JP2012236155A - Zeolite composite membrane - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a zeolite composite membrane usable in a carbon dioxide selective permeation separation membrane capable of exerting outstanding gas separation characteristics even under the presence of water vapor, in a zeolite composite membrane for recovering carbon dioxide from a mixed gas containing carbon dioxide (CO).SOLUTION: In this zeolite composite membrane, a faujasite (FAU)-type zeolite membrane having a zeolite skeleton of a composition as described below is provided on a porous substrate, AlSiO(in formula, 48≤n≤86). A water repellent coating layer is provided on a surface of the FAU-type zeolite membrane. Preferably, the water repellent coating layer comprises a water repellent zeolite membrane having a composition ratio of silica (Si)/aluminum (Al)≥100, and the surface of the water repellent coating layer of the zeolite composite membrane is preferably silylated.

Description

The present invention relates to a zeolite composite membrane useful for a carbon dioxide selective permeation separation membrane that recovers carbon dioxide from a mixed gas containing carbon dioxide (CO ₂ ).

  In recent years, carbon dioxide, a typical global warming gas, has been emitted from power plants, cement plants, steel plants, and chemical plants. From the viewpoint of preventing global warming, high-efficiency carbon dioxide recovery technology Development is an urgent need. Carbon dioxide is also contained in natural gas mainly composed of methane, and it is necessary to recover and remove carbon dioxide from methane from the viewpoint of preventing pipeline corrosion.

  Conventionally, as carbon dioxide recovery methods, techniques such as chemical absorption methods such as amine absorption methods and physical adsorption methods such as PSA (pressure fluctuation adsorption method) have been used. The development of more efficient recovery methods with high energy consumption is expected.

  By the way, the membrane separation method using a zeolite membrane is capable of continuous operation and does not require regeneration of an absorbing solution or an adsorbent, and thus is expected as a highly efficient carbon dioxide recovery technology.

Currently, as a membrane separation technique for removing carbon dioxide, as described in Patent Document 1 below, a Y-type zeolite separation membrane formed on the surface of a porous base material is used in the presence of water, that is, zeolite. There has been proposed a method for separating carbon dioxide from a gas mixture containing carbon dioxide and nitrogen in a state where water is adsorbed on the separation membrane.

Further, as described in Patent Document 2 below, in the gas separation zeolite membrane composite, a carbon dioxide mixed gas is placed on one side (zeolite membrane side) of the DDR type or Y type zeolite membrane composite, If the carbon dioxide partial pressure on the opposite side (porous support surface side) is set to be equal to or lower than the carbon dioxide partial pressure on the zeolite membrane side, carbon dioxide selectively permeates through the zeolite membrane composite for gas separation, and carbon dioxide mixing It is described that carbon dioxide in the gas can be separated on the surface of the porous support (see paragraph [0023] of Patent Document 2). The carbon dioxide mixed gas is not particularly limited as long as it is a gas containing carbon dioxide, and examples thereof include a mixed gas of carbon dioxide and hydrogen, oxygen, nitrogen, helium, water (water vapor), and the like. (See paragraph number [0024] of Patent Document 2).

Further, in Patent Document 3, when separating a specific gas from a mixed gas containing moisture through pores, the specific gas is specified with high separation efficiency and transmittance without being affected by moisture in the mixed gas. A laminated inorganic separator that can separate gases is disclosed.

Further, Non-Patent Document 1 discloses a hydrophobic silicalite (Silicalite-1) film, and Patent Document 4 discloses a method for producing a silicalite film.

Japanese Patent Laid-Open No. 10-36113 JP 2009-11980 A Japanese Patent No. 3297542 JP 2007-63259 A J. Lindmark et al., Journal of Membrane Science 360 (2010) 284-291.

  However, as described in the above-mentioned patent document, the present inventors have used a zeolite separation membrane in which a zeolite membrane is formed on a porous substrate, and a gas such as hydrogen, methane, carbon monoxide, nitrogen, and oxygen. Attempts were made to remove carbon dioxide from a mixed gas with carbon dioxide. In the presence of water, that is, in a state where water was adsorbed on the zeolite membrane, the amount of carbon dioxide permeation was small, As a result, almost no effect of reducing carbon dioxide was obtained.

On the other hand, in the hydrophobic silicalite (Silicalite-1) membrane, although the influence of carbon dioxide permeation inhibition by moisture is small, for example, in Non-Patent Document 1, carbon dioxide (CO ₂ ) / hydrogen (H ₂ ) There is a report that the separation selectivity is 3 or less, and satisfactory separation performance cannot be obtained.

