JP2014104383A - Hollow fiber membrane module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a hollow fiber membrane module in which both bundle end parts of hollow fiber membranes are inserted each into a bundle binding tube and fixed to each bundle binding tube through a potting part so that only the hollow inside of the hollow fiber membrane is opened to the outside and which enables not only hollow fiber membranes positioned in the peripheral surface on the side of the bundle of hollow fiber membranes or in the vicinity of the peripheral surface but hollow fiber membranes positioned inside the bundle of hollow fiber membranes to function effectively.SOLUTION: In a hollow fiber membrane module in which both bundle end parts of hollow fiber membranes are inserted each into a bundle binding tube and fixed to each bundle binding tube through a potting part so that only the hollow inside of the hollow fiber membrane is opened to the outside, hollow opening parts of the hollow fiber membranes in one end part of a hollow fiber membrane bundle are sealed with a sealing material, and, in the central part of the potting part in the module end part on the side where the hollow inside of hollow fiber membranes are sealed, there is provided a through hole penetrating the inside of the module and serving as an outlet for a fluid supplied externally to the module.

Description

  The present invention relates to a hollow fiber membrane module. More specifically, the present invention relates to a hollow fiber membrane module used for liquid deaeration and the like.

  Currently, hollow fiber membrane modules are used for degassing, filtering, separating, concentrating liquids, or for humidifying and dehumidifying gases. For example, as a method for removing gas in a liquid such as water, a membrane type deaeration method using a hollow fiber membrane module as shown in FIG. 4 of Patent Document 1, for example, is employed, which is a hollow fiber membrane. The liquid to be treated is allowed to flow to the outside of the hollow fiber membrane bundle of the module, the internal space side of the hollow fiber membrane is decompressed, and the gas dissolved in the liquid is removed therefrom.

  As such a hollow fiber membrane module, as shown in FIG. 2, the bundle ends of a plurality of hollow fiber membranes 4 are respectively inserted into left and right bundled tubes, and the hollow fiber membranes are inserted into the bundled tubes. What fixed the edge part via the potting parts 5 and 5 'is used, and the liquid etc. which are the object of filtration are supplied from the side peripheral surface with respect to the major axis direction of the hollow fiber membrane module 1. Can be mentioned. However, in the housing 7 in which these hollow fiber membrane modules 1 are housed via O-rings 8 and 8 ′, the liquid inlet 9 and the liquid outlet 10 are on the side with respect to the longitudinal direction of the hollow fiber membrane 4. It is provided on the peripheral surface side. As a result, the liquid supplied from the membrane module side peripheral surface is degassed mainly through the outer surface of the bundle of hollow fiber membranes when the hollow fiber membrane internal space side is depressurized from the degassing ports 11 and 11 ′. Therefore, the hollow fiber membrane 4 positioned at the center of the hollow fiber membrane bundle is not effectively used as compared with the hollow fiber membrane 4 positioned near the outer surface of the hollow fiber membrane bundle.

JP 2002-113334 A

  An object of the present invention is to insert a hollow fiber membrane bundle end into each bundled tube, and to place a potting portion on each bundled tube so that only the hollow interior of the hollow fiber membrane is opened to the outside. In the hollow fiber membrane module fixed through the hollow fiber membrane bundle, not only the hollow fiber membrane side peripheral surface or the vicinity thereof, but also the hollow fiber membrane located inside the hollow fiber membrane bundle can function effectively. An object of the present invention is to provide a hollow fiber membrane module that can be used.

  The object of the present invention is to insert the hollow fiber membrane bundle end into each bundled tube and pot the hollow fiber membrane end into each bundled tube so that only the hollow interior of the hollow fiber membrane is opened to the outside. In the hollow fiber membrane module fixed via the part, the hollow fiber membrane opening at one end of the hollow fiber membrane bundle is sealed with a sealing material, and the hollow end of the hollow fiber membrane is sealed This is achieved by a hollow fiber membrane module in which a through hole to the inside of the module is provided in the central portion of the potting portion.

