KR20120029523A - Separation devices and methods for separating acidic gas from mixed gas - Google Patents

Abstract

PURPOSE: A separating apparatus and a separating method for separating acidic gas from mixed gas are provided to save energy required for degassing acidic gas and to easily dilute absorbent. CONSTITUTION: A separating apparatus for acidic gas includes an absorbing column(201), a degassing column(202), an absorbent introducing path, a re-boiler(203), and a condensed water supplying line. Absorbent absorbing acidic gas is filled in the absorbing column. The degassing column applies thermal energy to degas the absorbed acidic gas. The absorbent introducing path is in connection with the degassing column and supplies additional absorbent diluting liquid to the degassing column. The re-boiler supplies thermal energy to the degassing column. Condensed water from the re-boiler is supplied to the absorbent diluting liquid by connecting the condensed water supplying line and the absorbent introducing path.

Description

Separation Devices and Methods for Separating Acidic Gas from Mixed Gas

The present invention relates to an apparatus and a separation method for separating acidic gas from a mixed gas, and more particularly, to an acid gas separation apparatus and method for saving energy for regenerating absorbent and having excellent process efficiency.

Recently, efforts to capture and store greenhouse gases, which are the causes of global warming, have been racing internationally. In particular, various methods have been tried to reduce carbon dioxide, which has been pointed out as a major cause of global warming.

Exhaust gases emitted from combustion facilities such as thermal power plants contain many acid gases such as carbon dioxide. In order to remove such acid gas, an absorption method using an absorbent has been attempted, and this method has been spotlighted with high efficiency and stable technology.

For example, the amine-based capture process for capturing carbon dioxide is a technique of securing the technical reliability applied in the reforming process, which is one of petrochemical processes as a kind of chemical absorption technology. However, the amine-based capture process is also a separation technology requiring improvement of the process in order to be applied to combustion exhaust gas rather than petrochemical process gas.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-described problems of the prior art and the technical problems required from the past.

The inventors of the present application have confirmed that by using the high-temperature condensed water generated in the reboiler as the diluent of the absorbent, the energy saving effect is excellent without lowering the process efficiency.

Accordingly, it is an object of the present invention to provide an acid gas separation apparatus and separation method excellent in process efficiency and energy saving effect.

Acid gas separation apparatus according to the present invention for achieving this object,

An absorption tower filled with an absorbent absorbing acid gas;

A degassing tower for degassing the adsorbed acid gas by applying thermal energy when an absorbent in which the acid gas is adsorbed is supplied from the absorption tower;

An absorbent input passage fluidly connected to the degassing column to supply an additional absorbent diluent;

A reboiler for supplying thermal energy to the degassing column; And

And a supply line fluidly connected with the absorbent input channel to supply the by-product condensate to the absorbent diluent while supplying thermal energy from the reboiler.

For example, in a reboiler connected to a degassing tower, thermal energy may be supplied through heat exchange with hot steam discharged from a power plant or a boiler. Hot steam is cooled and condensed during the heat exchange process. The condensed water condensed is relatively high temperature, for example, may be 70 ℃ to 100 ℃, depending on the pressure may be 100 ℃ or more. By supplying hot condensate to the degassing column as an absorbent diluent, it is possible to reduce the energy supply required during the regeneration process and to increase process efficiency.

The reboiler serves to supply heat energy to the deaeration tower. The method of supplying the thermal energy is not particularly limited, but for example, the thermal energy may be supplied through heat exchange with hot steam supplied from a power plant or a boiler. In one embodiment, the reboiler may include a heat exchanger for supplying thermal energy.

The acid gas separator may further include a mixing drum for mixing the absorbent and condensed water, which are additionally supplied, and supplying the condensed water to the degassing tower. By supplying the absorbent diluted with high temperature condensed water, the degassing efficiency can be improved. In addition, the acid gas separation device may further include a mixing drum for supplying to the degassing tower by mixing the absorbent and condensed water is additionally supplied. The absorbent diluent supplied from the mixed drum has the effect of replenishing the absorbent in the degassing column and increasing the temperature of the absorbent in which the acidic gas is absorbed to promote degassing to save energy.

