JPH09103606A - Gas separation membrane module - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the iron component from being bonded to or grown to the end part of a module main body by revolving a granular flowing material in a module cap by the fluid flowing into the cap to bring the same into contact with the end surface module main body. SOLUTION: When raw water flows in hollow gas separation membrane 1 from a fluid inflow port 6 through a module cap 5, the granular moving materials 8 housed in the space part 10 formed between the module cap 5 and module main body 4 are revolved in a suspend state by the inflow raw water. Even on the outflow side of treated water, when treated water flows out to the outside of a gas separation module through a fluid outflow port 7, the granular moving materials 8 are revolved in a suspended state by treated water. By the revolution of the granular moving materials 8 in a suspended state, the granular movable materials come into contact with the end part of the module main body 4. Therefore, the adhesion of an iron component to the end surface of the module main body 4 is prevented and the iron component already bonded to the end surface of the module main body 4 is removed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the structure of a gas separation membrane module used in a vacuum degassing apparatus for separating and removing dissolved gas in a liquid by utilizing a hollow gas separation membrane.

[0002]

2. Description of the Related Art In recent years, a deaerator has been used as a measure for preventing red water in buildings such as buildings and condominiums. Further, a deaerator is incorporated in a water supply line for cooling and heating equipment such as a boiler, a water heater and a cooler for the purpose of preventing internal corrosion of these equipment.

As the degassing device, a device using a hollow gas separation membrane is widely used because of its compactness and easy handling. In this type of deaerator, a gas separation membrane module containing a gas separation membrane such as a hollow gas separation membrane is connected to a water supply line to equipment used, and raw water is passed through the gas separation membrane module. The inside of the gas separation membrane module is evacuated during the water passing process to separate and remove the dissolved gas in the raw water. The gas separation membrane module is formed by fitting module caps to both ends of a module body composed of an assembly of hollow gas separation membranes.

[0004]

In the above-mentioned conventional structure, the raw water is passed through the gas separation membrane module to separate and remove it from the dissolved gas in the raw water, and the inside of the gas separation membrane module is passed through this water passing process. It is performed by drawing a vacuum. When the separation and removal of the dissolved gas in the raw water is continuously performed, iron, manganese, mud, algae, etc. in the raw water are discharged to the end (fluid inlet side) of the module body composed of the aggregate of hollow gas separation membranes. The iron and the like adhere to the ends of the module body and grow over time. Generally, in the deaerator, a filter is provided in front of the deaerator in order to prevent adhesion and growth of the iron and the like. It permeates the filter and adheres to the end face of the module body, which grows and blocks the inlet of the hollow separation membrane. When such blockage (clogging) occurs, the flow rate of treated water in the deaerator decreases, and the efficiency of the deaerator as a whole also decreases. Also, the life of the module itself is shortened.

Therefore, the present invention has as a problem to be solved to prevent the adhesion and growth of iron or the like to the end of the module body.

[0006]

The present invention has been made to solve the above problems, and the invention according to claim 1 is a module main body composed of an assembly of hollow gas separation membranes, A gas separation membrane module comprising module caps fitted to both ends of the module body, wherein the module caps are provided with fluid inlets and fluid outlets, respectively. The invention according to claim 2 is characterized in that a space portion is formed between each of the space portions and a large number of granular floating bodies are accommodated in the space portions, respectively.
The granular floating body is housed in at least a fluid inflow side space portion of the both space portions, and the invention according to claim 3 provides the fluid inflow port and the fluid outflow port with the The present invention according to claim 4 is characterized in that the fluid inflow preventing means for the granular floating bodies is provided, and the fluid inflow inlet and the fluid outflow outlet are provided deviated from the central portions of the both module caps, respectively. Is characterized by.

[0007]

BEST MODE FOR CARRYING OUT THE INVENTION The gas separation membrane module according to the present invention comprises a module body composed of an assembly of hollow gas separation membranes, a module cap, a granular floating body and an outflow prevention means. Specifically, the module caps are fitted to both ends of the module body,
A granular floating body is housed between them, and the outflow prevention means is provided at the fluid inlet and the fluid outlet of the module cap.