Further, in Patent Document 3, when a specific gas is separated from a mixed gas containing moisture through the pores, the specific gas is not affected by moisture in the mixed gas and has high separation efficiency and transmittance. Is disclosed, but for example, the separation selectivity of carbon dioxide (CO ₂ ) / nitrogen (N ₂ ) is improved from 0.9 to 1.3 to 1.7. Yes (see paragraph numbers [0034] and [0040] in the published patent specification of Patent Document 3), it is described that the effect is poor.

  An object of the present invention is to solve the above-described problems of the prior art and provide a zeolite composite membrane useful for a carbon dioxide selective permeation separation membrane that can exhibit remarkable gas separation characteristics even in the presence of water vapor.

As a result of intensive studies in view of the above points, the inventors of the present invention, among the zeolite composite membranes hydrophobized the surface of the zeolite membrane provided on the porous substrate, the chemical composition of the zeolite skeleton,
Al _n Si _192-n O ₃₈₄
In the formula, it has been found that a zeolite composite membrane provided with a water-repellent coating layer on the surface of a faujasite (FAU) type zeolite membrane with 48 ≦ n ≦ 86 can exhibit remarkable gas separation characteristics even in the presence of water vapor. The present invention has been completed.

In order to achieve the above object, the invention of the zeolite composite membrane of claim 1 is provided with a faujasite (FAU) type zeolite membrane having a zeolite skeleton having the following composition on a porous substrate,
Al _n Si _192-n O ₃₈₄
In the formula, a water repellent coating layer is provided on the surface of the FAU type zeolite membrane satisfying 48 ≦ n ≦ 86.

  The invention of claim 2 is the zeolite composite membrane according to claim 1, wherein the water-repellent coating layer comprises a hydrophobic zeolite membrane having a composition ratio of silica (Si) / aluminum (Al) ≧ 100. It is characterized by being.

A third aspect of the present invention, a zeolite composite membrane according to claim 1 or 2, the surface of the water-repellent coating layer is silylated, the silyl group (-O-Si-R ₃₎ are formed It is characterized by that.

  In the above formula, R represents an alkyl group, an aryl group, an alkoxide group, a vinyl group, or an amino group.

In the invention of the zeolite composite membrane of claim 1, a FAU type zeolite membrane having a zeolite skeleton having the following composition is provided on a porous substrate,
Al _n Si _192-n O ₃₈₄
In the formula, a water repellent coating layer is provided on the surface of the FAU type zeolite membrane where 48 ≦ n ≦ 86. According to the invention of claim 1, the membrane surface of the hydrophilic FAU type zeolite membrane is By forming a water-repellent coating, the pores of the FAU-type zeolite membrane can be relieved by water (water vapor), and even in the presence of water vapor, a remarkable carbon separation characteristic can be exhibited. It is possible to obtain a useful zeolite composite membrane.

The invention of claim 2 is the zeolite composite membrane according to claim 1, wherein the water-repellent coating layer comprises a hydrophobic zeolite membrane having a composition ratio of silica (Si) / aluminum (Al) ≧ 100. According to the invention of claim 2, by depositing hydrophobic zeolite on the surface of the FAU type zeolite membrane, there is an effect that it is possible to remarkably reduce the gas permeability decrease due to water vapor.

A third aspect of the present invention, a zeolite composite membrane according to claim 1 or 2, the surface of the water-repellent coating layer is silylated, the silyl group (-O-Si-R ₃₎ are formed (Wherein R represents an alkyl group, an aryl group, an alkoxide group, a vinyl group, or an amino group). According to the invention of claim 3, a hydrophobic zeolite is deposited on the surface of a FAU type zeolite membrane. In addition, silyl groups (—O—Si—R ₃ ) are formed by silylation to remove silanol groups on the surface of the zeolite membrane, and in the zeolite composite membrane with improved hydrophobicity, gas permeation by water vapor is performed. There is an effect that it is possible to further greatly reduce the degree of decrease.

It is a schematic diagram for demonstrating the difference in the separation performance of the zeolite composite membrane which is the product of the present invention and the zeolite membrane (Y type) which is a conventional product.

  Next, embodiments of the present invention will be described with reference to the drawings, but the present invention is not limited thereto.

The zeolite composite membrane according to the present invention is provided with a faujasite (FAU) type zeolite membrane having a zeolite skeleton having the following composition on a porous substrate,
Al _n Si _192-n O ₃₈₄
In the formula, a water repellent coating layer is provided on the surface of the FAU type zeolite membrane satisfying 48 ≦ n ≦ 86.

Incidentally, the zeolite membrane is generally a polycrystalline membrane, but it is desirable to use a dense zeolite membrane with few membrane defects such as voids between crystals as a substrate.

Here, as the zeolite membrane, either a tube or a hollow fiber-like porous substrate made of zeolite can be used. However, from the viewpoint of pressure resistance of the membrane element under the high pressure condition, the tubular membrane is used. Is preferred. Conversely, a hollow fiber membrane element can be used from the viewpoint of improving the membrane area per unit volume under low pressure conditions.

