JP2005161255A - Removing agent of gaseous mercury and its production method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To sufficiently absorb and remove gaseous mercury in high temperature gasified gas or combustion exhaust gas, even in a high temperature region of 150°C or higher, or in some case, 200°C or higher. <P>SOLUTION: From a solution containing one or two or more kinds of metal elements of copper, iron, zinc, tin, calcium, manganese, nickel, silver and lead, precipitate of one or two or more kinds of iron, calcium, zinc, manganese, nickel, copper, silver and lead, formed by precipitation method from the solution are filtered, washed and dried, followed by heating once to at least 150°C, to obtain a gaseous mercury absorbing substance. The removing agent is thus obtained which contains the gaseous mercury absorbing substance and removes gaseous mercury in the high temperature gas containing gaseous mercury. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a gaseous mercury remover and a method for producing the same. More specifically, the present invention relates to gaseous mercury contained in heavy oil or its residual residue, high-temperature gasification gas obtained by gasifying coal or biomass, exhaust gas after combustion such as coal, etc. The present invention relates to a removing agent for removal and a method for producing the same.

Gaseous mercury concentration in the exhaust gas burning coal reaches several [mu] g / m ³ to several tens of μg / m ^3, the number more than the exhaust gas combusted municipal waste and sewage sludge tens [mu] g / m ³ to several hundred In some cases, even μg / m ³ may be reached. In addition, technologies that use coal gasified gas for high-efficiency power generation in gas turbines and fuel cells, and technologies for fuel conversion to alcohol, dimethyl ether, etc. are being studied. Gas produced by gasification also contains gaseous mercury of several μg / m ^{3 to} several hundred μg / m ³ . More specifically, such gaseous mercury exists in two chemical forms, metallic mercury (Hg ⁰ ) and mercury oxide (Hg ²⁺ ). There is a metal mercury (Hg ^0), is in an oxidizing exhaust gas burned coal are believed metallic mercury (Hg ⁰⁾ and oxide mercury (Hg ²⁺⁾ are mixed.

  Gaseous mercury contained in these gases must be sufficiently removed from these gases from the viewpoint of environmental conservation and from the viewpoint of preventing deterioration of the fuel cell and the fuel production conversion catalyst. Conventionally, a wet removal method in which the temperature of the gas is lowered in advance and washed with an absorbing solution has already been put into practical use as a technique for removing gaseous mercury contained in gas such as coal gasified or exhaust gas after combustion. It has become.

  Furthermore, activated carbon and activated coke powder are used to remove gaseous mercury, that is, activated carbon and activated coke powder are blown into the exhaust gas after combustion of incinerated waste to absorb and absorb gaseous mercury. There is also a dry removal method in which the filter is removed by a filter (see, for example, Patent Documents 1, 2, and 3).

JP-A-5-31323 Japanese Patent No. 32007019 Japanese Patent No. 2994789

However, in the wet removal method, water-soluble mercury oxide (Hg ²⁺ ) in gaseous mercury is dissolved and removed in the absorption liquid, but water-insoluble metal mercury (Hg ⁰ ) is difficult to be captured, Since it passes as it is, it is difficult to sufficiently remove gaseous mercury. In addition, the wet removal method requires a wastewater treatment facility for treating the absorption liquid containing mercury, and there is a problem that the system becomes large and complicated. In particular, when applied to gas such as coal gasified, gaseous mercury is metallic mercury (Hg ⁰ ), so most of it cannot be removed, and it corresponds to latent heat due to condensation of moisture in the gas as the gas temperature decreases. Energy is lost, and there is also a loss of energy associated with the heat exchange process that raises the gas temperature again. Therefore, the thermal efficiency in the power generation plant and the fuel production plant is greatly reduced, and a large heat exchanger for raising and lowering the gas temperature is also required.

