KR101036651B1 - Recovery method of carbon dioxide from off gas by non used waste heat utilization - Google Patents

Abstract

The present invention relates to a method for recovering carbon dioxide, and more particularly, (a) supplying exhaust gas containing carbon dioxide to an absorption tower to which ammonia water is supplied to absorb carbon dioxide contained in the exhaust gas with ammonia water, and (b) the carbon dioxide. And transporting the absorbed ammonia water to the stripping column, and (c) separating and recovering carbon dioxide from the ammonia water absorbed by the carbon dioxide using waste heat of the flue flue gas, and regenerating the ammonia water. It provides a method for recovering carbon dioxide comprising.

CO2, Separation, Recovery, Waste, Flue Flue

Description

Recovery method of carbon dioxide from off gas by non used waste heat utilization}

The present invention relates to a method for recovering carbon dioxide for efficiently and economically separating and recovering carbon dioxide from off gas of an industrial process, and more particularly, to absorb carbon dioxide from exhaust gas and absorb carbon dioxide using ammonia water as an absorbent. The present invention relates to a method for recovering carbon dioxide, including a method of regenerating ammonia water using low temperature unutilized energy such as flue flue gas.

In general, in industrial processes, combustion flue gas or blast furnace flue gas is discharged after completion of the process, and the flue gas contains carbon dioxide, causing global warming. Therefore, various methods of recovering carbon dioxide from the exhaust gas have been studied, and adsorption, absorption, membrane separation, and the like have been used.

Among them, as the absorption method using a chemical absorbent, in general, the absorbent liquid which absorbs carbon dioxide is most used as an amine absorbent, and is currently used most commercially as a representative chemical absorbent.

However, since the amine compound is expensive and the corrosion of the device is large, the recent development of absorbents has been made.

An object of the present invention is to recover carbon dioxide by using ammonia water as an absorbent from a mixed gas containing carbon dioxide, such as combustion flue gas or blast furnace flue gas, and in particular, to recover the low temperature flue flue gas which is not utilized as an economic problem when regenerating the absorbent, and then waste heat thereof. It is to provide a method for recovering carbon dioxide used as a renewable energy of the absorbent by using.

The present invention for achieving the above object,

(a) supplying exhaust gas containing carbon dioxide to an absorption tower to which ammonia water is supplied to absorb carbon dioxide contained in the exhaust gas with ammonia water,

(b) transferring the ammonia water absorbed by the carbon dioxide to a stripping column,

(c) separating and recovering carbon dioxide from the ammonia water absorbed by the carbon dioxide using waste heat of the flue-gas and regenerating the ammonia water

It provides a method for recovering carbon dioxide comprising a.

Hereinafter, the present invention will be described in detail.

The present invention relates to a method for recovering carbon dioxide, which comprises a step of separating and recovering carbon dioxide from ammonia water absorbing carbon dioxide using waste heat of flue flue gas which has not been conventionally used, and simultaneously regenerating ammonia water. That is, the present invention is characterized by recovering and utilizing this waste heat because the temperature of the exhaust gas discharged from the stack of the final process is high.

In other words, unlike amine-based absorbers, ammonia water, which has been known for a long time, is used as an absorber for carbon dioxide. Ammonia water has recently attracted attention as an absorbent because it is cheaper and the corrosion problem of the device is significantly less than that of the amine absorbent.

By the way, in addition to these characteristic values, the ammonia water shows the most distinctive difference as compared to the amine absorbent. In general, when the amine absorbent absorbs carbon dioxide and regenerates the absorbent, a regeneration temperature of about 120 to 140 ° C. is required. However, in order to supply such a regeneration temperature, high-pressure steam at a temperature of 160 ° C. to 200 ° C. is required, and in fact, the part which most affects the economics in the amine absorption process is the production cost of steam used for the regeneration of the absorbent. In addition, the temperature of the exhaust gas to be lowered to about 40 ℃ before being supplied to the absorption process, there is a problem to use a cooling water for this purpose. Figure 1 briefly shows a process diagram of the carbon dioxide recovery method using a conventional amine-based absorbent. As shown in Fig. 1, carbon dioxide-containing flue gas is transferred from a flue gas discharge source to a washing tower continuously supplied with cooling water, and the temperature of the flue gas is lowered to 40 ° C by the coolant and then introduced into the amine absorption step. In addition, in the case of the amine absorption process, a high pressure steam for regenerating the amine absorbent must be supplied.

