KR102203817B1 - Ceramic hollow fiber membrane module for membrane contactor process - Google Patents

Abstract

The present invention relates to a ceramic hollow fiber contact membrane module, and according to the present invention, in the ceramic hollow fiber contact membrane module, the ceramic hollow fiber membrane can be prevented from being damaged by arranging the ceramic hollow fiber membranes on a hydrophilic metal mesh and then rolling and potting them. And, it can be evenly arranged in the inner space of the housing, and by forming a communication space between the shell side dispersion injection unit and the lumen side dispersion injection unit, the fluid pressure is distributed in the ceramic hollow fiber contact membrane module, and the material without the separation membrane wetting phenomenon It has the effect of enabling stable operation while maintaining transmission efficiency.

Description

Ceramic hollow fiber membrane module for membrane contactor process

The present invention relates to a ceramic hollow fiber contact membrane module, and more particularly, to a ceramic hollow fiber contact membrane module capable of stable operation while maintaining material transfer efficiency without the separation membrane wetting phenomenon.

The contact separation membrane technology is a process of selectively separating one or more components by contacting an absorbent and a gas through a separation membrane, and is a hybrid technology that combines the advantages of liquid absorption (high selectivity) and membrane separation (modularity and miniaturization). The concept of the contact separation membrane was introduced by Schaffer in 1960 for water treatment such as food and medicine, and since it was used for CO ₂ separation by Qi and Cussler in the 1980s, active research has been conducted in the field of gas separation. Currently, catalytic separation membranes are developed and applied to various applications such as liquid extraction, gas absorption and stripping, high-density gas extraction, isomer separation, fermentation and enzyme modification, protein extraction, pharmaceuticals, wastewater treatment, metal ion recovery, semiconductor processing, and osmotic distillation. Has become. In order to remove CO ₂ and O ₂ from the beer production line and extend the life of the boiler, a system for removing CO ₂ from water and a contact separation membrane process commercialized in the semiconductor industry to manufacture ultrapure water is in operation. Recently, the development of a contact separation membrane technology for reducing acid gases such as CO ₂ , H ₂ S, and SO ₂ generated during combustion of natural gas, industrial processes, and fossil fuels has been attracting attention. In particular, CO ₂ has been pointed out as a major cause of global warming, and many researches on CO ₂ capture technology are being conducted around the world. Therefore, most recent research on catalytic membranes has focused on the development of technology for capturing CO ₂ .

As a technology for reducing acid gases including CO ₂ , absorption processes such as packed towers, spray towers, and bubble towers are commercially available. The absorption process can achieve high acid gas removal efficiency even at atmospheric pressure and low gas concentration, and has been developed since it enables relatively stable operation. Although the acid gas trapping process based on such a liquid absorbent is a relatively efficient technology, it has some significant limitations. Specifically, the energy consumption required for absorbent regeneration is excessive, and due to the large size of the device, a large site is required. In addition, problems such as equipment corrosion, solvent loss, flooding, bubbles, drift, and entrainment may occur. On the other hand, the contact separation membrane process is regarded as a promising alternative that can overcome the shortcomings of the existing absorption process.

In the catalytic separation membrane, the membrane separates the gaseous and liquid phases instead of providing selectivity for separation, and serves to increase the effective contact area for mass transfer. It has a great advantage of providing high selectivity by the absorbent and reducing the size of the device through a high contact area per unit volume. In addition, since the gaseous phase and the liquid phase can be independently controlled and the gas flow rate can be increased without operational problems such as overflow and bubbles, it is possible to increase the processing capacity of the device in the same volume. In addition, the contact area can be easily controlled by controlling the number of unit modules, and system prediction is relatively easy, which is advantageous for process scale up. Membrane contactors are known to provide an effective contact area of about 30 times compared to the conventional absorption process, and it is reported that the size of the absorption unit process can be reduced up to 10 times.

Separation membrane modules include flat, spiral wound, tubular, and hollow fiber types, but the hollow fiber membrane has been attracting the most attention recently because it can maximize the membrane area per unit volume compared to other formulations and allows a compact module configuration.

As shown in FIG. 1, the conventional hollow fiber membrane module includes a housing 100 accommodating a hollow fiber membrane 10, a shell side fluid injection unit 110a, 110b, a lumen side fluid injection unit ( 120a, 120b), and a potting part 400.

