KR20110117343A - Bio-catalyst immobilization method for increasing of co2 capture efficiency - Google Patents

Abstract

The present invention improves the immobilization method of a biocatalyst in a method of using a biocatalyst (Enzyme) that can effectively remove carbon dioxide contained in a large fixed source or indoor air, thereby preventing the reduction of the active site of the existing biocatalyst immobilization method. It relates to a biocatalyst immobilization method which can reduce cost and reduce the size of a carbon dioxide absorption reaction system.
According to the present invention, the biocatalyst immobilization by the conventional covalent coupling method through the immobilization method for minimizing the reduction of the active site of the decarboxylase extracted from the human body and cows or the hemosite extracted from the shell, the extrapalyl fluid and excellent carbon dioxide reduction effect In the same reaction conditions than the method can lead to an increase in the carbon dioxide reduction effect.

Description

Bio-catalyst immobilization method for increasing of CO2 capture efficiency

The present invention relates to a method for immobilizing a biocatalyst for improving carbon dioxide capture efficiency, and more particularly, to a method for increasing carbon dioxide capture efficiency by improving a method for immobilizing a biocatalyst used for collecting carbon dioxide discharged from a large fixed source or a room. .

One method of removing carbon dioxide from large fixed sources or indoors is to use biocatalysts (or enzymes).

Biocatalysts used for carbon dioxide removal are human carbonic anhydrase extracted from humans, bovine carbonic anhydrase extracted from bovine serum, and hemocytes or axtrapalls extracted from shellfish such as oysters. Real Fluid (Extrapallial Fluid) is used.

Absorption towers for removing carbon dioxide are used in various shapes of fillers to increase the contact efficiency of carbon dioxide and biocatalyst, and various kinds of materials such as inorganic materials such as silica, resin, chitin, urethane or stainless steel.

The biocatalyst used to remove carbon dioxide is generally used by immobilizing the absorber column as a carrier to improve durability, stable use, and prevent loss of the biocatalyst.

On the other hand, the method of immobilizing a biocatalyst on a carrier includes an adsorption method, an ion bonding method, a crosslinking method, a capture method, a covalent bond method, and the like.

Among these immobilization methods, the covalent bonding method has a strong binding force between the carrier and the biocatalyst, so that the outflow of the biocatalyst can be minimized, and thus, it is suitable to be applied to a continuous process having a high flow rate and a high flow rate such as a power plant and a petrochemical process. In the covalent bonding method, the carrier carrying the biocatalyst is surface-treated with a chemical product to change the electron-friendly functional group to a fixed state, and then the amino group in the carrier and the biocatalyst using a binding material such as glutataraldehyde. Used as a method of bonding.

However, the covalent binding method requires a large amount of biocatalyst in order to show the same efficiency as other immobilization methods because the active site of the biocatalyst binds to chemicals and decreases in activity when the biocatalyst and the carrier are combined. There is a disadvantage that the cost increases. In particular, since the binding of the biocatalyst and the carrier occurs randomly, the probability that the active site of the biocatalyst can bind to the filler is increased, and thus the active site for removing carbon dioxide is partially lost. Therefore, in order to obtain the same effect as an unimmobilized biocatalyst, a larger amount of biocatalyst must be immobilized on a carrier, which results in an increase in the cost of the absorption system and an increase in the reactor size.

An object of the present invention for solving the above problems is to provide an immobilization method for preventing the loss of the activity of the biocatalyst by preventing the active site of the biocatalyst is bound to the carrier in the biocatalyst immobilization method for removing carbon dioxide.

The present invention to achieve the object as described above and to perform the problem to remove the conventional defects 1) to generate a hydroxyl group (-OH) on the surface by activating the carrier, 2) by treating with 3-Aminopropyl triethoxy silane Attaching an amine group (-NH ₂ ) to the surface, 3) forming a carboxyl group (-COOH) on the surface by treating with Glutaraldehyde, 4) combining the surface carboxyl group and the amine group (-NH ₂ ) at the end of the biocatalyst In the method of immobilizing the biocatalyst used to remove carbon dioxide in the carrier,

Biocatalyst for improving the efficiency of carbon dioxide capture efficiency, characterized in that the carbon dioxide used as a reactant before the step 3) after the step 3) as a substrate to prevent the active point is bound in the carrier direction to prevent the reduction of the carbon dioxide active site By providing a method of immobilization.