For this reason, the development of the carbon dioxide recovery process using the ammonia water as the absorbent has been actively made. When using ammonia water as the absorbent, the temperature of steam required for regeneration is about 115 to 130 ° C., which is sufficient, and the regeneration temperature is lower than that of the amine absorbent requiring high pressure steam. For example, the ammonia water varies depending on the concentration of ammonia, but even when 5% by weight of ammonia water is used, the regeneration temperature is very low compared to amines at about 86 ° C. Even 2% by weight of ammonia water is about 96 ℃. However, even when the ammonia water is used, since it is necessary to provide steam separately for regeneration until now, it is not economically preferable because a facility for providing separate steam is required.

In order to solve the above problems, the present invention, in the absorption process for recovering carbon dioxide, when using ammonia water as the absorbent and reusing the ammonia water absorbed carbon dioxide to be used again, by recovering the waste heat from the flue gas as a renewable energy low pressure Steam is produced and then used as renewable energy. Therefore, according to the present invention, carbon dioxide can be economically recovered by replacing the energy required for the production of renewable energy of ammonia water with waste heat of the flue-gas.

In general, the temperature of the combustion flue gas of the power plant or steel mill is about 150 ~ 200 ℃, the temperature of the flue gas discharged after recovering the waste heat in the hot blast furnace flue gas of the blast furnace is about 200 ℃. At this time, when recovering the waste heat of the flue-gas of the stack of the temperature range using a heat pipe can be produced steam of 120 ℃ or more. However, in terms of using steam, waste heat recovery steam at this temperature has been discharged to the atmosphere because it is considered to have no conventional use and economical efficiency of recovery cost.

However, the present invention is characterized in that in the carbon dioxide recovery process using ammonia water, in order to produce steam required for the regeneration of ammonia water, the waste heat of the combustion flue gas discharged to the atmosphere most of the prior art, such as the flue gas of the stack is recovered and used. . Therefore, in the case of using the conventional ammonia water as the absorbent, it is necessary to separately provide steam for regeneration, but the present invention does not need to supply energy separately.

The method for recovering carbon dioxide of the present invention comprises the steps of: (a) supplying the exhaust gas containing carbon dioxide to an absorption tower to which ammonia water is supplied to absorb carbon dioxide contained in the exhaust gas with ammonia water, and (b) ammonia water absorbed with the carbon dioxide. Transporting to the stripping column, (c) separating and recovering carbon dioxide from the ammonia water absorbed by the carbon dioxide using waste heat of the flue flue gas, and regenerating the ammonia water.

In more detail, the present invention is to recover the exhaust gas containing carbon dioxide before it is discharged to the atmosphere and then supply it to the absorption tower, the absorption tower in the absorption tower to selectively absorb only the carbon dioxide and the remaining gas at the top of the absorption tower To be discharged. The ammonia water passes through a heat exchanger using a pump, and the ammonia water absorbed by carbon dioxide flows into a stripper equipped with a reboiler for separating and recovering carbon dioxide. Thereafter, using waste heat of the flue-gas of the stack, carbon dioxide is separated and recovered, and ammonia water is also regenerated. In other words, the waste heat of the flue-gas of the stack is produced by the low-pressure steam and then supplied to the reboiler provided in the stripping column, by the low-pressure steam supplied to the separation and recovery of carbon dioxide and the regeneration of ammonia water. Carbon dioxide separated through this process is discharged to the top of the stripping tower.

The heated regenerated absorbent may be cooled by passing through the heat exchanger and ammonia water absorbing carbon dioxide transferred from the absorption tower, and then injected into the absorption tower to continuously absorb and separate carbon dioxide.

The exhaust gas containing carbon dioxide in step (a) may include the exhaust gas discharged from various industrial processes, such as power plants or submission stations. The ammonia water may be used 1 to 15% by weight of ammonia water.

As described above, the ammonia water of step (a) may be supplied to the top of the absorption tower, the exhaust gas may be supplied to the bottom of the absorption tower.

In addition, the waste heat of the stack flue gas of step (c) is supplied by producing a low pressure steam, the present invention can recover the waste heat from the stack flue gas can supply heat having a low pressure steam of 110 to 120 ℃. At this time, the flue flue gas may include recovering this waste heat because the temperature of the flue gas discharged from the flue of the final process is high. It may also include those recovered from sources of separate power plants or steel mills. Therefore, the waste heat of the flue flue gas is generated by supplying a low pressure steam from the recovery device of the flue flue gas using a heat pipe.