Candidates for the zeolite species constituting the zeolite membrane include LTA type, FAU type, CHA type, MOR type, ZSM-5 type, BEA type, etc., but strong with gas having dipole or quadrupole. The chemical composition of the zeolite framework that has an interaction and has a wide pore inlet diameter (0.74 nm)
Al _n Si _192-n O ₃₈₄
In the formula, 48 ≦ n ≦ 86
A FAU type zeolite membrane is preferred.

The FAU type zeolite membrane used as the substrate is not particularly limited as long as there are few membrane defects. For example, a NaY type zeolite membrane manufactured by Hitachi Zosen can be used.

Here, examples of the porous substrate include porous bodies such as alumina, silica, cordierite, zirconia, titania, Vycor glass, and sintered metal, but are not limited thereto, and various porous bodies are used. be able to.

The zeolite composite membrane according to the present invention has a water-repellent coating layer,
It is preferably made of a hydrophobic zeolite membrane having a composition ratio of silica (Si) / aluminum (Al) ≧ 100.

Here, as a hydrophobic zeolite membrane having a composition ratio of silica (Si) / aluminum (Al) ≧ 100, a silicalite membrane, a DDR type zeolite membrane or the like can be considered.

For example, in a silicalite film, a silicalite seed crystal is grown by hydrothermal synthesis at 170 ° C. for 48 hours in a reaction solution prepared to have a composition of SiO ₂ : 0.005TPABr: 0.05 NaOH: 100H ₂ O. The film can be formed by a method (for example, see Patent Document 4).

For the DDR film, in a reaction solution prepared in molar ratio (1-adamantanamine / silica) = 0.125, (ethylenediamine / 1-adamantanamine) = 16, (water / silica) = 56. The DDR seed crystal can be formed by hydrothermal synthesis and crystal growth for 48 hours at 160 ° C. (see, for example, Patent Document 2 above).

Here, the method of hydrophobizing the zeolite membrane surface is not particularly limited, but a method of removing aluminum (Al) in the zeolite skeleton by post-treatment, and modifying the silanol group (—OH) on the zeolite membrane surface Then, a method of coating with a hydrophobic group and depositing a hydrophobic layer can be considered.

However, in the method of removing Al in the zeolitic framework, voids are easily generated in the crystal grain boundaries of the zeolite membrane due to de-Al, and this causes a decrease in the separation performance of the zeolite membrane. It is preferable to provide a water-repellent coating layer, such as by coating with or by depositing a hydrophobic layer.

In the zeolite composite membrane according to the present invention, the surface of the water-repellent coating layer is silylated to form a silyl group (—O—Si—R ₃ ), and the membrane surface is preferably silylated to improve water repellency. .

  In the above formula, R represents an alkyl group, an aryl group, an alkoxide group, a vinyl group, or an amino group.

If silanol groups (—OH) remain on the zeolite membrane surface, the hydrophobicity is lowered even when the zeolite skeleton has a composition ratio of silica (Si) / aluminum (Al) ≧ 100. In order to remove silanol groups (—OH) on the zeolite membrane surface, introduction of alkyl groups by reaction with alkylsilanes or alcohols having functional groups capable of reacting with silanol groups is effective.

In the zeolite composite membrane according to the present invention, the silylation of the surface of the water-repellent coating layer can be performed by, for example, a method of supplying trimethylchlorosilane vapor to the membrane surface at 60 ° C. for 3 hours (for example, the above-mentioned patent document). 4).

FIG. 1 is a schematic diagram for explaining the difference in separation performance between the zeolite composite membrane of the present invention and the conventional zeolite membrane (Y type).

In the figure, a schematic diagram showing a difference between the zeolite membrane of the present invention and a conventional zeolite membrane is shown. In conventional hydrophilic zeolite membranes such as Y-type, in the presence of water vapor, pores are clogged due to moisture adsorbed on the pore surfaces of the zeolite membrane, and the permeability of carbon dioxide (CO ₂ ) and other gases is significantly reduced. .

On the other hand, according to the zeolite composite membrane of the present invention, the water surface of the FAU-type zeolite membrane is reduced by water (water vapor) by forming a water-repellent coating on the surface of the hydrophilic FAU-type zeolite membrane. It was possible to exhibit remarkable gas separation characteristics even in the presence of water vapor. In particular, a zeolite composite membrane in which hydrophobic zeolite is deposited on the surface of a FAU type zeolite membrane, and a composite membrane in which silanol groups on the surface of the zeolite membrane are removed by silylation of the surface of the water-repellent coating layer to improve hydrophobicity. It was possible to greatly alleviate the decrease in gas permeability caused by water vapor.