  By sealing the hollow fiber membrane opening at one end of the hollow fiber membrane bundle and providing a through hole to the inside of the module at the center of the potting portion of the module end where the hollow interior of the hollow fiber membrane is sealed, When the fluid is circulated through the hollow fiber membrane module, the flow path is changed so that the fluid that has been passing through the side surface of the hollow fiber membrane bundle or the vicinity mainly passes through the center of the hollow fiber membrane bundle. It becomes possible to do. As a result, there is an excellent effect that not only the vicinity of the side peripheral surface of the hollow fiber membrane bundle but also the hollow fiber membrane located in the vicinity of the central portion can be effectively functioned.

BRIEF DESCRIPTION OF THE DRAWINGS (D) is a longitudinal centerline end view showing a state in which the housing is mounted on the housing. It is a long-axis direction centerline end view which shows one aspect | mode of the conventional hollow fiber membrane module.

  The hollow fiber membrane module according to the present invention has a hollow fiber membrane bundle end inserted into a bundled tube, and the hollow fiber membrane end is connected to each bundled tube so that only the hollow interior of the hollow fiber membrane is opened to the outside. In the hollow fiber membrane module fixed to each through a potting portion, the hollow fiber membrane opening at one end of the hollow fiber membrane bundle is sealed with a sealing material, and the hollow interior of the hollow fiber membrane is sealed. A through hole into the module is provided at the center of the potting portion at the end of the module.

  Hereinafter, specific embodiments for the hollow fiber membrane module according to the present invention will be described in detail with reference to the drawings. It should be noted that the specific modes described below merely exemplify one mode of the present invention, and the present invention is not limited to the following modes.

  FIG. 1 (a) is a partial end face front view showing one embodiment of a hollow fiber membrane module 1 according to the present invention, the upper half of the figure is a front view of the hollow fiber membrane module, and the lower half of the figure is a hollow fiber membrane. It is a centerline end view of the long axis direction of the module. In the left bundle tube 2 and the right bundle tube 3, hollow fiber membrane bundle end portions composed of a plurality of hollow fiber membranes 4 filled therein are accommodated, respectively, and at both ends of the hollow fiber membrane module, Potting portions 5, 5 ′ are provided for sealing and fixing between the outer wall surfaces of the end portions of the hollow fiber membrane 4 and between the inner wall surfaces of the end portions of the hollow fiber membrane 4 and the left bundled tube 2 or the right bundled tube 3. . In general, the potting part is preferably first sealed with an adhesive having high heat resistance such as an epoxy adhesive and provided with a first potting part (external side), and further, a secondary adhesive with a soft adhesive with low heat generation. It is formed by multistage potting such as sealing and providing a second potting portion (inside). By using multi-stage potting in this way, it is possible to suppress heat generated when potting is cured, and in particular, it is possible to prevent breakage of the hollow fiber membrane by suppressing heat generation between the interface with the hollow fiber membrane. .

  In the present invention, the hollow fiber membrane 4 located in one potting part 5 has its hollow interior sealed with the same material as the potting material, but the hollow fiber membrane 4 located in the other potting part 5 ' The hollow interior is open to the outside. Potting part by sealing and fixing between the outer wall surface of each hollow fiber membrane end and the inner wall surface of the hollow fiber membrane end and the left bundled tube or right bundled tube so that the hollow interior is opened to the outside For example, after the hollow portion at the end of the hollow fiber membrane is sealed before potting, the potting portion is formed by potting, and the hollow fiber membrane is formed so that the hollow portion of the hollow fiber membrane is opened. The method of cutting etc. is mentioned. Moreover, as a method of sealing the hollow interior with the same material as the potting material, the hollow fiber membrane end is sealed with the same material as the potting material, and then accommodated in the bundled tube to form the potting portion. The hollow fiber membrane bundle in which the hollow fiber membrane end portion is not sealed is accommodated in a bundling tube, and the potting portion is formed, and at the same time, the hollow fiber membrane end portion is sealed together. At this time, the hollow fiber membrane bundle is accommodated in the bundled tube, in addition to a mode in which the hollow fiber membrane end is aligned with the bundled tube end, and the hollow fiber membrane end is located on the inner side of the bundled tube than the bundled tube end. Any of the modes of disposing and sealing the end portion of the hollow fiber membrane can be used.