The acid gas separation device may further include a gas-liquid separator between the reboiler and the mixing drum to remove gaseous components contained in the condensate. In the process of condensation of high temperature water vapor through heat exchange, a large portion of water vapor may be introduced together with condensate in the liquid state. Water vapor introduced with the condensate can inhibit the pumping in the pipe, thereby inhibiting the smooth flow of the condensate. Thus, gaseous water vapor can be removed through the gas-liquid separator.

The acid gas separator may further include a heat exchanger for exchanging a part of the condensed water condensed in the reboiler with a stream for transferring the absorbent absorbing the acid gas from the absorption tower to the degassing tower. The amount of condensate supplied to the heat exchanger is not particularly limited and may be, for example, supplied to the heat exchanger in the range of 1 to 90% (v / v) or 10 to 70% (v / v) of the condensate. Through this, part of the condensate is directly supplied to the diluent to raise the temperature of the absorbent, and the remaining condensate is subjected to heat exchange with the absorbent entering the degassing column.

In addition, the degassing column separates the acid gas and the absorbent, but the acid gas may flow out with a large amount of water vapor included. This steam can be condensed to obtain hot condensed water. For example, condensed water of high temperature may be obtained by condensing water vapor mixed with acid gas in a degassing column, which may be supplied as an absorbent diluent. More specifically, the acid gas separator, a condenser for condensing the water vapor mixed with the acid gas discharged from the degassing column; And a reflux drum separating the condensed water and the acid gas component condensed through the condenser. In one embodiment, the reflux drum may have a structure in fluid communication with an absorbent inlet passage that is in fluid communication with the degassing tower to supply additional absorbent diluent. In another embodiment, the acidic gas separation device may further include a heat exchanger for exchanging a part of the condensate separated in the reflux drum with a stream transferring the absorbent absorbing the acidic gas from the absorption tower to the stripping column. .

The acid gas separator, the pump for conveying condensate; Or it may include one or a plurality of flowmeters for flow control. The pump facilitates the flow of condensate and controls the flow of condensate based on the results measured by the flow meter.

The type of acid gas that can be separated through the acid gas separation device according to the present invention is not particularly limited, but for example, any one or two selected from the group consisting of carbon dioxide, hydrogen sulfide, sulfur dioxide, nitrogen dioxide, methane and carbonyl sulfide The above may be a mixed gas.

The type of absorbent applicable to the separator may vary depending on the type of acid gas, and the range thereof is not particularly limited. For example, the absorbent may be any one or more selected from the group consisting of amines, amino acid salts, inorganic salts and ammonia, or an aqueous solution thereof.

The present invention also provides an apparatus for regenerating an absorbent for separating acidic gas contained in exhaust gas.

In one embodiment, the absorbent regeneration device,

An absorbent regeneration unit for degassing the absorbed acid gas;

A heat exchanger supplying heat energy to the absorbent regeneration unit;

Mixing unit for mixing the by-product condensed water with the absorbent while supplying heat energy in the heat exchange unit; And

It may include a supply for supplying the absorbent solution mixed in the mixing unit to the absorbent regeneration unit. For example, the absorbent solution mixed with the hot condensate is in a relatively high temperature state and may be supplied to the absorbent regeneration unit for degassing the acid gas from the absorbent. The absorbent regeneration device includes a pump for conveying condensate; Flow meter for flow control; Or one or more nozzles for supplying the absorbent solution.

The type of absorbent applicable to the absorbent regenerating apparatus is not particularly limited, and may be, for example, at least one selected from the group consisting of amines, amino acid salts, inorganic salts, and ammonia or an aqueous solution thereof.

In addition, the present invention provides a method for separating the acid gas contained in the exhaust gas.

