thin film molten resin 6 is supplied to the resin quantitative supply machine 3, passes through the resin feed pipe 4 in a fixed amount in the molten state, and is discharged by the discharge die 5. The thin film-like molten resin 6 in a row is supplied onto the bottom roll 7.

Next, the filament (warp) of the sheet-like hollow fiber fabric 1 drawn by the driving roll 2
Both ends parallel to b are superimposed on two rows of the thin film molten resin 6 on the bottom roll 7. Further, two lines of thin-film resin in the same manner as the thin-film molten resin 6 are obtained from two series of resin quantitative feeders 3 ′, resin feeding pipes 4 ′, and discharge dies 5 ′ arranged downstream of the drive roll 2. The molten resin 6 ′ is sent out and is superimposed on the two rows of thin-film molten resin 6 via the sheet-like hollow fiber fabric 1 on the bottom roll 7. These thin film-like molten resins 6,
6 'may be supplied to at least one surface of the sheet-like hollow fiber fabric 1. However, by supplying both of the thin-film molten resins 6 and 6 ′, both surfaces of the sheet-like hollow fiber fabric 1 are covered with the thin-film molten resins 6 and 6 ′, and the resin is more between the hollow fibers a. It is preferably densely packed, because the strength of the hollow fiber sheet or hollow fiber membrane module is improved.

The thin-film molten resin 6, 6 'is made of at least one kind of thermoplastic resin, and its JIS K7
The melt flow rate defined by 210 is 20 or more, preferably 20 to 150, more preferably 40 to 100. Specific examples include polyethylene, wax, a mixture of wax and polyethylene, polyvinyl acetate, and the like.In particular, when solvent resistance is required, a polyolefin resin is preferable, and in this case, the price is low. It is economical.

Since the thermoplastic resin having the above-mentioned melt flow rate has a good fluidity in a molten state, the thin-film molten resin 6, 6 'enters between the hollow fibers a, and is filled without gaps. In addition, since the thin film-like molten resins 6 and 6 ′ are sufficiently adhered to each other, no gap is formed inside the resin joints c and c shown in FIGS.

When the melt flow rate exceeds 150,
In some cases, the resin joints c are too soft to have a uniform and appropriate thickness. Particularly, the thin film molten resin 6, 6 'is not retained on both surface portions of the sheet-like hollow fiber fabric 1, and the resin joints c, c on both surface portions of the sheet-like hollow fiber fabric 1 are not held.
In some cases, the strength of the hollow fiber sheet-like material and the hollow fiber membrane module may be reduced. It is preferable that the filling of 'is sufficiently performed.

The temperature of the thin-film molten resin 6, 6 'when the thin-film molten resin 6, the sheet-like hollow fiber fabric 1, and the thin-film molten resin 6' are sequentially superimposed depends on the heat of the material of the hollow fiber a. It is preferable that the temperature is controlled to be equal to or higher than the melting point of the plastic resin, and the temperature is substantially 1 to 30 ° C. higher than the melting point.
It is preferably adjusted by the supply amount of 6 ′. This improves the adhesiveness between the thin-film molten resin 6 and 6 ′ and the hollow fiber a that has come into contact with the thin-film molten resin 6,
The bonding state between 6 ′ and the hollow fiber a is improved.

Further, at this time, it is preferable that the relationship of the following formula I is satisfied. In the following formula I, the left side shows the heat capacity of the hollow fiber a, and the right side shows the heat capacity of the thin film molten resin (melt thermoplastic resin) 6, 6 ′. That is, by setting the heat capacity of the thin-film molten resin 6, 6 'to be equal to or less than the heat capacity of the hollow fiber a, the thin-film molten resin 6, 6'
The heat shock of the hollow fiber a due to the contact with the substrate can be softened.

In the formula (I), when the left side and the right side satisfy the relation of being connected by an equal sign, most of the resin constituting the hollow fiber a is melted, but the melting may cause the inside of the hollow fiber a to be closed. However, the internal shape of the hollow fiber a is maintained. When the left side is larger than the right side, a part of the hollow fiber a is melted.