  In addition, the method of removing gaseous mercury in gas using activated carbon or activated coke powder uses the phenomenon that mercury is physically adsorbed, and the removal performance decreases as the operating temperature increases. Therefore, there is a problem that it cannot withstand use in a high temperature range. In other words, activated carbon or activated coke powder that removes gaseous mercury by adsorption and absorption cannot exhibit sufficient mercury removal performance unless the operating temperature is low, especially gaseous mercury at high temperatures above 200 ° C. Absorption capacity is greatly reduced. Further, if it is intended to compensate for such a decrease in the gaseous mercury absorption capacity, the amount of necessary activated carbon and the like becomes unpractically large and cannot be solved. Therefore, it is necessary to lower the gas temperature also in the method of removing gaseous mercury in the gas using activated carbon, activated coke powder or the like, and although it is improved as compared with the wet removal method, the thermal efficiency is lowered.

  Therefore, the present invention is a method for removing gaseous mercury that can sufficiently absorb and remove gaseous mercury in high-temperature gasification gas and combustion exhaust gas even in a high temperature range of 150 ° C. or higher, and in some cases, 200 ° C. or higher. An object is to provide an agent and a method for producing the same.

In order to achieve this object, the present inventor has conducted various studies. Mercury has a melting point of minus 38.8 ° C and is liquid at room temperature and has a high vapor pressure. From a study by chemical equilibrium calculation, when mercury is heated to 300-400 ° C in air, mercury is oxidized to form HgO, and in the presence of hydrogen chloride, HgCl ₂ forms. It can be seen that the form of mercury oxide (Hg ²⁺ ) is the most stable. On the other hand, in the gas coal and gasified, since mercury be heated remains metallic mercury without reacting (Hg ^0), it is the most stable form of metal mercury (Hg ⁰⁾ in a reducing atmosphere I understand that. In addition, from the examination by the same chemical equilibrium calculation, when the reactivity of mercury in the temperature range from room temperature to 1000 ° C. and elements such as copper, iron, zinc, tin, calcium, manganese, nickel, silver, lead, etc. is obtained, It has been confirmed that mercury does not form a compound with any metal element and exists as gaseous mercury. Therefore, it is considered difficult to absorb and separate gaseous mercury contained in gasification gas and combustion exhaust gas by chemical reaction with elements such as copper, iron, zinc, calcium, manganese, nickel, silver and lead. It was. On the other hand, it is generally known that mercury forms amalgam with many metals, and it has been found that low melting point metals such as thallium, cadmium and lead are particularly easily dissolved in mercury.

  As a result of various experimental studies taking into consideration such characteristics, the present inventor has found that the gaseous mercury removing agent produced by a certain technique has a high temperature of 150 ° C. or higher as described above, and sometimes 200 ° C. It has been found that it is possible to sufficiently absorb and remove gaseous mercury in high-temperature gasification gas and combustion exhaust gas even in the region. The present invention has been made on the basis of such knowledge, and the method for producing a gaseous mercury removing agent according to claim 1 includes copper, iron, zinc, tin, calcium, manganese, nickel, silver and lead metal elements. Filtering and washing one or more precipitates of copper, iron, zinc, tin, calcium, manganese, nickel, silver and lead produced by a precipitation method from a solution containing one or more of And then drying and further heating to at least about 150 ° C. to obtain a gaseous mercury-absorbing substance, and the gaseous mercury in the high-temperature gas containing the gaseous mercury-absorbing substance and containing gaseous mercury is removed. The removal agent which can do is obtained. The precipitation method here is a method of changing a dissolved metal into an insoluble precipitate, more specifically, a metal that is insoluble by adding alkali to an acidic solution in which the metal is ionized and dissolved. It means a method for producing a precipitate of oxide, metal hydroxide or metal nitrate.

  The invention according to claim 2 is the method for producing a gaseous mercury removing agent according to claim 1, wherein the solution is stirred and homogeneous when the precipitate is produced from the solution containing the metal element by the precipitation method. A precipitate is formed.