However, in the conventional contact separation membrane in the hollow fiber membrane module, membrane resistance existed. In particular, when a long-term operation using the basic unit module, as shown in Fig. 2(a), the breakthrough occurs because pressure is applied from the injection part of the shell side. As the pressure rises above the breakthrough pressure, as shown in FIG. 2(b), the separation membrane is wetted by the absorbent. When the membrane is wetted by the absorbent, the mass transfer resistance increases rapidly. In addition, in a conventional hollow fiber membrane module, the hollow fiber bundles are ported in parallel in a row, and in this case, the spacing between the separation membranes is unevenly distributed. Accordingly, severe fluid drift and bypass phenomena may occur at the shell side of the module, resulting in a decrease in mass transfer characteristics. While this does not appear very well on the laboratory scale, it can cause serious problems when designing large processes. In addition, since the ceramic hollow fiber membrane is fragile, it is damaged during potting, making it difficult to manufacture. In addition, the pores of the separator and the sealing material used for modularization may be damaged by the absorbent, and replacement costs according to the life of the module are additionally incurred. In addition, an increase in pressure drop caused by the fluid flowing through the small inner diameter of the hollow fiber membrane increases the operating cost of the process. These shortcomings act as a major obstacle to the commercialization of the contact separator, and have caused many restrictions on application to industrial sites.

Therefore, according to the fluid flow in the contact separation membrane, the overall performance may be influenced by the membrane resistance rather than the vapor phase and the liquid phase. This indicates that when designing a contact separation membrane process, it is important to consider not only the structure and characteristics of the separation membrane and the absorbent, but also the module structure controlling the fluid flow. Accordingly, the development of a module design in which the regular arrangement of the hollow fiber membrane, the filling rate, and the flow direction of the fluid are considered as important factors is emerging as a major issue.

1. Korean Patent Application No. 10-2014-0161849

The present invention was conceived to improve the above problems, and an object of the present invention is to prevent breakage of the ceramic hollow fiber membrane, to be evenly disposed in the interior space of the housing, and the first fluid and the second fluid It is to provide a ceramic hollow fiber contact membrane module that is uniformly injected through a shell side dispersion injection unit and a lumen side dispersion injection unit, respectively, to maintain high material transfer efficiency without the separation membrane wetting phenomenon.

In order to achieve the above object, the present invention is a hollow fiber membrane bundle consisting of a plurality of ceramic hollow fiber membranes, a hydrophilic metal mesh surrounding each hollow fiber membrane in the hollow fiber membrane bundle, a ceramic hollow fiber membrane bundle surrounded by the hydrophilic metal mesh Is accommodated, and a cylindrical housing in which a plurality of through holes through which the first fluid can move is formed at both ends, and the entrance is coupled to one end of the housing and through which the second fluid enters and exits the lumen side of the hollow fiber membrane. A lumen side dispersion injection unit in which a communication space is formed between the lumen side entrance and the hollow fiber membrane, and a communication space is formed to surround the outer circumferential surface at one end of the cylindrical housing and communicate with the through hole of the housing, On one side, a ceramic hollow fiber contact membrane module including a shell side dispersion injection unit having an entrance through which the first fluid enters and exits the shell side is provided.

Also preferably, the ceramic hollow fiber membrane bundle surrounded by the hydrophilic metal mesh may be formed by aligning the ceramic hollow fiber membrane in a line with the hydrophilic metal mesh and then rolling.

Also preferably, the hollow fiber membrane bundle may be formed so that the filling rate of the ceramic hollow fiber membrane in the housing is 10 to 60%.

Also preferably, the hydrophilic metal mesh may be a hydrophilic stainless mesh.

Also preferably, in the ceramic hollow fiber contact membrane module, the first fluid and the second fluid may contact each other in a cross-flow manner.

Also preferably, the first fluid may be a liquid containing an absorbent, and the second fluid may be a gas containing an adsorption target.

Also preferably, the first fluid may be an amine-based solution that absorbs CO ₂ , and the second fluid may be a gas containing CO ₂ and N ₂ .

In addition, preferably, the ceramic hollow fiber contact membrane module is injected through the through hole in a state where the pressure is evenly distributed while the fluid is spread while surrounding the housing through the communication space in the shell side dispersion injection unit. Can come into contact with the desert.

In addition, preferably, the ceramic hollow fiber contact membrane module may further include a connection part for connection of unit modules.