In the present invention, carbon dioxide may be separated and recovered by distillation through heating at 80 to 96 ° C. when the waste heat of the flue gas is used. That is, after producing steam using the recovered waste heat (heat pipe method), it is supplied to the reboiler (heater) to heat the ammonia water. The carbon dioxide absorbed in the ammonia water is removed from the ammonia water by this heating. At this time, the temperature is about 80 to 96 ° C depending on the ammonia water concentration.

The carbon dioxide separated in step (c) may be discharged into the atmosphere through an outlet installed separately in the stripping tower.

In this invention, the structure of an absorption tower and a stripping tower is not specifically limited, Any device used for the ammonia absorption process used for normal carbon dioxide recovery can be used. In addition, they may be connected through a transfer line, and the configuration is not particularly limited, provided that only pipes capable of providing low pressure steam of the waste heat of the flue flue gas are installed.

The carbon dioxide recovered by the method of the present invention may have a concentration of 95% or more.

Figure 1 shows a simplified process of the recovery of carbon dioxide according to an embodiment of the present invention.

The present invention recovers heat from the exhaust gas by using a heat pipe from the exhaust gas discharge source of various industrial sites to produce a low pressure steam, and supplies it to the ammonia water absorption process. In this case, although not shown in the drawing, the ammonia water absorption process may include the configuration of an absorption tower having an inlet for supplying ammonia water and an inlet for exhaust gas containing carbon dioxide and a stripping column for distilling off carbon dioxide. After the ammonia water absorption process, the remaining exhaust gas from which carbon dioxide is removed is discharged through the stack. The exhaust gas discharged through the stack may be recovered before being discharged to the atmosphere, which may be recovered through the heat pipe and then applied to ammonia water regeneration.

In the method for recovering carbon dioxide of the present invention, carbon dioxide contained in combustion flue gas or blast furnace flue gas is absorbed into ammonia water and then supplied using waste heat without separately producing energy for regeneration of the ammonia water, thereby greatly increasing the cost of renewable energy of ammonia water. The savings can also greatly reduce the cost of CO2 recovery.

Hereinafter, the present invention will be described in more detail with reference to the following examples. These examples are only for illustrating the present invention, of course, the scope of the present invention is not limited to the following examples.

Example

Ammonia water at a concentration of 2% by weight was continuously supplied to the upper part of the absorption tower consisting of a total of 10 stages, and carbon dioxide-containing exhaust gas supplied from a power plant or waste gas was supplied to the lower part of the absorption tower. The carbon dioxide-containing exhaust gas contained 12% carbon dioxide. The supply rate of ammonia water was 200 cc / min. Thereafter, the ammonia water absorbed by the ammonia water in the absorption tower was transferred to the stripping column, and the ammonia water was heated and regenerated at 96 ° C.

In this case, the removal rate of carbon dioxide in the absorption tower was 94% and the concentration of carbon dioxide in the upper part of the stripping column was 95%.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

Figure 1 shows a conventional carbon dioxide recovery process.

Figure 2 shows a carbon dioxide recovery process diagram of the present invention.

Claims (8)

(a) supplying a flue gas containing carbon dioxide to an absorption tower supplied with 1 to 2% by weight of ammonia water to absorb carbon dioxide contained in the flue gas with ammonia water, (b) transferring the ammonia water absorbed by the carbon dioxide to a stripping column, (c) separating and recovering carbon dioxide from the ammonia water absorbed by the carbon dioxide using waste heat of the flue flue gas, and regenerating the ammonia water, Waste heat of the stack flue gas of step (c) is a carbon dioxide recovery method for supplying heat of low pressure steam of 110 to 120 ℃. delete The method of claim 1, wherein the waste heat of the flue flue gas of step (c) comprises the waste heat recovered from the flue flue gas discharged from the flue of the power plant or steel mill or the flue flue gas in the final process. The method of claim 3, wherein the flue flue gas is recovered from a flue gas discharge source through a heat pipe. The method of claim 1, wherein the carbon dioxide in step (c) is separated by distillation by heating at 80 to 96 ℃. delete The method of claim 1, wherein the ammonia water of step (a) is supplied to the upper portion of the absorption tower, the exhaust gas is supplied to the lower portion of the absorption tower, carbon dioxide separation and recovery method. The method of claim 1, wherein the carbon dioxide recovered in the step (c) has a concentration of 95% or more.

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