  According to a third aspect of the present invention, there is provided the method for producing a gaseous mercury removing agent according to the first aspect, wherein a heat-resistant substrate is mixed in advance with a solution containing a metal element, whereby the gaseous mercury absorbing substance is treated as described above. It is a very finely dispersed and supported on a heat resistant substrate. Specific examples of the heat-resistant substrate applicable here include silicon oxide, silica sol, aluminum oxide, activated alumina, alumina sol, and titanium oxide.

  Further, the gaseous mercury removing agent according to claim 4 is prepared by precipitating a solution containing one or more of copper, iron, zinc, tin, calcium, manganese, nickel, silver and lead metal elements. The generated precipitate of one or more of copper, iron, zinc, tin, calcium, manganese, nickel, silver and lead is filtered, washed, dried, and once heated to at least about 150 ° C. It contains the gaseous mercury absorbing material obtained by doing this, and makes it possible to remove the gaseous mercury in the high-temperature gas containing gaseous mercury.

  According to the first aspect of the present invention, a gaseous mercury removing agent capable of absorbing gaseous mercury in a high-temperature gas such as gasification gas or combustion exhaust gas can be produced by the production method unique to the present invention. Moreover, this gaseous mercury removing agent can absorb gaseous mercury in a temperature range of 100 ° C. or higher, and can absorb and remove gaseous mercury without significantly lowering the gas temperature in the plant. Therefore, gaseous mercury contained in the high-temperature gas can be absorbed and removed while avoiding a significant decrease in the thermal efficiency of the plant. Moreover, the gaseous mercury remover produced by this process can effectively absorb and remove gaseous mercury in gases at high temperatures of 150 ° C or higher, and in some cases even higher temperatures of 200 ° C or higher. Therefore, it is possible to remove gaseous mercury in a high temperature range, which was difficult in the past.

  According to the second aspect of the present invention, when the precipitate is produced from the solution containing the metal element by the precipitation method, the solution is stirred, so that the neutralization reaction proceeds homogeneously and the product becomes fine. The surface area of the gaseous mercury-absorbing material obtained through drying, pretreatment, etc. becomes larger. For this reason, the absorptive capacity exhibited by the removing agent is increased, and the gaseous mercury removing performance is improved.

  According to the third aspect of the present invention, when the precipitate is produced from the solution containing the metal element by the precipitation method, the gaseous mercury-absorbing substance is converted into the heat-resistant substrate by previously mixing the heat-resistant substrate with the solution. Highly dispersed and supported on the top. Although this heat-resistant substrate itself does not have the ability to remove gaseous mercury, the surface area of the gaseous mercury removing agent is increased in the gaseous mercury removing agent produced by the production method of the present invention. The function as a carrier is expressed. For this reason, the absorption capability which a gaseous mercury removing agent exhibits increases, and the performance which removes gaseous mercury improves.

  According to the invention described in claim 4, a gaseous mercury removing agent capable of absorbing gaseous mercury in a high-temperature gas such as gasification gas or combustion exhaust gas can be obtained through a specific manufacturing method (process). Moreover, this gaseous mercury removing agent can absorb gaseous mercury in a high temperature range of 100 ° C. or higher, and can remove gaseous mercury without drastically reducing the gas temperature in the plant. Therefore, it is possible to remove gaseous mercury contained in the high-temperature gas while avoiding a significant decrease in the thermal efficiency of the plant. In addition, the gaseous mercury remover produced by this process can effectively absorb and remove gaseous mercury in gases at high temperatures of 150 ° C or higher, and in some cases even higher temperatures of 200 ° C or higher. Thus, it is possible to obtain a gaseous mercury removing agent that can be used even in a high temperature range, which has been difficult in the past.