In the present invention, it is characterized in that the aqueous solution containing the biocatalyst is adjusted to a range of pH 6-8 and 40 ℃ or less so that the biocatalyst can be immobilized in the active state.

In addition, in the present invention, the pH is controlled in the range of 6 to 8, characterized in that by using a tris-HCl buffer solution.

In addition, the present invention is characterized in that to supply the concentration of carbon dioxide injected 0.5-1.0% so that the biocatalyst can be immobilized in the active state.

As described above, the biocatalyst immobilization method for removing carbon dioxide may reduce the amount of biocatalyst required to achieve the same effect by preventing the reduction of the active point of the biocatalyst generated when the existing biocatalyst is supported. ,

In addition, the immobilization method minimizes the reduction of active sites of decarboxylase extracted from humans and cows or from the shells of hemosite and extrapalyl fluids, which are excellent in reducing carbon dioxide. Under the condition that the carbon dioxide reduction effect can be increased,

In addition, it can be reduced in size compared to a carbon dioxide absorption tower containing a packing material (biocatalyst + carrier) manufactured using the existing immobilization method (covalent bonding method), thereby reducing the immobilization cost, device manufacturing cost and operating cost. It is a useful invention having the advantage of being large and is an invention which is expected to be greatly used in industry.

1 is a view showing a comparison of the immobilization method using the biocatalyst immobilization method and the existing covalent bonding method of the present invention according to an embodiment of the present invention,
2 is a view showing the carbon dioxide collection efficiency in the carbon dioxide absorption tower including the same amount of the biocatalyst and the carrier prepared by different immobilization method according to another embodiment of the present invention.

Hereinafter, the configuration and the operation of the embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

The present invention proposes a new method of immobilizing a biocatalyst on a carrier to increase the carbon dioxide removal efficiency.

Immobilization of the biocatalyst to the carrier may include 1) activating the carrier to produce hydroxyl (-OH) on the surface, ₂ ) attaching an amine group (-NH ₂ ) to the surface by treating with 3-Aminopropyl triethoxy silane, 3) forming a carboxyl group (-COOH) on the surface by treating with Glutaraldehyde, 4) bonding the surface carboxyl group and the amine group (-NH ₂ ) at the end of the biocatalyst.

In the biocatalyst immobilization step, in order to prevent the biocatalyst active point from binding to the carboxyl group to reduce the carbon dioxide removal efficiency, carbon dioxide is injected into the substrate before the step 3) and 4) before the active catalyst is bound in the carrier direction. It is characterized by preventing that.

Since glutaraldehyde and carbon dioxide bind competitively to the active site of the biocatalyst, injecting carbon dioxide before step 3) and before step 4) reduces the probability that the active point is combined with glutaaldehyde.

In addition, since the carbon dioxide combined with the active point is separated into the aqueous solution through an exchange reaction with water, the active point of the biocatalyst may be used in a carbon dioxide capture process because the active point exists in an empty space.

The hemosite and extrapalial fluid extracted from human or bovine decarboxylase and already shellfish used in the present invention is a biocatalyst that reacts rapidly with carbon dioxide selectively. Amine groups at other sites will be combined with the carrier.

The carbon dioxide combined with the biocatalyst active point is converted to bicarbonate ion (HCO ₃ ⁻ ) through the following reaction, and is discharged out of the biocatalyst through the exchange reaction with water, so that the active point of the biocatalyst may be combined with carbon dioxide in the future. Can be left empty.

The reaction scheme of reacting with carbon dioxide by the biocatalyst (BC) fixed to the carrier is the same as in Scheme 1, Scheme 2 and Scheme 3.

BC means biocatalyst.

In the present invention, an aqueous solution containing a biocatalyst, a carrier, and the like used to prevent the active site of the biocatalyst from binding to the carrier is used to adjust the pH range between 6.0 and 8.0 using tris-HCl buffer solution. It is characterized by. As the buffer solution, tris-HCl, Phosphate, etc. can be used in various kinds, but the biocatalyst applied to the present invention showed the best carbon dioxide collection efficiency in tris-HCl.

 Among the biocatalysts used in the present invention, anhydrous decarboxylase, hemosite, and extrapalial fluid are extracted from the living body, and the activity decreases outside the pH.

In addition, in order to prevent the active site of the biocatalyst from binding to the carrier, the biocatalyst is maintained at a temperature of 40 ° C. or less so that the biocatalyst can be immobilized in an active state. At temperatures above 40 ° C., the beta-structure in the biocatalyst affects carbon dioxide capture, resulting in reduced activity.