In one embodiment, the acid gas separation method,

An absorption step of absorbing the acid gas by reacting the exhaust gas containing the acid gas with an absorbent; And

Degassing process for separating the absorbed acid gas by supplying heat energy to the absorbent absorbed acid gas,

In the degassing process, the heat energy for degassing is supplied, and the by-product condensate is characterized in that the supply of the absorbent diluent. In one embodiment, the acid gas separation method may supply the condensed water as a diluent of the absorbent introduced into the degassing process.

The separation method is to effectively separate the acid gas contained in the exhaust gas discharged from the combustion or chemical process. In general, the acid gas absorbent absorbs the acid gas at low temperature and degass the acid gas absorbed at high temperature. In the degassing process according to the present invention, the supply of thermal energy for degassing and the by-product condensate is in a high temperature state. Therefore, by supplying such hot condensed water as a diluent of the absorbent introduced into the degassing process, there is an advantage that the energy consumption required for degassing the absorbed acid gas can be reduced and the process can be simplified.

The acid gas separation method may be further subjected to a gas-liquid separation process for removing gaseous components contained in condensate. In the process of condensation of high temperature water vapor through heat exchange, a large portion of water vapor may be introduced together with condensate in the liquid state. Since the water vapor introduced with the condensate can inhibit the pumping in the pipe and can inhibit the smooth flow of the condensate, the gas-liquid separation process removes the gaseous water vapor.

The acid gas separation method may use a part of the condensed water to preheat the absorbent introduced into the degassing process. The amount of condensate supplied to preheat the absorbent is not particularly limited, and for example, 1 to 90% (v / v) or 10 to 70% (v / v) of the condensate can be supplied for preheating the absorbent. Through this, a part of the condensate generated is directly supplied to the diluent for raising the temperature of the absorbent, and the remaining condensate is subjected to heat exchange with the absorbent introduced into the degassing process.

In addition, in the degassing process, the acid gas and the absorbent are separated, but the acid gas may include a large amount of water vapor. This steam can be condensed to obtain hot condensed water. For example, condensed water obtained by condensing water vapor discharged together with an acid gas in a degassing process may be supplied to the absorbent diluent. In an embodiment, the method may further include preheating the absorbent introduced into the degassing process by using a part of the condensed water obtained by condensing water vapor discharged together with the acid gas in the degassing process.

The type of acid gas that can be separated through the acid gas separation method according to the present invention is not particularly limited, and for example, any one or two selected from the group consisting of carbon dioxide, hydrogen sulfide, sulfur dioxide, nitrogen dioxide, methane and carbonyl sulfide The above may be a mixed gas.

The type of absorbent applicable to the separation method according to the present invention may vary depending on the type of acid gas, and the range thereof is not particularly limited. For example, the absorbent may be any one or more selected from the group consisting of amines, amino acid salts, inorganic salts and ammonia, or an aqueous solution thereof.

In addition, the present invention provides a method for regenerating the absorbent by supplying thermal energy to the absorbent absorbed acid gas, in one embodiment, the acid gas absorbent regeneration method for supplying condensate by-produced in the process of supplying the thermal energy to the absorbent diluent Can be. For example, heat energy may be supplied using high temperature steam discharged from a power plant or a boiler, and the high temperature steam is cooled and condensed through a heat exchange process. The condensed water condensed is relatively hot, so it can be fed to the absorbent diluent. When hot condensate is supplied to the absorbent diluent, it is possible to reduce the energy supply required during the regeneration process.

In one embodiment, in the absorbent regeneration method, a portion of the condensed water may be used to preheat the absorbent to which the acidic gas is adsorbed. The amount of condensate supplied to preheat the absorbent is not particularly limited, and for example, 1 to 90% (v / v) or 10 to 70% (v / v) of condensate can be supplied for absorbent preheating. Through this, part of the condensate is directly supplied to the diluent to raise the temperature of the absorbent, and the remaining condensate is subjected to heat exchange with the absorbent introduced for regeneration.