  Hereinafter, the configuration of the present invention will be described (see FIG. 1 and the like). The gaseous mercury removing agent according to the present invention includes one or more metal compounds of metal elements of copper, iron, zinc, tin, calcium, manganese, nickel, silver, and lead, specifically, One or more precipitates of copper, iron, zinc, tin, calcium, manganese, nickel, silver and lead produced by precipitation from a solution of metal nitrate, metal chloride, metal hydroxide, etc. It contains a gaseous mercury-absorbing substance obtained by filtering, washing, drying, and heating once to at least about 150 ° C. The gaseous mercury-absorbing material obtained in this way is mainly in the form of metal oxides, and exhibits sufficient ability to remove gaseous mercury in the gas at high temperatures of at least 100 ° C and in some cases 200 ° C and above. It is characterized by doing. The gaseous mercury removing agent may be composed of only the above-described gaseous mercury absorbing material, but may be combined with a heat resistant substrate. The heat-resistant substrate itself does not have a gaseous mercury removing performance, but functions as a carrier for improving the mercury removing performance by highly dispersing and supporting a metal oxide that is a gaseous mercury absorbing material. The content of gaseous mercury-absorbing substances in the gaseous mercury removal agent is 100% by weight when it is composed of metal oxides only, and 100% by weight when it is composed of these and heat-resistant substrates. Needless to say, the amount is preferably at least 10% by weight in terms of exhibiting sufficient removal ability. The target gas is heavy oil or its residual residue, gasification gas obtained by gasifying coal or biomass, exhaust gas that burns those fuels, city waste, sewage sludge, etc. It is a high-temperature gas containing gaseous mercury such as exhaust gas from incineration of waste, and gaseous mercury contained in these gases is to be removed.

  By the way, one or more precipitates of each element of copper, iron, zinc, tin, calcium, manganese, nickel, silver and lead produced by the precipitation method are heated in air at a high temperature of 500 ° C or higher. It has been found that the performance of removing gaseous mercury is low when it is fired. In contrast, in the present embodiment, in the final stage of producing the gaseous mercury remover, heavy oil or its residual liquid, coal, biomass, etc. are gasified by firing treatment at a temperature range of 400 ° C. or lower. The performance of removing gaseous mercury contained in the high-temperature gasification gas obtained by gasification and the exhaust gas that burned them is developed.

  The above-described embodiment is an example of a preferred embodiment of the present invention, but is not limited thereto, and various modifications can be made without departing from the scope of the present invention.

  The gaseous mercury removing agent contained in the high-temperature gasification gas and combustion exhaust gas according to the present invention was produced by a precipitation method. As an example, a remover containing copper, a remover containing copper, iron and silicon oxide, a remover containing copper and silicon oxide, and a remover containing zinc and iron were produced, respectively. (See FIG. 2). FIG. 1 shows the relationship between the temperature of the gaseous mercury removing agent and the metal mercury concentration after the reaction. Among these, the difference between the metal mercury concentration at the reactor inlet indicated by the dotted line and the plotted point is shown. This means that the mercury equivalent to was removed.

  First, as Example 1, a gaseous mercury removing agent containing copper was produced by the following method. An aqueous solution in which 242 g of copper nitrate trihydrate is dissolved in water and the total amount is 1000 ml is heated to 60 ° C., and a small amount of the aqueous solution in which 80 g of sodium hydroxide is dissolved in water and the total amount is 500 ml is stirred. Added in increments. The produced precipitate was filtered, washed, dried and pulverized to obtain a powder containing copper. This was calcined in a nitrogen stream at a temperature of 150 ° C. to obtain a gaseous mercury removing agent.