  A potting portion through-hole 6 into the module is provided at the center of the potting portion 5 at the end of the module where the hollow interior of the hollow fiber membrane is sealed. Such a through hole is formed, for example, by inserting an axial projection having a conical tip at the tip into the hollow fiber membrane bundle before potting and then removing the projection.

  The potting portion through hole 6 functions as an outlet for the liquid supplied from the outside of the hollow fiber membrane module 1. The liquid to be degassed is supplied from the peripheral surface of the hollow fiber membrane bundle and reaches the central part of the hollow fiber membrane bundle, and then the potting part through hole provided in the center of the sealed module end potting part 5 6 will flow out. By adopting such a configuration, it is possible to effectively use all the hollow fiber membranes housed regardless of the arrangement position of the hollow fiber membranes, and to improve the performance of the hollow fiber membrane module. There is an effect.

  1 (b) is a left side view of the hollow fiber membrane module 1 shown in FIG. 1 (a), and FIG. 1 (c) is a right side view of the hollow fiber membrane module 1 shown in FIG. 1 (a). is there. In FIG. 1 (c), the opening portion of the hollow fiber membrane 4 is a hollow opening portion 13 at the end of the hollow fiber membrane, whereas in FIG. The hollow fiber membrane end hollow block 12 is sealed, and the potting portion through-hole 6 into the module is formed at the center of the potting portion 5 at the module end where the hollow interior of the hollow fiber membrane is sealed. Is provided. Since the hollow portion of the hollow fiber membrane is sealed with a sealant, there is no outflow or inflow of gas or liquid from the portion, and the potting portion through hole into the module provided in the central portion of the potting portion 5 6 functions as an outlet for the liquid supplied from the outside of the hollow fiber membrane bundle.

  FIG. 1D shows that the hollow fiber membrane module 1 shown in FIG. 1A is stored in the housing 7 via O-rings 8 and 8 ′ attached to the left bundled tube 2 or the right bundled tube 3. FIG. As shown in FIG. 2, the conventional housing 7 was provided with the liquid outlet 10 in addition to the liquid inlet 9 on the side peripheral surface side with respect to the long axis direction of the hollow fiber membrane 4. Most of the liquid only passes through the side peripheral surface of the hollow fiber membrane bundle or the vicinity thereof, but in the present invention, the liquid outlet 10 is provided on one end side of the hollow fiber membrane module 1. The liquid to be deaerated reaches from the outer surface of the hollow fiber membrane bundle to the center of the hollow fiber membrane bundle, and effectively uses all the contained hollow fiber membranes regardless of the arrangement position of the hollow fiber membrane 4 Since the deaeration is performed, it is possible to achieve further improvement in performance in the case of the hollow fiber membrane module using the same number of hollow fiber membranes.

DESCRIPTION OF SYMBOLS 1 Hollow fiber membrane module 2 Left bundling tube 3 Right bundling tube 4 Hollow fiber membrane 5, 5 'Potting part 6 Potting part through-hole 7 Housing 8, 8' O-ring 9 Liquid inflow port 10 Liquid outflow port 11, 11 ' Deaeration port 12 Hollow fiber membrane end hollow blockage 13 Hollow fiber membrane end hollow opening

  The present invention relates to a hollow fiber membrane module. More specifically, the present invention relates to a hollow fiber membrane module used for liquid deaeration and the like.