W1 · C1 (T−T1) ≧ W2 · C2 (T2-T) (I) Here, the symbols in the above formula I represent the following. C1: Material specific heat of hollow fiber material T: Melting point of hollow fiber material W1: Unit weight of hollow fiber C2: Material specific heat of molten thermoplastic resin W2: Unit weight of molten thermoplastic resin T1: Melt thermoplastic resin and hollow fiber T2: Temperature of the molten thermoplastic resin when the melted thermoplastic resin and the hollow fiber come into contact with each other.

Further, when the thin-film molten resins 6, 6 'are supplied onto the bottom roll 7, it is necessary to avoid excessive cooling of the thin-film molten resins 6, 6' and to appropriately control the temperature thereof. Preferably, the bottom roll 7 has a structure whose surface temperature can be controlled. As this control method,
For example, known methods such as a heater, temperature control air, and a heat medium can be used, and it is more preferable to perform accurate temperature control by using a combination of these methods.

The resin metering devices 3 and 3 'are, for example, extruders and gear pumps, and can be used as long as they have the same performance. Further, these preferably have a heating mechanism for melting the resin. The resin feed pipes 4 and 4 'preferably have a heating mechanism for feeding the resin quantitatively supplied from the resin quantitative supply devices 3 and 3' to the discharge dies 5 and 5 'in a molten state. It is preferable that the discharge dies 5 and 5 'have the same heating mechanism. As mentioned above,
The surface temperature of the above-described bottom roll 7 is controlled by controlling these heating mechanisms by using a resin fixed amount feeder 3, 3 ′ resin feeding pipe 4, 4 ′ discharge die 5, 5 ′ having a heating mechanism. It is also possible to control the temperature of the thin-film molten resins 6, 6 'when the thin-film molten resins 6, 6' and the sheet-like hollow fiber fabric 1 are overlapped with each other to be equal to or higher than the melting point of the hollow fibers a. it can.

Next, a laminate composed of the thin-film molten resin 6, the sheet-like hollow fiber fabric 1, and the thin-film molten resin 6 'is pressed by a nip roll 8, and the thin-film molten resin 6, 6' is sheeted. Impregnated into the hollow fiber woven fabric 1 as shown in FIGS.
The hollow fiber sheet-like material 9 formed with the resin joints c, c as shown in FIG. The pressure applied by the nip roll 8 is preferably adjusted so that the hollow fibers a are not crushed and a gap is not generated between the thin-film molten resins 6, 6 ′ and the hollow fibers a.

Further, the hollow fiber sheet material 9 is forcibly cooled by pressurized air or the like, if necessary, before being guided to the nip roll 11 by the guide rolls 10, so that the resin joints c, c are formed. It is solidified and wound up by the winding section 13 via the nip roll 11. In addition, in the winding section 13, when a cylindrical hollow fiber membrane module is intended, the hollow fiber sheet-like material 9 is used.
May be used.

The range of formation of the resin joints c, c is within a range of 10 cm or less, substantially 4 to 10 cm, respectively, from both ends of the sheet-like hollow fiber fabric 1. The reason for setting the range to 10 cm or less is that a hollow fiber membrane module is prepared using the hollow fiber sheet material 9 of the present invention, so that the filtration function of the hollow fibers does not decrease.

As shown in FIG. 4, the resin joints c, c of the hollow fiber sheet material 9 manufactured as described above are filled with resin between the hollow fibers a, and the sheet-like hollow fiber fabric 1 (hollow fiber a) is formed so as to be covered with a resin. These resin joints c, c and hollow fiber a
Are sufficiently adhered to each other without gaps. There is no gap inside the resin joints c. For this reason, the hollow fibers a are sufficiently bundled and fixed, and the strength of the hollow fiber sheet 9 and the hollow fiber membrane module formed from the hollow fiber sheet 9 can be increased.