Next, as Example 2, a gaseous mercury removing agent containing copper, iron and silicon oxide was produced by the following method. 194 g of silica sol was added to an aqueous solution in which 81 g of copper nitrate trihydrate and 269 g of iron (III) nitrate nonahydrate were dissolved in water to make a total volume of 1000 ml. The added silica sol is in such an amount that the molar ratio of copper, iron and silicon ((Cu + Fe) / Si) in the aqueous solution is 1.5. The mixed aqueous solution was heated to 60 ° C., and an aqueous solution in which 107 g of sodium hydroxide was dissolved in water to make a total amount of 670 ml was added little by little while stirring. The produced precipitate was filtered, washed, dried and pulverized to obtain a powder containing copper, iron and silicon. This was calcined in a nitrogen stream at a temperature of 150 ° C. to obtain a gaseous mercury removing agent. The content of gaseous mercury absorbing material (CuFe ₂ O ₄ ) in the gaseous mercury removing agent was 67% by weight.

  Further, as Example 3, a gaseous mercury removing agent containing copper and silicon oxide was produced by the following method. 194 g of silica sol was added to an aqueous solution in which 242 g of copper nitrate trihydrate was dissolved in water and the total amount was 1000 ml. The added silica sol is such that the molar ratio of copper to silicon (Cu / Si) in the aqueous solution is 1.5. The mixed aqueous solution was heated to 60 ° C., and an aqueous solution in which 80 g of sodium hydroxide was dissolved in water to make the total amount 500 ml was added little by little while stirring. The generated precipitate was filtered, washed, dried, and pulverized to obtain a powder containing copper and silicon. This was calcined in a nitrogen stream at a temperature of 150 ° C. to obtain a gaseous mercury removing agent. The content of gaseous mercury absorbing material (CuO) in the gaseous mercury removing agent was 66% by weight.

  Further, as Example 4, a gaseous mercury removing agent containing zinc and iron was produced by the following method. 99 g of zinc nitrate hexahydrate and 269 g of iron (III) nitrate nonahydrate were dissolved in water to make a total volume of 1000 ml. This aqueous solution was heated to 60 ° C., and an aqueous solution in which 133 g of ammonia water was dissolved in water to make the total amount 500 ml was added little by little while stirring. The produced precipitate was filtered, washed, dried and pulverized to obtain a powder containing zinc and iron. This was calcined in a nitrogen stream at a temperature of 150 ° C. to obtain a gaseous mercury removing agent.

For gas-phase mercury removing agent obtained in the above example were evaluated performance of removing gaseous metallic mercury contained in the nitrogen gas (Hg ⁰⁾ (see FIG. 1). In addition, for comparison with a gaseous mercury removing agent, a commercially available activated carbon (Wako Pure Chemical Industries, Ltd.) as Comparative Example 1, and a commercially available gaseous mercury adsorbent (Ajinomoto Fine Techno Co., MA-G) as Comparative Example 2. Type) was also evaluated for its ability to remove gaseous metallic mercury (Hg ⁰ ) contained in nitrogen gas. The metal mercury concentration shown on the vertical axis of the figure represents the concentration of metal mercury contained in the gas after passing through the removal agent (or adsorbent). The smaller this value, the better the removal ability (adsorption ability). Become. In both Comparative Example 1 (commercial activated carbon) and Comparative Example 2 (commercial gaseous mercury adsorbent), the removal performance declines as the temperature increases. For example, Comparative Example 2 (□ in the figure) with high performance is 150 ° C. This shows that gaseous mercury cannot be completely removed. On the other hand, it was found that the remover (Examples 1 to 4) produced by the method according to the present invention can remove gaseous mercury even in a higher temperature range, for example, about 220 ° C. Among them, the Cu / Si-based removal agent (● in the figure) that combines copper and silicon in Example 3 absorbs and removes almost all of the mercury even at 265 ° C. Was found to be expensive. This Cu / Si-based remover has higher performance than the Cu-based remover of Example 1 (♦ in the figure) because mercury is added by adding a heat-resistant substrate (silica sol in this example) in the manufacturing process. This is probably because copper, which is an absorbent material, was highly dispersed, and its surface area increased to facilitate contact with gaseous mercury, resulting in a more appropriate shape as a removal agent. Also, the Cu / Fe / Si-based remover of Example 2 (■ in the figure) and the Zn / Fe-type remover of Example 4 (▲ in the figure) are excellent under high temperature conditions as shown in FIG. It was confirmed that the mercury removal performance was excellent. In addition, when the mercury contained in the removal agent after the test was quantified, the content was almost the same as the mercury removed during the test, and the gaseous mercury removal agent absorbed and immobilized the mercury in the gas. It was confirmed.