  Currently, hollow fiber membrane modules are used for degassing, filtering, separating, concentrating liquids, or for humidifying and dehumidifying gases. For example, as a method for removing gas in a liquid such as water, a membrane type deaeration method using a hollow fiber membrane module as shown in FIG. 4 of Patent Document 1, for example, is employed, which is a hollow fiber membrane. The liquid to be treated is allowed to flow to the outside of the hollow fiber membrane bundle of the module, the internal space side of the hollow fiber membrane is decompressed, and the gas dissolved in the liquid is removed therefrom.

As such a hollow fiber membrane module, for example , as shown in FIG. 2, both bundle end portions of a plurality of hollow fiber membranes 4 are respectively inserted into left and right bundled tubes, and hollow fibers are inserted into each bundled tube. What fixed the membrane edge part via potting part 5, 5 'is used, and the liquid etc. which are the object of filtration are supplied from the side peripheral surface with respect to the major axis direction of the hollow fiber membrane module 1 Is mentioned. However, in the housing 7 in which these hollow fiber membrane modules 1 are housed via O-rings 8 and 8 ′, the liquid inlet 9 and the liquid outlet 10 are on the side with respect to the longitudinal direction of the hollow fiber membrane 4. It is provided on the peripheral surface side. As a result, the liquid supplied from the membrane module side peripheral surface is degassed mainly through the outer surface of the bundle of hollow fiber membranes when the hollow fiber membrane internal space side is depressurized from the degassing ports 11 and 11 ′. Therefore, the hollow fiber membrane 4 positioned at the center of the hollow fiber membrane bundle is not effectively used as compared with the hollow fiber membrane 4 positioned near the outer surface of the hollow fiber membrane bundle.

JP 2002-113334 A

An object of the present invention, fitted to the hollow fiber membrane both bundle end portions, each bundle deposition tube, potting the hollow fiber membrane both ends so that only the hollow interior of the hollow fiber membrane is open to the outside in each bundle deposition tube In the hollow fiber membrane module fixed through the section, not only the hollow fiber membrane located on the hollow fiber membrane bundle side peripheral surface or the vicinity thereof, but also the hollow fiber membrane located inside the hollow fiber membrane bundle is effectively functioned. An object of the present invention is to provide a hollow fiber membrane module that makes it possible.

The purpose of such invention, the hollow fiber membrane both bundle end portion fitted to the flux deposition tube respectively, in each bundle deposition tube hollow fiber membrane both ends so that only the hollow interior of the hollow fiber membrane is open to the outside In each hollow fiber membrane module fixed via a potting part, the hollow fiber membrane hollow opening at one end of the hollow fiber membrane bundle was sealed with a sealing material, and the hollow interior of the hollow fiber membrane was sealed This is achieved by a hollow fiber membrane module provided with a through hole to the inside of the module , which serves as an outlet for the fluid supplied from the outside of the module, at the central portion of the potting portion at the end of the module.

The hollow fiber membrane hollow opening at one end of the hollow fiber membrane bundle is sealed, and the hollow fiber membrane , generally the inside of the module at the center of the potting portion of the module end where the hollow inside of the porous hollow fiber membrane is sealed When a fluid is circulated through the hollow fiber membrane module by providing a through-hole, a fluid , for example, a liquid, which has conventionally passed mainly at or near the side peripheral surface of the hollow fiber membrane bundle, The flow path can be changed so as to pass through the central portion. As a result, there is an excellent effect that not only the vicinity of the side peripheral surface of the hollow fiber membrane bundle but also the hollow fiber membrane located in the vicinity of the central portion can be effectively functioned.

It is a diagram showing an embodiment of a hollow fiber membrane module according to the present invention, (a) is a front view showing the lower half as a long axis direction center line end view, (b) is a left side view, (c) is a right side (D) is a longitudinal centerline end view showing a state in which the housing is mounted on the housing. It is a long-axis direction centerline end view which shows one aspect | mode of the conventional hollow fiber membrane module.