The state of the irregularities on the surfaces of the resin joints c, c is determined by the amount of the thin-film molten resin 6, 6 'supplied and the hollow fiber a.
Is determined by the outer diameter and the spacing of the array. That is, the resin supply amount of the thin film-like molten resin 6 is large, and the hollow fibers a
When the outer diameter is small and the arrangement interval of the hollow fibers a is small, the surface of the resin joints c and c becomes smooth, and when the opposite, the unevenness is easily formed. The resin supply amounts of these thin film-like molten resins 6 and 6 ′, the outer diameter of hollow fibers a and the arrangement intervals, etc. are determined by the volume ratio of hollow fibers a required in the hollow fiber membrane module formed from the hollow fiber sheet material 9. Determined by

According to the method for producing the hollow fiber sheet material 9 described above, most of the production steps can be performed mechanically and continuously. Further, by adjusting the supply position of the sheet-like hollow fiber fabric 1 and the thin-film molten resin 6, 6 ′ to the bottom roll 7 and the width of the thin-film molten resin 6, 6 ′, the resin joint c, c The formation position and range can be adjusted, and the resin joints c can be provided at required positions. Further, when the thin film-like molten resin 6, 6 ′ and the sheet-like hollow fiber fabric 1 are overlapped,
Since the temperature of 6 ′ is controlled to be equal to or higher than the melting point of the material of the hollow fiber a, the hollow fiber a in contact with the thin film-shaped molten resin 6, 6 ′ adheres tightly and can adhere sufficiently firmly.

Further, the melt flow rate of the thin film-like molten resin 6, 6 'constituting the resin joints c, c is 20 or more, preferably 20 to 150, more preferably 40 to 150.
Since a thermoplastic resin that satisfies the condition of 100 and has good fluidity in the molten state is used, when forming the resin joints c, c, the thin film-like molten resin 6, between the hollow fibers a, The thin-film molten resins 6 and 6 ′ into which the thin-film molten resin 6 and 6 ′ overlap each other via the sheet-like hollow fiber fabric 1 are in contact with and adhere to each other between the hollow fibers a. , And the hollow fiber sheet-like material 9 in which the hollow fibers a and the resin joints c, c are sufficiently bonded to each other can be obtained. At this time, when the above-mentioned formula I is satisfied, the heat shock when the thin film-like molten resin 6, 6 ′ comes into contact with the sheet-like hollow fiber fabric 1 is small,
This is preferable without damaging the hollow fiber a.

As described above, since there is no gap inside the resin joints c, c, and the hollow fibers a and the resin joints c, c are sufficiently bonded, the hollow fiber sheet 9 or the hollow fiber fiber sheet 9 will be described later. Even when stress is applied to the hollow fiber membrane module using the hollow fiber sheet material 9 from the outside, the resin joints c and c do not peel off from the hollow fiber a, and the hollow fiber sheet material 9 and the hollow fiber The mechanical strength of the membrane module can be improved.

The conditions for selecting the thermoplastic resin forming the hollow fiber a and the resin joints c, c (thin film-like molten resin 6, 6 ') are as follows: the melting temperature of the material of the resin joints c, c; Only the rate (20 or more) is not affected by each melting point. Therefore, the material of the hollow fiber a can be freely selected, a wide combination of the material of the hollow fiber a and the material of the resin joints c and c is possible, and the required chemical properties such as solvent resistance are also required. Performance can be supported.

As described above, it is possible to carry out most of the steps mechanically and continuously, and to obtain the hollow fiber sheet-like material 9 in which the hollow fibers a and the resin joints c, c are sufficiently bonded. Therefore, it is possible to manufacture a hollow fiber sheet-like material 9 having high performance and small variations in performance of individual products and a hollow fiber membrane module using the same, which is efficient and economical. Is also excellent.