In the above Examples 1 to 4, the final stage of producing the gaseous mercury removing agent by the precipitation method is carried out at a temperature of 150 ° C. under the flow of nitrogen gas. Comparison was made using a Cu / Si-based remover (see FIG. 2). In this example, this pretreatment was not performed, and the filtered copper and silicon precipitate was used as it was for the evaluation of the removal performance. This precipitate (gaseous mercury removal agent) was not able to remove gaseous mercury under low temperature conditions of 100 ° C. or lower (see the low temperature side of ◆ in the figure). That is, it was confirmed that mercury could not be sufficiently removed by the precipitate itself obtained in the production. This is presumably because the chemical form of the precipitate is Cu ₂ (NO ₃ ) (OH) ₃ and the gaseous mercury removal performance of this substance is low. On the other hand, when the temperature of the removal agent was set to 150 ° C. or higher, the removal performance of gaseous mercury was expressed (see FIG. 2). This operation (heating to 150 ° C. or higher) is the same as the pretreatment in nitrogen in Examples 1 to 4, and the mercury obtained by raising the temperature of the precipitate obtained by the precipitation method in a nitrogen stream. It was confirmed that it changed to a form that can be removed. On the other hand, it was also confirmed that the precipitate obtained by the precipitation method was calcined at 500 ° C. in the air and did not have sufficient gaseous mercury removal performance (■ in the figure). Although the chemical form of the metal compound contained in the removal agent is the same as that of copper oxide (CuO), the sintering of the particles progresses due to the high-temperature firing treatment, and the contact with gaseous mercury decreases. This is because the removal performance deteriorated due to the above. That is, the removal agent is preferably fired at about the temperature at which the removal agent is used, specifically at 400 ° C. or less. In addition, the gaseous mercury removing agent can be used as a gaseous mercury removing agent in a high-temperature gas while maintaining the temperature as long as it is fired at a temperature of 150 ° C. in the final stage of production by the precipitation method. Alternatively, it can be used as a gaseous mercury removing agent in a high-temperature gas after the temperature is lowered to room temperature once after the baking treatment.

In the above-described embodiments, the removal performance of gaseous metallic mercury (Hg ⁰ ) contained in nitrogen gas was evaluated, but it is general that many gas components are mixed in the actual use situation. . For example, since the gas obtained by gasifying coal or the like is a reducing gas containing carbon monoxide, carbon dioxide, hydrogen and water vapor, the gaseous mercury removing agent must be usable even in a reducing atmosphere. Therefore, for the Cu / Si-based removal agent, the removal performance of gaseous mercury against a gas simulating coal gas (carbon monoxide 20%, carbon dioxide 5%, hydrogen 8%, water vapor 4%, nitrogen 63%) was evaluated. (See FIG. 3). As a result, it was found that the Cu / Si-based removal agent can remove almost all gaseous mercury even under the condition of 250 ° C, as well as the removal performance of gaseous mercury in nitrogen gas (● in the figure). ■). In other words, it has been confirmed that this remover can be applied in reducing gas, and technology that utilizes gas obtained by gasifying coal or the like for high-efficiency power generation in gas turbines, fuel cells, etc., and further to alcohol and dimethyl ether In the technology used for fuel conversion, it was confirmed that gaseous mercury mixed as an impurity can be removed before the gasification gas is used.