When the dissolved gas removal treatment of raw water is performed using the gas separation membrane module, raw water is introduced from the one module cap, passes through the module main body, and flows out from the other module cap.
When passing through the module body, the inside of the module body is evacuated to separate and remove the dissolved gas in the raw water.

Raw water sometimes contains iron, manganese, mud, algae and the like. In the deaerator, a filter is provided in front of the deaerator in order to remove the iron and the like. However, the iron or the like, which is ionic or smaller than the filtration accuracy of the filter, permeates the filter and adheres to and grows on the end surface of the module main body, blocking the inlet of the hollow separation membrane.

In the gas separation membrane module according to the present invention, since many granular floating bodies are interposed between the module body and the module cap, raw water flows into the module body through the module cap. At this time, the granular floating body turns, and the granular floating body comes into contact with the end surface of the module body. As described above, since the granular floating body turns while contacting the end surface of the module body, the iron content and the like are prevented from adhering to the end surface of the module body, and the iron content and the like already attached to the end surface of the module body are removed. Further, since the fluid inflow port and the fluid outflow port provided in the module cap are provided with the outflow prevention means having smaller eyes than the granular floating body, the outflow to the outside of the module cap is prevented. .

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. First, FIG. 1 showing a first embodiment of the present invention will be described. FIG. 1 is a sectional explanatory view schematically showing a structure of a gas separation membrane module according to the present invention. In FIG. 1, the gas separation membrane module according to the present invention comprises a hollow gas separation membrane 1, a module case 2, and a module cap 5. Specifically, the assembly of the hollow gas separation membranes 1 is housed in the module case 2 to form a module body 4, and the module caps 5 are fitted to both ends of the module body 4, respectively. An appropriate space portion 10 is formed between the module 4 and each of the module caps 5. A large number of granular floating bodies 8 for cleaning the end surface of the module body 4 are housed in both the space portions 10. It is preferable that the granular floating body 8 has a relatively low specific gravity such as plastic beads,
As the shape, a spherical shape, a rice grain shape, a cylindrical shape, or the like is applied.

In the above structure, when the raw water is introduced from the fluid inlet 6 provided in one of the module caps 5 and passes through the hollow gas separation membrane 1 of the module body 4, the dissolved gas is separated and the other is Module cap 5
Is discharged as treated water (degassed water) from the fluid outlet 7 provided in the. For the separation of the dissolved gas, a device such as a water-sealed vacuum pump (not shown) for vacuuming is connected to the extraction hole 3 provided in the module case 2 so that raw water is the hollow gas separation membrane. It is performed by drawing a vacuum with the water-sealed vacuum pump or the like while passing through 1.

When raw water flows from the fluid inlet 6 into the hollow gas separation membrane 1 through the module cap 5, the module cap 5 and the module body 4
The granular floating body 8 housed in the space portion 10 formed between the and is swirled by the inflowing raw water. As the granular floating body 8 idles and turns in the space portion 10,
The granular floating body 8 contacts the end surface of the module body 4. Therefore, by contacting the end surface of the module main body 4 with the granular floating body 8, it is possible to prevent the adhesion of iron or the like to the end surface of the module main body 4, and to prevent the iron content already attached to the end surface of the module main body 4. Etc. are removed.

Also on the treated water outflow side, when the treated water flows out of the gas separation membrane module through the fluid outlet 7, it is formed between the module body 4 and the module cap 5 by the treated water. The granular floating body 8 housed in the formed space portion 10 swings freely. This granular floating body 8
The floating swirl prevents the adhesion of iron or the like to the end surface of the module body 4 on the treated water outflow side as well as the raw water inflow side, and removes the iron or the like already adhered to the end surface of the module body 4. Remove.

FIG. 2 showing a second embodiment of the present invention.
Will be described. In this embodiment, the sizes of the fluid inlet 6 and the fluid outlet 7 provided in the module cap 5 are compared with the sizes of the granular floating bodies 8,
When the granular floating body 8 is small enough to flow out from the fluid inlet 6 and the fluid outlet 7, outflow preventing means 9 such as a wire mesh is provided at the fluid inlet 6 and the fluid outlet 7, respectively. It has a different structure.