A hollow fiber membrane module having a sheet shape, a cylindrical shape, a columnar shape or the like is manufactured using the hollow fiber sheet material 9 described above. FIG. 5 shows an example of a method of manufacturing a sheet-like hollow fiber membrane module capable of processing two hollow fiber sheet-like materials 9 at a time, and FIG.
(B) is a side view. In the figure, reference numeral 20 denotes a cartridge housing. The cartridge housing 20 is a plate-like frame in which slits (potting portions) 24 for inserting the ends of two hollow fiber sheet-like materials 9 are formed. 23, a projection forming tool 21 having a recess 21a facing the lower surface of the plate-like frame 23, and a fixing jig 23b for fixing these. The slit 24, 2
Numeral 4 is for forming fixing portions d, d by potting described later around the hollow fiber sheet material 9 therein.

In order to manufacture a sheet-shaped hollow fiber membrane module, first, the convex forming tool 21 is housed in the accommodating portion 23a of the fixing jig 23b, and the lower surface of the plate-shaped frame 23 and the convex forming tool 21 The cartridge housing 20 is configured by being assembled so as to be in close contact with the upper end face of the cartridge. Next, the resin joints c, c at one end of the two hollow fiber sheet members 9, 9 are passed through slits 24, 24 provided in the plate-like frame 23, respectively. It is inserted into the recess 21a.
A molten fixing resin 22 made of a thermoplastic resin is injected into the concave portion 21 a of the convex forming tool 21 and the slits 24, 24 of the plate-like frame 23, and the convex forming tool 2 is formed.
1, a convex portion 22a is formed, and a hollow fiber sheet-like material 9,
9 is sealed and fixed.

After the fixing resin 22 is solidified, the plate-like frame 23
And the convex part forming tool 21 is taken out from the fixture 23b, and between the lower surface of the plate-shaped frame 23 and the upper end face of the hollow forming tool 21 (arrow B in the figure), perpendicular to the hollow fiber a,
Further, one end of the hollow fiber sheet 9 (9) is cut so as to intersect with the resin joints c, c, and the hollow fiber is opened to open the hollow fiber. The fixing portions d, d made of the fixing resin 22 are formed. The same operation is performed for the resin joints provided at the other ends of the hollow fiber sheet materials 9, 9 to obtain a sheet-like hollow fiber membrane module having both ends opened.

FIG. 6 shows an example of a method for manufacturing a hollow fiber membrane module having a cylindrical or columnar shape. The main difference between the cartridge housing 20 shown in FIG. 5 and the cartridge housing 30 shown in FIG. 6 is that the slit 24 is replaced by the outer periphery of a target hollow or cylindrical hollow fiber membrane module. Here, a plate-shaped frame 33 having a circular insertion portion (potting portion) 34 is formed. The insertion portion 34 is for forming a fixing portion d ′ made of a fixing resin (potting resin) described later around the hollow fiber sheet material 9 therein.

First, the convex forming tool 31 is housed in a storage portion (not shown) of the fixing jig 33b, and the lower surface of the plate-like frame 33 is brought into close contact with the upper end surface of the convex forming tool 31. The cartridge housing 30 is assembled. Then, as shown in FIG.
The resin joining portion c at one end of the wound material 9a formed by being wound by the above is inserted through the insertion portion 34, and the convex forming tool 31 is formed.
Into the recess 31a. Then, the fixing resin 32 in a molten state is injected into the concave portion 31a of the convex forming tool 31 and the insertion portion 34 of the plate-shaped frame 33 to form the convex portion 32a in the convex forming tool 31, Seal the end of the winding 9a,
Fix and fix.

After the fixing resin 32 is solidified, the plate-like frame 33
And the convex forming tool 31 are taken out from the fixing tool 33b, and between the lower surface of the plate-shaped frame 33 and the upper end face of the hollow forming tool 31 (arrow B 'in the figure), perpendicular to the hollow fiber a, and The hollow fiber sheet-like material 9 is intersected with the resin joint c.
One end (a potting portion penetrating end) of the wound material 9a made of
And a fixing resin 32 are formed. The same operation is performed on the resin joint provided at the other end of the roll 9a to open both ends of the roll 9a to obtain a cylindrical or columnar hollow fiber membrane module.