Also preferably, the ceramic hollow fiber contact membrane module may further include an auxiliary pump to control a pressure difference between the liquid phase and the gas phase.

According to the present invention, in the ceramic hollow fiber contact membrane module, by arranging the ceramic hollow fiber membranes on a hydrophilic metal mesh and then rolling and potting the ceramic hollow fiber membranes, damage to the ceramic hollow fiber membrane can be prevented, and the ceramic hollow fiber membranes can be evenly disposed in the interior space of the housing, By forming a communication space between the shell side dispersion injection unit and the lumen side dispersion injection unit, the pressure of the fluid is distributed in the ceramic hollow fiber contact membrane module, and there is an effect that stable operation is possible while maintaining the material transfer efficiency without the separation membrane wetting phenomenon.

1 is a conceptual diagram showing the overall structure of a conventional ceramic hollow fiber contact membrane module.
FIG. 2 is a photograph showing a conventional ceramic hollow fiber contact membrane module, (a) a flow of a fluid in a shell side injection part, and (b) a wetting phenomenon due to an absorbent.
3 is a perspective view showing the overall structure of the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.
4 is a photograph of a ceramic hollow fiber contact membrane module according to an embodiment of the present invention.
5 shows the problems of the conventional ceramic hollow fiber membrane potting and the formation of a ceramic hollow fiber membrane bundle formed using a hydrophilic metal mesh in the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.
6 shows a ceramic hollow fiber membrane bundle formed using a hydrophilic metal mesh in the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.
7 illustrates a flow of fluid in a shell side dispersion injection unit in the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.
8 is a cross-sectional view illustrating a flow of a fluid in a cross-sectional view of a shell side dispersion injection unit in a ceramic hollow fiber contact membrane module according to an embodiment of the present invention.
9 illustrates a flow of fluid in a lumen side dispersion injection unit in the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.
10 is a photograph showing a connection part of a ceramic hollow fiber contact membrane module according to an embodiment of the present invention.
11 is a view showing a state in which several unit modules of the ceramic hollow fiber contact membrane module according to an embodiment of the present invention are connected.
12 is a view showing a method of operating the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.
13 is a view in which an auxiliary pump is provided in the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.

While the present invention allows various modifications and variations, specific embodiments thereof are illustrated and shown in the drawings, and will be described in detail below. However, it is not intended to limit the present invention to the particular form disclosed, but rather the present invention encompasses all modifications, equivalents and substitutions consistent with the spirit of the present invention as defined by the claims.

When an element such as a layer, region or substrate is referred to as being “on” another component, it will be understood that it may exist directly on another element or there may be intermediate elements between them. .

Although terms such as first, second, etc. may be used to describe various elements, components, regions, layers and/or regions, these elements, components, regions, layers and/or regions It will be understood that it should not be limited by these terms.

Hereinafter, exemplary embodiments of the present invention will be described in more detail with reference to the accompanying drawings. Hereinafter, the same reference numerals are used for the same components in the drawings, and duplicate descriptions for the same components are omitted.

3 is a perspective view showing an overall structure of a ceramic hollow fiber contact membrane module according to an embodiment of the present invention, and FIG. 4 is a photograph of a ceramic hollow fiber contact membrane module according to an embodiment of the present invention.

3 and 4, the ceramic hollow fiber contact membrane module according to an embodiment of the present invention includes a housing 100 in which the hollow fiber membrane bundle is accommodated, a shell side dispersion injection unit 102, and a lumen side dispersion injection unit. Includes 200.

The housing 100 has a cylindrical large tubular shape, and a housing space having a hollow shape therein is formed, and a plurality of hollow fiber membranes 10 are accommodated in the housing space.

Here, the hollow fiber membrane 10 is a separation membrane formed in a tubular shape having a surface on which fine pores are formed and a hollow, and at this time, the hollow fiber membrane 10 is a ceramic hollow fiber membrane.

5 and 6 show a ceramic hollow fiber membrane bundle formed by using a hydrophilic metal mesh in the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.

Both ends of the bundle of the hollow fiber membrane 10 are fixed by a potting part 400 formed by curing a synthetic resin. The liquid synthetic resin fills the voids between the hollow fiber membranes. At this time, in general, as shown in FIG. 5 in the process of forming the bundle of the hollow fiber membrane 10, when the ceramic hollow fiber membrane 10 is twisted, a phenomenon in which the ceramic hollow fiber membrane is broken occurs when the potting part 400 is formed, Due to the non-uniform distribution of the gaps between the separation membranes, severe fluid drift and bypass phenomena occur at the shell side of the module, resulting in a decrease in mass transfer characteristics.