In the present invention, the concentration of carbon dioxide injected to prevent the active site of the biocatalyst from binding to the carrier is characterized in that 0.5 to 1.0% range.

At 0.5% or less, the effect of preventing the active site from binding to the carrier is not great. At 1.0% or more, the activity of the biocatalyst is decreased since the pH is rapidly decreased by the reaction of the biocatalyst and carbon dioxide. Therefore, in the immobilization reaction, the binding probability of carbon dioxide and the biocatalyst is reduced, so that the effect of preventing the reduction of the active site of the biocatalyst is not large.

Hereinafter is a preferred embodiment of the present invention.

Example 1 Biocatalyst Immobilization Method for Removing Carbon Dioxide

Effect of the biocatalyst immobilization method for removing carbon dioxide through the present invention can be represented as shown in FIG.

(a) shows a state in which the active site of the biocatalyst is bound in the carrier direction by using a conventional covalent bonding method, and the active site of the biocatalyst is fixed in a state in which the biocatalyst is randomly immobilized on the surface of the carrier on which the carboxyl group is formed. The probability that an amino group at can bind to a carboxyl group is increased, thus providing an active site for removing carbon dioxide.

(b) shows the effect of supplying carbon dioxide prior to bonding with the carrier to prevent the reduction of the active area of the biocatalyst, in which carbon dioxide is injected during the immobilization of the carrier and the biocatalyst to which the carboxyl group is immobilized. Coupling with carbon dioxide prior to binding reduces the probability that the active site can bind with the carrier. Therefore, a smaller amount of biocatalyst is required than existing biocatalyst immobilization methods, and there is an advantage of reducing the reactor size.

Example 2 Comparison of Carbon Dioxide Removal Results Using a New Biocatalyst Immobilization Method

2 is a view showing the carbon dioxide conversion efficiency in the carbon dioxide absorption tower including the same amount of the biocatalyst and the carrier prepared by different immobilization method according to another embodiment of the present invention.

The embodiment of the present invention is similar to the carbon dioxide concentration contained in the coal-fired power plant flue gas at a temperature of 40 ℃, initial pH 7.0 conditions 12 vol. Percentage of carbon dioxide flows in from the bottom of the absorption tower, and shows the conversion rate of carbon dioxide over time using the reaction system supplied with water at the top of the absorption tower.

As shown in the results, the conversion rate of about 85% was obtained using the covalent bonding method, whereas the conversion rate of about 90% was obtained using the immobilization method developed through the present invention. Got.

In the above embodiment, based on the carbon dioxide concentration contained in the flue gas discharged to the coal-fired power plant, it can be applied to a variety of carbon dioxide concentration range, so not only a large amount of carbon dioxide emission sources such as petrochemical process, cement industry process, steelmaking process, It should be interpreted that it is applied equally to the method of immobilizing biocatalysts applied to offices and transportation facilities.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

Claims (4)

1) generating a hydroxyl group (-OH) on the surface by activating the carrier, 2) attaching an amine group (-NH ₂ ) to the surface by treating with 3-Aminopropyl triethoxy silane, 3) treating with Glutaraldehyde on the surface Forming a carboxyl group (-COOH), 4) bonding the surface carboxyl group to the amine group (-NH ₂ ) at the end of the biocatalyst, and immobilizing the biocatalyst used to remove carbon dioxide to the carrier.
Biocatalyst for improving the efficiency of carbon dioxide capture efficiency, characterized in that the carbon dioxide used as a reactant before the step 3) after the step 3) as a substrate to prevent the active point is bound in the carrier direction to prevent the reduction of the carbon dioxide active site Immobilization Method.
The method according to claim 1,
Biocatalyst immobilization method for improving the carbon dioxide capture efficiency, characterized in that the biocatalyst, the aqueous solution containing the carrier is adjusted to a range of pH 6-8 and 40 ℃ or less so that the biocatalyst can be immobilized in the active state.
The method according to claim 2,
Adjusting the pH in the range of 6 to 8 biocatalyst immobilization method for improving the carbon dioxide capture efficiency, characterized in that by using a tris-HCl buffer solution.
The method according to claim 1,
Biocatalyst immobilization method for improving the carbon dioxide capture efficiency, characterized in that for supplying the concentration of carbon dioxide injected so that the biocatalyst can be immobilized in the active state.

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