At this time, when a mandrel is used in the winding section 13 in the production of the hollow fiber sheet-like material 9 shown in FIG. 1 described above, the mandrel is formed into a cylindrical hollow fiber membrane module, It may or may not be removed, and its presence or absence is preferably determined by the required specifications of the hollow fiber membrane module. When removing the mandrel, in the hole after removing the mandrel,
It is a well-known method to inject the molten thermoplastic resin and stop the holes, but also in this case, it is natural to take care that there is no gap between the shot resin and the roll.

For this reason, the same resin as the fixing resin 32 is used as the shot-preventing resin, and this resin is injected in a heated and molten state into the hole after the mandrel is removed. Then, the fixing portion d ′ in contact with the resin is partially melted, and the shot-proof resin and the fixing portion d ′ can be integrated,
The mechanical strength of the hollow fiber membrane module can be improved.

In the production of the above-mentioned sheet-like, cylindrical or cylindrical hollow fiber membrane module, a sudare knitting sheet is used as the sheet-like hollow fiber woven fabric 1, and a plurality of discontinuous hollow fibers a are formed of the sheet. Since weft yarns were formed, resin joining portions c, c were provided at both ends thereof to obtain a hollow fiber sheet-like material 9. When a Russell knitted sheet is used as the sheet-like hollow fiber fabric 1, the adjacent weft yarns are connected to each other, so that only one end is provided with a resin joint c to obtain a hollow fiber sheet 9. Often. It is preferable to use the same resin as the material of the resin joining portion c as the fixing resins 22 and 32 because the adhesion state is good. Also, the front cartridge housing 2
The range in which the hollow fiber sheet-like material 9 is inserted into 0, 30 is:
It is 2 to 7 cm from the end of the hollow fiber sheet material 9.

In the production of the above-mentioned hollow fiber membrane module, the hollow fiber a is provided with a resin bonding portion c which is in close contact with the hollow fiber a without any gap and in which no void is present. Since the fibrous sheet material 9 is used, the resin bonding portion c and the fixing resin 2 are compared with a case where the fixing resin in a molten state is directly sealed at the end of the bundle of the hollow fibers a.
A gap is rarely formed in the fixed portions d and d ′ formed by the components 2 and 32. That is, the fixing resin 22 in the case of the sheet-shaped hollow fiber membrane module may have a role of flattening the surface of the fixing portion d and further improving its strength. Further, the fixing resin 32 in the case of manufacturing a hollow fiber membrane module having a cylindrical shape or a cylindrical shape,
It is only necessary to bond the plurality of layers of the hollow fiber sheet material 9 constituting the winding material 9a to each other, maintain the cylindrical or columnar shape, and play the role of flattening the surface of the fixing portion d '.

Further, since the hollow fiber a is protected by the resin joint c, the fixing resin 22 in the molten state
Even if 32 is enclosed, the hollow fiber a is less likely to be directly damaged by heat, and the fixing resin in a molten state is sucked up by the hollow fiber a, so that the positions of the fixing portions d and d ′ are shifted. Nothing. Thus, compared to the case where the fixing resin in the molten state is directly sealed at the end of the bundle of the hollow fibers a, the bonding state between the fixing parts d and d ′ and the hollow fiber a is better, and these fixing parts d and d 'A high-strength hollow fiber membrane module free of voids or the like inside can be stably obtained.

[0047]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail with reference to embodiments. (Example 1) A hollow fiber sheet as described above,
A hollow fiber membrane module using this was manufactured. However,
Since a Russell knitted sheet was used as the sheet-like hollow fiber fabric, the resin joint was formed only at one end of the sheet-like hollow fiber fabric, and only one end was opened using the hollow fiber sheet-like material. The cylindrical hollow fiber membrane module thus manufactured was manufactured.