In order to solve this problem, the present invention, as shown in Figs. 5 and 6, the ceramic hollow fiber membrane 10 is aligned in a line with the hydrophilic metal mesh 500 and then rolled to bundle the hollow fiber membrane 10 Characterized in that to form. The hydrophilic metal mesh 500 is formed in a form surrounding the hollow fiber membrane 10 to prevent the hollow fiber membrane from being broken when the potting part 400 is formed, and by maintaining an appropriate gap between the hollow fiber membranes, it is possible to transfer gas/liquid materials. It secures a space that can be used, secures a space where the adhesive can enter between the hollow fiber membranes and seals when potting the module, and it is possible to prevent drift of the shell side.

At this time, the hydrophilic metal mesh may be used generally used in the art. In an embodiment of the present invention, a hydrophilic stainless mesh was used.

The hollow fiber membrane 10 bundle is preferably formed so that the filling rate of the ceramic hollow fiber membrane in the housing is 10 to 60%. If the filling rate exceeds 60%, there is a problem in that the sealing agent is not properly injected and leaks when the module is manufactured because the sealing agent is not well injected between the hollow fiber membranes.

A plurality of through holes 101 through which a fluid can move are formed at both ends of the housing 100. A shell side dispersion injection unit 102 is installed in the region where the through hole 101 is formed.

The shell side dispersion injection unit 102 surrounds the outer circumferential surface at one end of the cylindrical housing including a region in which the through hole 101 of the housing is formed, and a communication space is formed to communicate with the through hole of the housing, , On one side, entrances 110a and 110b through which the fluid enters are formed.

In the fluid entrances 110a and 110b formed in the shell side dispersion injection units 102 at the top and bottom of the housing 100, the fluid injected through the first entrance 110a is discharged to the second entrance 110b. On the contrary, the fluid injected through the second entrance 110b is discharged through the first entrance 110a. The fluid may be a gas containing an adsorption target or a liquid containing an absorbent, but is not limited thereto.

The ceramic hollow fiber contact membrane module according to the present invention is characterized in that a cross-flow method is applied for the purpose of efficiently meeting a liquid absorbent and a gas to improve mass transfer characteristics. The conventional contact membrane module used a longitudinal-flow method in which a gas phase and a liquid phase meet in parallel in countercurrent or parallel flow with a separator interposed therebetween, but a cross flow method used in the ceramic hollow fiber contact membrane module according to the present invention. Is a method in which the gaseous phase and the liquid phase are induced to be in contact with each other at a specific angle or vertically rather than horizontal. This cross-flow method minimizes the bypass of the shell side of the module and improves the material transfer characteristics because the fluid flow can be formed in a direction hitting the surface of the separator.

7 and 8 illustrate the flow of fluid in the shell side dispersion injection unit in the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.

7 and 8, in the ceramic hollow fiber contact membrane module according to the present invention, the fluid injected into the entrances 110a and 110b of the shell side dispersion injection unit 102 is directly applied to the hollow fiber contact membrane. It is not in contact with but spreads while surrounding the circumference of the housing through a communication space surrounding the housing, and is injected into the hollow fiber contact membrane inside the housing through a plurality of through holes 101a formed in the housing. Therefore, when the fluid is injected, the pressure is evenly distributed and injected, and since the injection is injected in a cross-flow method, stable operation is possible while maintaining high material transfer efficiency without wetting the separator.

The fluid in contact with the hollow fiber contact membrane moves in the longitudinal direction of the hollow fiber contact membrane and exits the housing through a plurality of through holes 101b formed at the ends of the housing. The ceramic hollow fiber contact membrane module according to the present invention can be used in a single stage or can be connected in two stages. Even if the ceramic hollow fiber contact membrane module is connected in two stages, the fluid that escapes to the outside of the housing on the same principle moves through the connection, and the hollow inside the housing through the through hole 101c formed at one end of the housing of the next module. It is injected into the yarn contact membrane, moves in the longitudinal direction of the hollow fiber contact membrane, and exits out of the housing through a plurality of through holes 101d formed at the end of the housing.