The hollow fiber membrane module according to the present invention is hollow so that both ends of the bundles of hollow fiber membranes are fitted into bundled tubes, and only the hollow interior of the hollow fiber membrane , generally a porous hollow fiber membrane , is opened to the outside. fiber membrane in the hollow fiber membrane module was allowed secured via a respective potting portions each bundle deposition tube both ends, together with the hollow fiber membrane hollow opening of the one end portion of the hollow fiber membrane bundle is sealed by a sealing material A through hole to the inside of the module serving as an outlet for the fluid supplied from the outside of the module is provided in the central portion of the potting portion at the end of the module on the side where the hollow inside of the hollow fiber membrane is sealed.

  Hereinafter, specific embodiments for the hollow fiber membrane module according to the present invention will be described in detail with reference to the drawings. It should be noted that the specific modes described below merely exemplify one mode of the present invention, and the present invention is not limited to the following modes.

FIG. 1 (a) is a partial end face front view showing one embodiment of a hollow fiber membrane module 1 according to the present invention, the upper half of the figure is a front view of the hollow fiber membrane module, and the lower half of the figure is a hollow fiber membrane. It is a centerline end view of the long axis direction of the module. The left bundle tube 2 and the right bundle tube 3 accommodate a plurality of hollow fiber membranes 4 filled therein , generally hollow fiber membrane bundle end portions made of porous hollow fiber membranes, respectively. At both ends of the module, potting portions 5 for sealing and fixing between the outer wall surfaces of the end portions of the hollow fiber membranes 4 and between the inner wall surfaces of the end portions of the hollow fiber membranes 4 and the left bundled tube 2 or the right bundled tube 3. 5 '. In general, the potting part is preferably first sealed with an adhesive having high heat resistance such as an epoxy adhesive and provided with a first potting part (external side), and further, a secondary adhesive with a soft adhesive with low heat generation. It is formed by multistage potting such as sealing and providing a second potting portion (inside). By using multi-stage potting in this way, it is possible to suppress heat generated when potting is cured, and in particular, it is possible to prevent breakage of the hollow fiber membrane by suppressing heat generation between the interface with the hollow fiber membrane. .

In the present invention, the hollow fiber membrane 4 located in one potting part 5 has its hollow interior sealed with the same material as the potting material, but the hollow fiber membrane 4 located in the other potting part 5 ' The hollow interior is open to the outside. A method for forming a potting part by sealing and fixing between the outer wall surfaces of each hollow fiber membrane end and between the hollow fiber membrane end and the inner wall surface of the right bundled tube 3 so that the hollow interior is opened to the outside For example, after sealing the hollow portion of the end portion of the hollow fiber membrane before potting, the potting portion is formed by potting, and the hollow fiber membrane is cut so that the hollow portion of the hollow fiber membrane is opened. Is mentioned. Moreover, as a method of sealing the hollow interior with the same material as the potting material, the hollow fiber membrane end is sealed with the same material as the potting material, and then accommodated in the bundled tube to form the potting portion. The hollow fiber membrane bundle in which the hollow fiber membrane end portion is not sealed is accommodated in a bundling tube, and the potting portion is formed, and at the same time, the hollow fiber membrane end portion is sealed together. At this time, the hollow fiber membrane bundle is accommodated in the bundled tube, in addition to a mode in which the hollow fiber membrane end is aligned with the bundled tube end, and the hollow fiber membrane end is located on the inner side of the bundled tube than the bundled tube end. Any of the modes of disposing and sealing the end portion of the hollow fiber membrane can be used.

A potting portion through-hole 6 to the inside of the module , which serves as an outlet for fluid such as liquid supplied from the outside of the module , is provided at the central portion of the potting portion 5 at the end of the module where the hollow interior of the hollow fiber membrane is sealed. Is provided. Such a through hole is formed, for example, by inserting an axial projection having a conical tip at the tip into the hollow fiber membrane bundle before potting and then removing the projection.