As the sheet-like hollow fiber fabric, EHF410A (Russell knitted sheet) manufactured by Mitsubishi Rayon Co., Ltd. was used. The hollow fibers constituting the sheet-like hollow fiber fabric have an average outer diameter of 415.8 μm and an average inner diameter of 279.8 μm.
The constituent material is polyethylene resin, the melting point is 136 ° C., the porosity is 71.2%, and the specific heat of the material is 0.5.
0 and the unit weight was 0.02 g / m ² . This sheet-shaped hollow fiber fabric had a width of 265 mm, and the distance between adjacent hollow fibers was 0.7 mm as the center-to-center distance of the hollow fiber cross section. As a material for the resin joint, Mirason (product code FL60) manufactured by Mitsui Petrochemical Co., Ltd. was used.
The material of the resin joint has a melting point of 106 ° C., a melt flow rate of 70, a specific heat of 0.50, and a unit weight of 0.9 g / c.
c.

First, as shown in FIG. 1, the sheet-like hollow fiber fabric 1 was pulled out by the driving roll 2 at a pulling-out speed of 500 mm / min. At this time, the temperature of the sheet-like hollow fiber fabric 1 was 25 ° C., which was equivalent to room temperature. On the other hand, a sheet-like thin-film molten resin 6 having a width of 40 mm,
6 ′, one from each of the ejection dies 5 and 5 ′,
The resin metering devices 3 and 3 ′ were driven such that the resin was supplied at a rate of about 3.4 cc / min. At this time, the temperature of the thin-film molten resins 6 and 6 ′ was 145 ° C.

The above-mentioned thin film molten resin 6, 6 ′ and one end of the sheet-like hollow fiber fabric 1 are overlapped on a bottom roll 7. 6 'is supplied, the nip roll 8 is pressed against the laminate so as to have a linear pressure of 200 g / 40 mm, and impregnated with a resin, as shown in FIG. 2, but having a resin joint c at only one end thereof. The hollow fiber sheet 9 was obtained. At this time, the value on the left side in the formula I is 34.88.
And the value on the right-hand side was 27.54.
The relationship was satisfied.

Until the hollow fiber sheet material 9 is guided to the nip roll 11 by the guide rolls 10, forced cooling is performed by pressurized air to solidify the resin joint c at a temperature equivalent to room temperature. The film was taken up by a take-up unit 13 via the cable 11.

Using the hollow fiber sheet material 9 thus manufactured, a cylindrical hollow fiber membrane module was manufactured as shown in FIG. At this time, the same resin as the resin constituting the resin joint c was used as the fixing resin 32, and the temperature in the molten state was 145 ° C. Further, the thickness of the fixing portion d ′ was 3 mm. Water pressure was applied to the fixed portion d 'of the hollow fiber membrane module so as to be 3 kg / cm ² , but no leak was observed.

(Embodiment 2) The difference between Embodiment 2 and Embodiment 1 is that the materials of the resin joint c and the fixing resin 32 are changed. That is, in Example 2, Sumikaron (product code G80) manufactured by Sumitomo Chemical Co., Ltd. was used.
6) was used. This material has a melting point of 104 ° C., a melt flow rate of 50, a specific heat of 0.50, and a unit weight of 0.92 g.
/ Cc. The temperature of the thin-film molten resins 6 and 6 ′ is 143 ° C., and the temperature of the fixing resin 32 in the molten state is 1 °.
40 ° C.

The hollow fiber membrane module of the second embodiment is fixed in the same manner as in the first embodiment.
Was applied with a water pressure of 3 kg / cm ² , but no leak was found from the boundary between the hollow fiber a and the fixing portion d ′.

Comparative Example A hollow fiber membrane module was produced in the same manner as in Example 1 except that the temperature of the thin film-like molten resin 6, 6 ′ was 115 ° C., that is, lower than the melting point of the constituent material of the hollow fiber a. Was manufactured. At this time, the value on the left side of Expression I was 34.88, and the value on the right side was -76.5. In the same manner as in Example 1, the fixing portion d of the hollow fiber membrane module of the comparative example was 3 kg / cm.
^{Although the} water pressure was applied so as to be ² , the bonding force between the hollow fiber a and the fixing portion d ′ (the resin bonding portion c) was weak, and a large number of leaks occurred from the boundary between these.

From the results of these examples and comparative examples, it was confirmed that in the example according to the present invention, a hollow fiber membrane module having a good bonding state between the hollow fiber a and the fixing portion d ′ and a high strength can be manufactured. Was.