The lumen side dispersion injection unit 200 may be coupled to the upper and lower portions of the housing 100, and at one side, entrances 120a and 120b through which the fluid enters and exits the lumen side of the hollow fiber membrane are formed. , A communication space is formed between the lumen side entrances 120a and 120b and the hollow fiber membrane.

In the fluid entrances (120a, 120b) formed in the lumen side dispersion injection unit (200), the fluid injected through the first entrance (120a) is discharged to the second entrance (120b), conversely, to the second entrance (120b). The injected fluid is discharged through the first entrance 120a. The fluid may be a gas containing an adsorption target or a liquid containing an absorbent, but is not limited thereto.

In the ceramic hollow fiber contact membrane module according to the present invention, if a liquid containing an absorbent is injected into the fluid entrances 110a and 110b formed in the shell side dispersion injection unit 102, the lumen side dispersion injection unit 200 ), the gas containing the object to be adsorbed is injected into the fluid entrances (120a, 120b) formed in the shell side, and if the gas containing the object to be adsorbed is injected into the fluid entrances (110a, 110b) formed in the shell side dispersion injection unit (102) In this case, a liquid including an absorbent may be injected into the fluid entrances 120a and 120b formed in the lumen side dispersion injection unit 200.

Preferably, a liquid containing an absorbent is injected into the fluid entrances 110a, 110b formed in the shell side dispersion injection unit 102, and the fluid entrances 120a, 120b formed in the lumen side dispersion injection unit 200 are adsorbed. Gas containing the object may be injected. At this time, the gas containing the adsorption target may be a gas containing CO ₂ and N ₂ , and the liquid containing the absorbent may be an amine-based solution capable of absorbing CO ₂ .

9 illustrates a flow of fluid in a lumen side dispersion injection unit in the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.

As shown in FIG. 9, since the lumen side dispersion injection unit 200 also forms a communication space, the fluid injected through the entrances 210a and 210b of the lumen side dispersion injection unit 200 directly contacts the hollow fiber membrane. Rather, it moves while filling the communication space, so the pressure can be evenly distributed and injected.

Meanwhile, in the ceramic hollow fiber contact membrane module according to the present invention, since the ceramic hollow fiber membrane is fragile when the length is increased, unlike the polymer hollow fiber membrane, efficient connection of unit modules is important to increase the area. Accordingly, the ceramic hollow fiber contact membrane module according to the present invention may further include connection parts 600 and 601 for connecting unit modules.

10 is a photograph showing a connection part of a ceramic hollow fiber contact membrane module according to an embodiment of the present invention.

As shown in FIG. 10, the ceramic hollow fiber contact membrane module according to the present invention may be connected through a lumen side connection part 601 and a shell side connection part 600, and the lumen side connection part 601 and the shell side connection part 600 ) In addition, since the communication space is formed, the moving fluid moves while filling the communication space, so that the pressure in the module is evenly distributed.

11 is a view showing a state in which several unit modules of the ceramic hollow fiber contact membrane module according to an embodiment of the present invention are connected.

As shown in FIG. 11, the ceramic hollow fiber contact membrane module according to the present invention can be connected in several stages using the connection portions 600 and 601 to adjust the length.

In addition, when the hollow fiber contact membrane module is connected to increase the length, the performance of the module at the rear end may decrease due to concentration polarization. Accordingly, a fluid inlet 602 may be formed at one side of the shell side connection part 600. This concentration polarization phenomenon can be minimized by dispersing and supplying a new fluid at the fluid entrance 602 of the connection part.

12 is a view showing a method of operating the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.

As shown in FIG. 12, the ceramic hollow fiber contact membrane module according to the present invention can perform all eight operation methods according to gas/liquid flow, and operation can be performed by selecting an operation condition suitable for the purpose.

At this time, it is important to balance the pressure between the liquid phase and the gas phase. If the pressure of the liquid phase is higher than the minimum permeation pressure, as shown in FIG. 2, a phenomenon in which the pores of the separator are wetted to the liquid phase occurs, thereby significantly reducing the contact membrane performance. In addition, when the pressure of the gaseous phase is high, the gaseous phase is transferred to the liquid phase, and bubbles may be generated in the liquid phase.