The type of absorbent according to the present invention may vary depending on the type of acid gas adsorbed, and the range thereof is not particularly limited. For example, the absorbent may be at least one selected from the group consisting of amines, amino acid salts, inorganic salts and ammonia or an aqueous solution thereof.

As described above, the acid gas separation apparatus and separation method according to the present invention, the dilution of the absorbent is easy, there is an effect of reducing the energy required to degas the acid gas.

1 is a process chart showing a process for collecting acidic gas contained in the mixed gas;
2 is a process chart showing an acid gas collection process according to an embodiment of the present invention.

Hereinafter, the present invention will be further described with reference to the drawings according to the present invention, but the scope of the present invention is not limited thereto.

1 is a process chart showing an acid gas collection process using an absorbent.

Referring to FIG. 1, the exhaust gas 101 is typically adsorbed by reacting with the absorbent 102 at a temperature of 40 ° C. to 60 ° C., and the exhaust gas from which the acid gas is removed is discharged from the absorption tower 201. The absorbent 103 having absorbed the acid gas is heated in the heat exchanger 207 and then injected into the degassing column 202. In order to supply energy for degassing, hot saturated steam 104 is supplied to the reboiler 203, and the saturated steam 104, which has undergone heat exchange, loses thermal energy and condenses and is returned to the boiler in the condensed water 105 state. It is discarded. The supplied energy degass the chemically bound acid gas from the absorbent. The mixed gas 106 of degassed acid gas and water vapor is condensed by the condenser 204 and separated into water and acid gas 107. The separated water is fed back to the degassing column 202 and acidic gas is sent to the treatment process. The absorbent 102 from which carbon dioxide is degassed is transferred to the absorption tower 201 via the heat exchanger 207. In addition, after the absorbent stock solution 109 and the demineralized water 110 are mixed to replenish the consumed absorbent, a predetermined amount is injected into the reflux drum 205.

In this acid gas collection, the cold demineralized water 110 is mixed with the stock solution absorbent 109 and then injected into the dilution, and in severe cases, crystals are not generated to maintain the concentration of the absorbent. In addition, there is a problem that the renewable energy efficiency is lowered by lowering the temperature of the degassing tower 202.

2 is a process chart showing an acid gas collection process according to an embodiment of the present invention.

Referring to FIG. 2, the acid gas collection process includes an absorption tower 201, a degassing tower 202, a reboiler 203, a reflux drum 205, a flash drum 206, and first and second heat exchangers ( 207, 208, and first to seventh pumps 209, 210, 211, 212, 213, 214, and 215.

The absorption tower 201 is supplied with an exhaust gas 101 and an absorbent 102. Exhaust gas 101 includes at least one acidic gas of carbon dioxide (CO ₂ ), hydrogen sulfide (H ₂ S), sulfur dioxide (SO ₂ ), nitrogen dioxide (NO ₂ ), methane (CH ₄ ) and carbonyl sulfide (COS) It may be a chemical process gas or combustion exhaust gas. The exhaust gas 101 is preferably supplied to the absorption tower 201 by the first pump 209 to overcome the pressure drop generated in the absorption tower 201. The absorbent 102 may be used alone or in combination of amines, amino acid salts, inorganic salt solutions, ammonia water, and the like, and is not particularly limited. At this time, the absorbent is preferably used as an aqueous solution in the range of 1 to 50 volume fractions.

In the absorption tower 201, the absorbent 102 and the exhaust gas 101 are in direct contact with each other. The absorbent 102 absorbs the acid gas contained in the exhaust gas 101 to produce the acid gas saturated absorbent 103. The acid gas saturated absorbent 103 is injected into the degassing column 202 in a preheated state by the second pump 210 and the first and second heat exchangers 207 and 208. Unreacted gases such as nitrogen (N ₂ ) and oxygen (O ₂ ) that do not react with the absorbent 102 in the exhaust gas 101 are discharged through the upper portion of the absorption tower 201. The operating temperature of the absorption tower 201 may vary depending on the type of absorbent, for example, the operating temperature of the absorption tower may be maintained in the range of 40 ℃ to 60 ℃.