[0057]

As described above, according to the present invention, most of the steps of manufacturing the hollow fiber sheet can be performed mechanically and continuously. Also, by adjusting the supply position of the sheet-shaped hollow fiber fabric and the molten thermoplastic resin to the bottom roll, the formation position of the thermoplastic resin joint can be adjusted, and the resin joint is provided at a required position. be able to.

Further, in forming the thermoplastic resin joint, when laminating the molten thermoplastic resin (thin film-shaped molten resin) and the sheet-shaped hollow fiber fabric, the temperature of the molten thermoplastic resin is adjusted to the hollow fiber material. Because it is controlled above the melting point,
Adhesion with the surface of the hollow fiber in contact with the molten thermoplastic resin is improved, and these are adhered sufficiently firmly.

Since the thermoplastic resin having a melt flow rate of 20 or more, preferably 20 to 150, more preferably 40 to 100 is used as the molten thermoplastic resin, the fluidity in the molten state is low. When forming a thermoplastic resin joint, the resin enters between the hollow fibers and is filled without gaps. Further, when the molten thermoplastic resin is supplied from both sides of the sheet-like hollow fiber fabric, the molten thermoplastic resins superimposed via the sheet-like hollow fiber fabric also contact each other between the hollow fibers and adhere to each other. Therefore, it is possible to obtain a hollow fiber sheet in which no gap exists inside the thermoplastic resin joint and the hollow fiber and the thermoplastic resin joint are sufficiently bonded. At this time, it is preferable that the above formula I is satisfied, since the heat shock to the hollow fiber when the molten thermoplastic resin comes into contact is small and the hollow fiber is hardly damaged.

As described above, since there is no gap inside the thermoplastic resin joint and the hollow fiber and the thermoplastic resin joint are sufficiently bonded, the hollow fiber fiber sheet and the hollow fiber sheet Even if stress is applied to the hollow fiber membrane module made of a material from the outside, the thermoplastic resin joint does not peel off from the hollow fiber, improving the mechanical strength of the hollow fiber sheet-like material and the hollow fiber membrane module Can be done.

Further, the selection of the thermoplastic resin as the material of the joint between the hollow fiber and the thermoplastic resin is limited only to the condition that the material of the thermoplastic resin joint has a melt flow rate of 20 or more. It does not depend on each melting point. Therefore, the material of the hollow fiber can be freely selected, a wide combination of materials for the hollow fiber and the thermoplastic resin joint can be obtained, and the required performance is also achieved with respect to the chemical properties such as solvent resistance. Can respond.

Further, most of the steps can be performed mechanically and continuously, and a hollow fiber sheet material in which the hollow fiber and the thermoplastic resin joint are sufficiently bonded can be obtained without fail. The dispersion of the performance is small, and a high-performance hollow fiber sheet can be stably manufactured.

In the method for manufacturing a hollow fiber membrane module of the present invention, a hollow fiber sheet provided with a thermoplastic resin joint in advance is used. Is previously provided with a thermoplastic resin bonding portion which is in close contact with the hollow fiber without any gap and has no voids inside. Therefore, as compared with the case where the fixing resin in a molten state is directly enclosed in the hollow fiber bundle, a gap is less likely to be formed in the thermoplastic resin joining portion and the fixing portion formed by the fixing resin.

Further, since the hollow fibers are protected by the thermoplastic resin bonding portion, the hollow fibers a are hardly directly damaged even if the fixing resin in a molten state is sealed, and the hollow fibers are hardly damaged. As a result, the fixing resin in the molten state is sucked up and the position of the fixing portion does not shift. In this way, the bonding state between the fixing portion made of the thermoplastic resin bonding portion and the fixing resin and the hollow fiber is good,
There is no void or the like inside the fixing portion, and a high-strength hollow fiber membrane module can be stably obtained.

As described above, since the hollow fiber sheet can be produced mechanically and continuously, the occurrence rate of defective products of the hollow fiber sheet and the hollow fiber membrane module using the same is low, and the efficiency is low. And economical.