Therefore, it is very important to control the pressure difference (ΔP) between the liquid phase and the gas phase in the contact film process. In general, in order to maintain the pressure of the liquid phase slightly higher than that of the gas phase, and to constantly adjust the pressure difference (ΔP) between the liquid phase and the vapor phase, an auxiliary pump may be additionally provided to the ceramic hollow fiber contact membrane module according to the present invention. have.

13 is a view in which an auxiliary pump is provided in the ceramic hollow fiber contact membrane module according to an embodiment of the present invention.

As shown in FIG. 13, the height of the liquid phase can be adjusted according to the height of the auxiliary pump 700, and through this, the pressure difference ΔP between the liquid phase and the gas phase can be adjusted.

According to the present invention, in the ceramic hollow fiber contact membrane module, by arranging the ceramic hollow fiber membranes on a hydrophilic metal mesh and then rolling and potting the ceramic hollow fiber membranes, damage to the ceramic hollow fiber membrane can be prevented, and the ceramic hollow fiber membranes can be evenly disposed in the interior space of the housing, By forming a communication space between the shell side dispersion injection unit and the lumen side dispersion injection unit, the pressure of the fluid is distributed in the ceramic hollow fiber contact membrane module, and there is an effect that stable operation is possible while maintaining the material transfer efficiency without wetting the separator.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only illustrative, and those of ordinary skill in the field to which the technology pertains, various modifications and other equivalent embodiments are possible. I will understand. Therefore, the technical protection scope of the present invention should be determined by the following claims.

10: hollow fiber membrane
100: housing
101, 101a, 101b, 101c, 101d: through hole of housing
102: shell side dispersion injection unit
110a, 110b: fluid inlet of the shell side dispersion unit
200: lumen side dispersion injection unit
120a, 120b: fluid inlet of lumen side dispersion injection unit
400: potting part
500: hydrophilic metal mesh
600: shell side connection
601: lumen side connection
602: fluid inlet of connection
700: auxiliary pump

Claims (10)

Hollow fiber membrane bundle made of a plurality of ceramic hollow fiber membranes;
A hydrophilic metal mesh for preventing drift, surrounding each hollow fiber membrane in the hollow fiber membrane bundle;
A cylindrical housing in which a ceramic hollow fiber membrane bundle surrounded by the hydrophilic metal mesh is accommodated, and a plurality of through holes through which a first fluid is movable are respectively formed at both ends;
A lumen side dispersion injection unit coupled to one end of the housing and having an entrance through which the second fluid enters and exits the lumen side of the hollow fiber membrane, and a communication space formed between the lumenside fluid entrance and the hollow fiber membrane; And
Distributed injection of the shell side at one end of the cylindrical housing surrounding the periphery of the outer circumferential surface, forming a communication space to communicate with the through hole of the housing, and having an entrance through which the first fluid enters and exits the shell side Ceramic hollow fiber contact membrane module comprising a unit. The method of claim 1,
Ceramic hollow fiber contact membrane module, characterized in that the ceramic hollow fiber membrane bundle surrounded by the hydrophilic metal mesh is formed by aligning the ceramic hollow fiber membrane in a line with the hydrophilic metal mesh and then rolling. The method of claim 1,
The hollow fiber membrane bundle is a ceramic hollow fiber contact membrane module, characterized in that formed so that the filling rate of the ceramic hollow fiber membrane in the housing is 10 to 60% by volume. The method of claim 1,
The hydrophilic metal mesh is a ceramic hollow fiber contact membrane module, characterized in that the hydrophilic stainless mesh. The method of claim 1,
The ceramic hollow fiber contact membrane module, wherein the first fluid and the second fluid are in contact with each other in a cross-flow manner. The method of claim 1,
The first fluid is a liquid containing an absorbent, and the second fluid is a gas containing an absorption target. The method of claim 1,
The first fluid is an amine-based solution that absorbs CO ₂ , and the second fluid is a gas containing CO ₂ and N ₂ . The method of claim 1,
In the ceramic hollow fiber contact membrane module, when fluid is injected, the fluid is spread while surrounding the housing through the communication space in the shell side dispersion injection unit, and the pressure is injected through the through hole in a uniformly distributed state to contact the hollow fiber membrane. Ceramic hollow fiber contact membrane module, characterized in that. The method of claim 1,
The ceramic hollow fiber contact membrane module further comprises a connection part for connection of the unit module. According to claim 1
The ceramic hollow fiber contact membrane module further comprises an auxiliary pump to adjust a pressure difference between the liquid phase and the gas phase.

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