The acid gas saturated absorbent 103 injected into the degassing tower 202 is degassed by the heat energy supplied from the reboiler 203 while moving to the lower part of the degassing tower 202 and the absorbent is regenerated. The mixed gas 106 mixed with the acid gas and the discharge steam is separated into the condensate and the acid gas 107 through the condenser 204 and the reflux drum 205. The acid gas 107 is transferred to a recovery process or treatment process and used according to storage or use, and the condensate 108 is supplied to the degassing column. The regenerated absorbent is supplied to the upper portion of the absorption tower 201 through the first heat exchanger 207 by the third pump 211.

In addition, in order to replenish the absorbent consumed by deterioration and evaporation, the high temperature by-product condensate 105 of the saturated steam 104 supplied to the heat source of the reboiler 203 may be used.

The acid gas separator is a flash drum 206 for supplying thermal energy for degassing from the reboiler 203 of the degassing column 202 and gas-liquid separation of the by-product high-temperature condensate 105, the fifth for transferring the condensate To seventh pumps 213, 214, and 215, first to second flow meters 216 and 217 to measure the amount of separated condensate and steam, and a mixing drum 218 to mix the absorbent and condensate of the stock solution. . A part of the liquid 111 gas-separated from the flash drum 206 among the condensate 105 is supplied to the dilution by-product condensate 112. A portion 113 of the condensate 105 is then used in the second heat exchanger 208 for preheating the saturated absorbent entering the degassing column and then sent to the boiler.

101: exhaust gas 201: absorption tower
102: regenerated absorbent 202: degassing tower
103: absorbent saturated with acid gas 203: reboiler
104: saturated steam 204: condenser
105: by-product condensation water 205: reflux drum
106: mixed gas of acid gas and water vapor 206: flash drum
107: acid gas 207: first heat exchanger
108: condensate 208: second heat exchanger
109: supplemental absorbent 209: first pump
110: cold demineralized water 210: second pump
111: by-product condensate 211: third pump
112: by-product condensate for dilution 212: fourth pump
113: by-product steam for heat exchange 213: fifth pump
214: sixth pump 215: seventh pump
216: first flow meter 217: second flow meter
218: mixed drum

Claims (26)