[Brief description of the drawings]

FIG. 1 is a view showing an example of a method for producing a hollow fiber sheet according to the present invention.

FIG. 2 is a perspective view showing an example of a sheet-like hollow fiber fabric used in the present invention.

FIG. 3 is a perspective view showing an example of the hollow fiber sheet-shaped material of the present invention.

FIG. 4 is a cross-sectional view taken along line AA ′ of FIG. 3;

FIG. 5 is a view showing an example of a method for producing a sheet-like hollow fiber membrane module of the present invention.

FIG. 6 is a view showing one example of a method for producing a cylindrical or cylindrical hollow fiber membrane module of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Sheet-shaped hollow fiber fabric 9 Hollow fiber sheet-like material 20 Cartridge housing 22 Fixing resin 24 Slit (potting part) 30 Cartridge housing 32 Fixing resin 34 Insertion part (potting part) a Hollow fiber (weft) b Filament (warp) c Thermoplastic resin joint d, d 'fixing part

Claims (7)

[Claims] 1. A sheet-like hollow fiber woven fabric in which a large number of hollow fibers made of a thermoplastic resin are arranged substantially parallel to each other as weft yarns, and the arrangement interval of the weft yarns is held by filaments arranged as warp yarns. A hollow fiber sheet having a thermoplastic resin joining portion made of a thermoplastic resin provided on one or both of the ends parallel to the warp in a width within 10 cm from the end. Stuff. 2. A sheet-like hollow fiber woven fabric in which hollow fibers made of a thermoplastic resin are arranged substantially parallel to each other as weft yarns, and the arrangement interval of the weft yarns is held by filaments arranged as warp yarns. And a thin film molten thermoplastic resin is supplied to one or both ends of the sheet-like hollow fiber woven fabric parallel to the warp within a range of 10 cm or less from the end. Forming a thermoplastic resin joint to form a hollow fiber sheet, thereby producing a hollow fiber sheet. 3. The method for producing a hollow fiber sheet according to claim 2, wherein the melt flow rate of the thin film-shaped molten thermoplastic resin is 20 to 150. 4. The method for producing a hollow fiber sheet according to claim 2, wherein the temperature of the thin-film molten thermoplastic resin at the time of contact with the sheet-like hollow fiber fabric is equal to or higher than the melting point of the hollow fiber material. A method for producing a hollow fiber sheet-like material, characterized in that: 5. The method for producing a hollow fiber sheet according to any one of claims 2 to 4, wherein the thin-film molten thermoplastic resin is supplied to both surfaces of the sheet-shaped hollow fiber woven fabric. A method for producing a fiber sheet. 6. The method for producing a hollow fiber sheet according to any one of claims 2 to 5, wherein the thin film molten thermoplastic resin is supplied to the sheet hollow fiber fabric by the following formula I: A method for producing a hollow fiber sheet material, which satisfies a relationship represented by the following formula. W1 · C1 (T−T1) ≧ W2 · C2 (T2−T) (I) Here, the symbols in the above formula I represent the following. C1: Material specific heat of hollow fiber material T: Melting point of hollow fiber material W1: Unit weight of hollow fiber C2: Material specific heat of thin film molten thermoplastic resin W2: Unit weight of thin film molten thermoplastic resin T1: Thin film heat of fusion Temperature of hollow fiber when thermoplastic resin and hollow fiber contact T2: Temperature of thin-film molten thermoplastic resin when thin-film molten thermoplastic resin and hollow fiber come into contact 7. The hollow fiber sheet according to claim 1,
The thermoplastic resin joint is inserted so as to penetrate the potting portion in the cartridge housing, and a resin for melting and fixing made of a thermoplastic resin is sealed in the potting portion, and after being fixed, the hollow fiber sheet material is removed. A hollow fiber membrane module characterized in that a hollow fiber sheet is cut at a penetrating end through a potting portion so as to be perpendicular to the hollow fibers to be formed and to intersect with the thermoplastic resin joint, thereby opening the hollow fibers. Manufacturing method.