The potting portion through-hole 6 functions as an outlet for the fluid supplied from the outside of the hollow fiber membrane module 1. Fluid to be degassed subject etc., after reaching to the hollow fiber membrane bundle central portion is supplied from the hollow fiber membrane bundle side peripheral surface, potting portion through which is provided at the center of the sealed module end potting portion 5 It will flow out of the hole 6. By adopting such a configuration, it is possible to effectively use all the hollow fiber membranes housed regardless of the arrangement position of the hollow fiber membranes, and to improve the performance of the hollow fiber membrane module. There is an effect.

1 (b) is a left side view of the hollow fiber membrane module 1 shown in FIG. 1 (a), and FIG. 1 (c) is a right side view of the hollow fiber membrane module 1 shown in FIG. 1 (a). is there. In FIG. 1 (c), the opening portion of the hollow fiber membrane 4 is a hollow opening portion 13 at the end of the hollow fiber membrane, whereas in FIG. The hollow fiber membrane end portion is a hollow blocking portion 12 that is sealed, and the potting portion penetrates into the inside of the module at the center portion of the potting portion 5 on the module end portion on the side where the hollow interior of the hollow fiber membrane is sealed. A hole 6 is provided. Since the hollow portion of the hollow fiber membrane is sealed with a sealant, there is no outflow or inflow of gas or liquid from the portion, and the potting portion through hole into the module provided in the central portion of the potting portion 5 6 functions as an outlet for the fluid supplied from the outside of the hollow fiber membrane bundle.

  FIG. 1D shows that the hollow fiber membrane module 1 shown in FIG. 1A is stored in the housing 7 via O-rings 8 and 8 ′ attached to the left bundled tube 2 or the right bundled tube 3. FIG. As shown in FIG. 2, the conventional housing 7 was provided with the liquid outlet 10 in addition to the liquid inlet 9 on the side peripheral surface side with respect to the long axis direction of the hollow fiber membrane 4. Most of the liquid only passes through the side peripheral surface of the hollow fiber membrane bundle or the vicinity thereof, but in the present invention, the liquid outlet 10 is provided on one end side of the hollow fiber membrane module 1. The liquid to be deaerated reaches from the outer surface of the hollow fiber membrane bundle to the center of the hollow fiber membrane bundle, and effectively uses all the contained hollow fiber membranes regardless of the arrangement position of the hollow fiber membrane 4 Since the deaeration is performed, it is possible to achieve further improvement in performance in the case of the hollow fiber membrane module using the same number of hollow fiber membranes.

DESCRIPTION OF SYMBOLS 1 Hollow fiber membrane module 2 Left bundling tube 3 Right bundling tube 4 Hollow fiber membrane 5, 5 'Potting part 6 Potting part through-hole 7 Housing 8, 8' O-ring 9 Liquid inflow port 10 Liquid outflow port 11, 11 ' Deaeration port 12 Hollow fiber membrane end hollow blockage 13 Hollow fiber membrane end hollow opening

Claims (3)

The hollow fiber membrane bundle end was fitted into the bundled tube, and the hollow fiber membrane end was fixed to each bundled tube via the potting part so that only the hollow interior of the hollow fiber membrane was opened to the outside. In hollow fiber membrane module,
The hollow fiber membrane opening at one end of the hollow fiber membrane bundle is sealed with a sealing material, and a through hole to the inside of the module is formed at the center of the potting portion at the end of the module where the hollow interior of the hollow fiber membrane is sealed. A hollow fiber membrane module provided.   The hollow fiber membrane module according to claim 1, wherein the hollow interior of the hollow fiber membrane is sealed with the same material as the potting material.   The hollow fiber membrane module according to claim 1 or 2, which is used for liquid deaeration.

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