An absorption tower filled with an absorbent absorbing acid gas;
A degassing tower for degassing the adsorbed acid gas by applying thermal energy when an absorbent in which the acid gas is adsorbed is supplied from the absorption tower;
An absorbent input passage fluidly connected to the degassing column to supply an additional absorbent diluent;
A reboiler for supplying thermal energy to the degassing column; And
An acid gas separation device including a condensate supply line fluidly connected with an absorbent input channel to supply by-product condensate to the absorbent diluent while supplying thermal energy from the reboiler. The method of claim 1,
The reboiler is acid gas separation apparatus comprising a heat exchanger for supplying thermal energy. The method of claim 1,
The acid gas separator,
The acid gas separator further comprises a mixing drum for supplying the absorbent and condensed water is further supplied to the degassing column. The method of claim 1,
The acid gas separator, between the reboiler and the mixing drum,
An acid gas separator further comprising a gas-liquid separator for removing gaseous components contained in condensate. The method of claim 1,
The acid gas separator,
And an heat exchanger for heat-exchanging a portion of the condensed water condensed in the reboiler with a stream for transferring the absorbent absorbing the acid gas from the absorption tower to the deaeration tower. The method of claim 1,
The acid gas separator,
A condenser for condensing water vapor mixed with acid gas discharged from the degassing column; And
An acid gas separator further comprising a reflux drum separating the condensed water and the acid gas component condensed through a condenser. The method according to claim 6,
The reflux drum is in fluid communication with the degassing column in fluid connection with an absorbent inlet passage for supplying additional absorbent diluent. The method according to claim 6,
The acid gas separator,
And a heat exchanger for heat-exchanging a portion of the condensate separated in the reflux drum with a stream transferring the absorbent absorbing the acid gas from the absorption tower to the stripping column. The method of claim 1,
The acid gas separator,
A pump for conveying condensate; or
Acid gas separator further comprises a flow meter for flow control. The method of claim 1,
The acid gas separator is any one or more selected from the group consisting of carbon dioxide, hydrogen sulfide, sulfur dioxide, nitrogen dioxide, methane and carbonyl sulfide. The method of claim 1,
The absorbent is at least one selected from the group consisting of amines, amino acid salts, inorganic salts and ammonia, or an aqueous solution thereof. An apparatus for regenerating an absorbent for separating acid gas contained in exhaust gas,
An absorbent regenerator for degassing the acid gas absorbed by the absorbent;
A heat exchanger supplying heat energy to the absorbent regeneration unit;
Mixing unit for mixing the by-product condensed water with the absorbent while supplying heat energy in the heat exchange unit; And
An absorbent regeneration device comprising a supply unit for supplying the absorbent solution mixed in the mixing unit to the absorbent regeneration unit. The method of claim 12,
The absorbent regeneration device,
A pump for conveying condensate;
Flow meter for flow control; or
An absorbent regeneration device further comprising a nozzle for supplying an absorbent solution. The method of claim 12,
An absorbent regenerating device, wherein the absorbent is at least one selected from the group consisting of amines, amino acid salts, inorganic salts and ammonia or an aqueous solution thereof. By separating the acid gas contained in the exhaust gas,
An absorption step of absorbing the acid gas by reacting the exhaust gas containing the acid gas with an absorbent; And
Degassing process for separating the absorbed acid gas by supplying heat energy to the absorbent absorbed acid gas,
Acid gas separation method for supplying the thermal energy for degassing in the degassing process and supplying the by-product condensed water as the absorbent diluent. The method of claim 15,
The acid gas separation method, the acid gas separation method for supplying condensed water as a diluent of the absorbent flowing into the degassing process. The method of claim 15,
The acid gas separation method,
Acid gas separation method further undergoes a gas-liquid separation process to remove the gaseous components in the condensate. The method of claim 15,
The acid gas separation method,
Using a portion of the condensate, acid gas separation method further comprising the step of preheating the absorbent flowing into the degassing process. The method of claim 15,
Acid gas separation method further comprising the step of obtaining condensate by condensing the water vapor discharged with the acid gas in the degassing process. The method of claim 19,
The acid gas separation method,
Acid gas separation method using condensed water obtained by condensing water vapor discharged with acid gas in degassing process as absorbent diluent. The method of claim 19,
The acid gas separation method,
And preheating the absorbent introduced into the degassing process by using a part of condensed water obtained by condensing water vapor discharged together with the acid gas degassed from the absorbent in the degassing process. The method of claim 15,
The acid gas is any one or more selected from the group consisting of carbon dioxide, hydrogen sulfide, sulfur dioxide, nitrogen dioxide, methane and carbonyl sulfide. The method of claim 15,
The absorbent is at least one selected from the group consisting of amines, amino acid salts, inorganic salts and ammonia or an aqueous solution thereof. A method for regenerating an absorbent by supplying thermal energy to an absorbent to which acidic gas is adsorbed, wherein the condensed water by-produced in the process of supplying thermal energy is supplied to the diluent of the absorbent. The method of claim 24,
A method of regenerating an acid gas absorbent which uses a part of condensed water to preheat an absorbent absorbed with acid gas. The method of claim 24,
The absorbent is at least one selected from the group consisting of amines, amino acid salts, inorganic salts and ammonia or an aqueous solution thereof.

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