Zeolite composite membranes of the present invention, since those having the characteristics as described above, for example, the recovery of carbon dioxide (CO ₂₎ from exhaust gas containing water vapor, from the water vapor-containing biogas carbon dioxide (CO ₂₎ New uses as various gas separation membranes such as recovery and recovery of carbon dioxide (CO ₂ ) from high-pressure hydrogen gas containing steam after steam reforming can be expected.

  Examples of the present invention will be described below, but the present invention is not limited thereto.

Example 1
A zeolite composite membrane according to the present invention was produced as follows.

  First, as the FAU type zeolite membrane, a FAU type zeolite membrane (NaY type zeolite membrane, manufactured by Hitachi Zosen) formed on a porous alumina tube was used.

Here, the composition of the zeolite framework of the FAU type zeolite membrane is
Al _n Si _192-n O ₃₈₄
In the formula, 48 ≦ n ≦ 86.

  Next, a water repellent coating layer made of a hydrophobic zeolite membrane (DDR membrane) having a composition ratio of silica (Si) / aluminum (Al) ≧ 100 is formed on the surface of this FAU type zeolite membrane at a molar ratio (1 -DDR coated on a FAU type zeolite membrane in a reaction solution prepared as: adamantaneamine / silica) = 0.125, (ethylenediamine / 1-adamantanamine) = 16, (water / silica) = 56 The seed crystal was prepared by a method of hydrothermal synthesis and crystal growth at 160 ° C. for 48 hours.

  The thus obtained zeolite composite membrane according to the present invention was subjected to a gas permeation test.

(Gas permeation test)
A gas permeation test was performed using the zeolite composite membrane according to the present invention obtained in Example 1 and a conventional FAU type zeolite membrane.

A zeolite composite membrane according to the present invention is installed in a gas separation module (not shown), and a mixed gas of carbon dioxide / water vapor / nitrogen ratio (CO ₂ / H ₂ O / N ₂ = 20: 2: 78) is heated to a temperature of 40 The gas was passed through a gas separation module at 0 ° C., and a CO ₂ / N ₂ mixed gas was brought into contact with the zeolite composite membrane. The permeate side of the zeolite composite membrane was swept with argon gas. And the carbon dioxide gas (permeate gas) which permeate | transmitted the zeolite composite film was sampled, and the gas chromatography (GC) measurement was performed on the following conditions.

Gas analysis: gas chromatography; GC (TCD)
Column: Polapack Q
Carrier gas: Ar
Test gas: CO ₂ / H ₂ O / N ₂ = 20: 2: 78
Gas flow rate: 100ml / min
Inlet gas pressure: 101 kPa
Permeation pressure: Atmospheric pressure (101 kPa)
Permeate side sweep Ar gas flow rate: 100ml / min
For comparison, a zeolite membrane (Y type), which is a conventional product, was subjected to a gas permeation test in the same manner as described above, and sampled carbon dioxide gas (permeated gas) that permeated the zeolite composite membrane. Similarly, gas chromatography (GC) measurement was performed.

    As a result, the zeolite composite membrane according to the present invention clearly has superior gas separation characteristics as compared with the conventional FAU type zeolite membrane, and the hydrophilic FAU type zeolite membrane has a water repellent coating surface. A zeolite composite membrane useful for carbon dioxide selective permeation separation membrane that can relieve blockage of water (water vapor) in pores of FAU type zeolite membrane and can exhibit remarkable gas separation characteristics even in the presence of water vapor is obtained. We were able to confirm that

Next, the surface of the zeolite composite film as the water-repellent coating layer according to the present invention is silylated with trimethylchlorosilane to form a silyl group, —O—Si— (CH ₃ ) _3, thereby forming a silanol group on the surface of the zeolite film. (-OH) was removed,
As for the zeolite composite membrane of the present invention in which the surface of the water-repellent coating layer thus obtained was silylated, a gas permeation test was conducted in the same manner as described above. Thus, it was confirmed that in the zeolite composite membrane in which the silanol group on the surface of the zeolite membrane was removed and the hydrophobicity was improved, it was possible to further significantly reduce the decrease in gas permeability due to water vapor.

Claims (3)

A faujasite (FAU) type zeolite membrane having a zeolite skeleton having the following composition is provided on a porous substrate,
Al _n Si _192-n O ₃₈₄
A zeolite composite membrane, wherein a water-repellent coating layer is provided on the surface of the FAU type zeolite membrane where 48 ≦ n ≦ 86.   2. The zeolite composite film according to claim 1, wherein the water-repellent coating layer is composed of a hydrophobic zeolite film having a composition ratio of silica (Si) / aluminum (Al) ≧ 100. The surface of the water-repellent coating layer is silylated, characterized in that the silyl group (-O-Si-R ₃₎ is formed, a zeolite composite membrane according to claim 1 or 2.
In the above formula, R represents an alkyl group, an aryl group, an alkoxide group, a vinyl group, or an amino group.

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