By providing the outflow prevention means 9,
The particle size of the granular floating body 8 and the fluid are not limited to the balance between the granular floating body 8 and the fluid inflow port 6 and the fluid outflow port 7, that is, the outflow of the granular floating body 8 is not taken into consideration. The diameters of the inflow port 6 and the fluid outflow port 7 can be set to values that can achieve better effects.

In the second embodiment, the construction in which the wire net is used as the outflow prevention means 9 has been described. However, the present invention is not limited to this. It is suitable.

Further, FIG. 3 showing a third embodiment of the present invention.
Will be described. In both of the embodiments, the fluid inlet 6 and the fluid outlet 7 provided in the module caps 5 are shown and described as being connected to the central portions in the outer peripheral portions of the module caps 5. In the example, the fluid inlet 6 and the fluid outlet 7 are provided at positions offset from the center. That is, FIG. 3 shows a structure in which the circular module cap 5 is connected from the tangential direction. According to this structure, the space portion 10 defined by the module cap 5 is formed.
The floating swinging force of the granular floating body 8 in the inside is improved, and removal of iron and the like from the end surface of the module body 4 and prevention of adhesion can be efficiently achieved. Even if both module caps 5 are rectangular, the swinging force of the granular floating body 8 is improved by providing the both inflow / outflow ports 6 and 7 at positions deviated from the center.

In each of the above embodiments, both the space portions 1
The amount of the granular floating bodies 8 housed in each of the 0 is determined by the volume of both the space portions 10 (the diameter of the module main body 4, the diameter and depth of the module cap 5, etc.) and the size of the granular floating bodies 8. Determined by Sato. Specifically, it is determined as an amount required for the granular floating body 8 to efficiently oscillate in the space 10 and uniformly contact the end surface of the module body 4.

[0020]

According to the present invention, the granular floating body is swirled by the fluid flowing into the module cap, and the granular floating body comes into contact with the end surface of the module body, so that the adhesion of iron or the like to the end surface of the module body is prevented. In addition to preventing it, it becomes possible to remove iron and the like already attached to the end surface of the module body. In addition, since the fluid inflow port and the fluid outflow port provided in the module cap are provided with the outflow prevention means, it is possible to prevent the granular floating body housed in the space from flowing out of the module cap. it can. Further, since the fluid inlets and the fluid outlets of both module caps are provided at the eccentric positions, the floating swinging force of the granular floating body in the module cap, that is, in the space portion is increased, and the iron content of the end surface of the module main body is increased. Removal and prevention of adhesion can be efficiently achieved.

[Brief description of the drawings]

FIG. 1 is a schematic cross-sectional explanatory view of a gas separation membrane module showing a first embodiment of the present invention.

FIG. 2 is a schematic cross-sectional explanatory view of a gas separation membrane module showing a second embodiment of the present invention.

FIG. 3 is a schematic cross-sectional explanatory view of a module cap used in a third embodiment of the present invention.

[Explanation of symbols]

 1 Hollow Gas Separation Membrane 4 Module Main Body 5 Module Cap 6 Fluid Inlet 7 Fluid Outlet 8 Granular Floating Body 9 Outflow Prevention Means 10 Space

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Takuhiro Yamao 7 Horie-cho, Matsuyama-shi, Ehime Miura Industry Co., Ltd.

Claims (4)

[Claims] 1. A module main body 4 composed of an assembly of hollow gas separation membranes 1, and module caps 5 and 5 fitted to both ends of the module main body 4, respectively. In a gas separation membrane module in which a fluid inlet 6 and a fluid outlet 7 are provided respectively, space portions 10 are formed between the module body 4 and both module caps 5, and the space portions 10 are formed. A gas separation membrane module, characterized in that a large number of granular floating bodies 8 are housed therein. 2. The gas separation membrane module according to claim 1, wherein the granular floating body 8 is housed in at least the fluid inflow side space 10 of the both space 10. 3. Outflow prevention means 9 for preventing outflow of the granular floating bodies 8 to the fluid inlet 6 and the fluid outlet 7.
The gas separation membrane module according to claim 1, wherein the gas separation membrane module is provided. 4. The fluid inflow port 6 and the fluid outflow port 7 are provided so as to be offset from the central portions of the both module caps 5, respectively.
The gas separation membrane module according to any one of 1.