  On the other hand, since the gas which burned coal etc. is oxidizing gas containing oxygen, a carbon dioxide, and water vapor | steam, the gaseous mercury removal agent must be usable also in oxidizing atmosphere. Therefore, the removal performance of gaseous mercury with respect to an oxidizing gas in which the oxygen concentration contained in the gas was changed under a temperature condition of 200 ° C. was evaluated for the Cu / Si-based removal agent (see FIG. 4). As a result, it was found that the Cu / Si-based remover can remove almost all gaseous mercury contained in the gas even under the condition of oxygen concentration of 0 to 10%. That is, it was confirmed that this removal agent can be applied even in oxidizing gas, and it was confirmed that gaseous mercury mixed as an impurity in exhaust gas obtained by burning coal or the like can be removed.

Gaseous mercury exists in two chemical forms, metallic mercury (Hg ⁰ ) and mercury oxide (Hg ²⁺ ). For example, it is considered that metallic mercury (Hg ⁰ ) and mercury oxide (Hg ²⁺ ) are mixed in the oxidizing gas burned from coal, etc., so it is desirable to remove both of them as a gaseous mercury removing agent. It is. Therefore, the removal performance of gaseous mercury for a gas containing both metallic mercury (Hg ⁰ ) and mercury oxide (Hg ²⁺ ) was evaluated for the Cu / Si-based removal agent (see FIG. 5). As a result, it was found that this remover can almost remove mercury even at a temperature exceeding 260 ° C. That is, it was confirmed that this remover can be removed from the gas regardless of the chemical form of mercury.

It is a graph which shows the relationship between the gaseous mercury density | concentration after the removal reaction by a gaseous mercury removing agent, and the temperature at that time about each of the Example of the gaseous mercury removing agent of this invention, and a comparative example. It is a graph which shows the relationship between the gaseous mercury density | concentration at the time of changing the pre-processing method regarding the Cu / Si type removal agent, and the temperature at that time. It is a graph which shows the relationship between the gaseous mercury density | concentration on conditions with reducing gas regarding the Cu / Si type removal agent, and the temperature at that time. It is a graph which shows the relationship between the gaseous mercury density | concentration at the time of changing oxygen concentration on the conditions that it is in oxidizing gas, and the temperature at that time regarding a Cu / Si type removal agent. Relates Cu / Si-based removers are graphs showing the relationship between the metal mercury (Hg ⁰⁾ and gaseous mercury concentration in both including conditions mercury oxide (Hg ²⁺⁾ and the temperature at that time.

Claims (4)

  Copper, iron, zinc, tin, calcium, copper, iron, zinc, tin, calcium produced by a precipitation method from a solution containing one or more of each metal element of copper, iron, zinc, tin, calcium, manganese, nickel, silver and lead, One or more precipitates of manganese, nickel, silver and lead are filtered, washed, dried, and heated to at least about 150 ° C to obtain a gaseous mercury absorbing material. A method for producing a gaseous mercury removing agent that obtains a removing agent capable of removing gaseous mercury in a high-temperature gas containing gaseous mercury-absorbing substance and containing gaseous mercury.   The method for producing a gaseous mercury removing agent according to claim 1, wherein when the precipitate is produced from the solution containing the metal element by a precipitation method, the solution is stirred to produce a homogeneous and fine precipitate.   The gaseous mercury removal according to claim 1, wherein the gaseous mercury absorbing material is dispersed and supported on the heat resistant substrate in an extremely fine manner by mixing a heat resistant substrate in advance with the solution containing the metal element. Manufacturing method. The copper, iron, zinc, tin, calcium, copper, iron, zinc, tin, calcium, the copper, iron, zinc, tin, calcium, which produces a solution containing one or more of each metal element of each metal element of copper, iron, zinc, tin, calcium, manganese, nickel, silver and lead; Contains gaseous mercury-absorbing substances obtained by filtering, washing, drying, and heating at least about 150 ° C to precipitates of one or more of manganese, nickel, silver and lead. A gaseous mercury remover that makes it possible to remove gaseous mercury in a high-temperature gas containing gaseous mercury.

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