KR102189717B1 - Gas capturing apparatus composed of absorption column and stripping column in a single column and gas capturing method using the same - Google Patents

Abstract

The present invention relates to a gas collection device in which an absorption tower and a stripping tower are formed as one tower, and a gas collection method using the same. The gas collection device according to the present invention operates the absorption process with only one tower including an absorption tower and a stripping tower, and one circulation pump, so that the circulation flow rate of the absorbent can be maintained very stably. Drive is possible. In addition, since there is no need to control the flow rate by a separate level control system, the manufacturing cost of equipment can be drastically reduced. In particular, based on these effects, it can be usefully used in test equipment and operation for developing absorbents.

Description

Gas capturing apparatus composed of absorption column and stripping column in a single column and gas capturing method using the same}

The technical field of the present invention relates to absorption and separation of gases generally used in chemical processes, and more particularly, to a gas collection apparatus composed of a single tower and a gas collection method using the same.

Absorption method in which the gas component contained in the mixed gas is absorbed into an absorption solution and removed or separated by removing it is a very commonly used method in chemical processes. Typical chemical processes using the absorption method include'the process of producing sulfuric acid by absorbing SO ₃ in water','the process of separating acetylene from the high-temperature pyrolysis gas using dimethylformamide','CO ₂ and CO ₂ using an ammonium carbonate In addition to manufacturing processes such as the process of absorbing NH ₃ and producing Urea,'the process of separating/removing CO ₂ by absorbing CO ₂ in an aqueous amine solution', and'the process of removing SO ₂ using a Lime/limestone aqueous solution' It is commonly used in gas purification processes (Non-Patent Document 1).

In particular, the absorption method is commonly used as a method of removing or separating carbon dioxide (CO ₂ ) or sulfur dioxide (SO ₂ ) from the combustion exhaust gas of power plants using fossil fuels or mixed gas obtained in the steel and cement production process. Process improvement for energy efficiency is also being made by developing solutions. Typically, an amine-based aqueous solution such as monoethanolamine is used as the carbon dioxide absorption solution. Due to the high thermal and chemical stability of the carbamate produced from the reaction with carbon dioxide, monoethanolamine consumes excessive renewable energy as its decomposition temperature is higher than 120 ℃, and excessive volatilization loss of amine due to high regeneration temperature, etc. This is pointed out as a disadvantage.

In order to compensate for the shortcomings of the amine-based aqueous absorbent, attempts have been made to use various amine mixtures, an alkanolamine aqueous solution having a steric hindrance around the amine group of the alkanolamine, and a non-aqueous amine solution as an absorbent. U.S. Patent No. 6,849,774 (Patent Document 1), U.S. Patent No. 6,623,659 (Patent Document 2), and U.S. Patent Publication No. 2008-0146849 (Patent Document 3) have no volatility, high thermal stability, and low temperatures of 100 ℃ or less. Research has been actively conducted to lower the energy required for CO ₂ separation as a whole by using an ionic liquid that maintains a liquid phase at temperature as a non-aqueous absorbent.

On the other hand, SO ₂ contained in gas discharged from thermal power plants is currently mostly treated with CaCO ₃ /CaO, etc. and separated into Gypsum form. However, in the case of the solid absorbent, not only the tube clogging phenomenon occurs, but also the SO ₂ absorption rate is relatively slow compared to that of the liquid absorbent, and heat exchange between the components is difficult, so relatively much heat is required for regeneration of the absorbent. In addition, the gypsum generated after absorption is partially utilized, but a large amount is sometimes discarded. Recently, SO ₂ is separated/recovered by an absorption process to be utilized. Representatively, Cansolv has developed a diamine-based SO ₂ recovery system and introduced it into power plants/smelters, and 9 units are currently in operation worldwide. In 2016, Canada's Sask Dam Project developed a system combined with a CO ₂ capture process, and the amount of SO ₂ recovered from it is estimated to reach 5,000 tons per year.

In order to develop an absorbent or absorbent solution for CO ₂ or SO ₂ as described above, not only the absorption capacity of the absorbent, but also energy consumption, chemical stability, etc. must be excellent, and it is necessary to establish optimal operating conditions for realizing such performance. In other words, in order to be applied to a commercial factory, its economical efficiency and efficacy must be proved through a long-term performance test in a facility equipped with a pilot test or the like, that is, a facility equipped with an entire absorption/detaching process, but a high-cost facility is required for such a pilot experiment.

In addition, according to the existing absorption / stripping process, two towers for absorption and stripping, two pumps for circulating the absorbent and stripped absorbent, condensers and reboiler of the stripping tower, and a heat exchanger are essential. In the above process, the two pumps, which are driving devices, must stably and consistently supply the absorbent of the two towers (absorption tower and stripping tower) and maintain the liquid level of both bottom tanks within a certain range. For this, there is a problem in that two pumps are used as metering pumps or a system for controlling the flow rate must be additionally provided. In addition, since the liquid level of both top and bottom tanks must be continuously measured and linked with the flow control of the pump, a level control system must be attached to each pump. However, the flow rate control is continuously destabilized by the liquid level control system, causing a problem in that the liquid flow rate in the tower changes.

US Patent No. 6,849,774 US Patent No. 6,623,659 US Patent Publication No. 2008-0146849

Handbook of Separation Process Technology, Ronald W. Rousseau, 1987, Hohn Wiley & Sons, Inc. Jaeheum Jung, et. al., “New Configuration of the CO2 Capture Process Using Aqueous Monoethanolamine for Coal-Fired Power Pants”, Ind. Eng. Chem. Res. 2015, 54, 3865-3878

In order to solve the problems and limitations of the conventional gas collecting (absorption and stripping) device described above, as a result of trying to develop a gas collecting device that is capable of stable long-term operation, has a simple configuration and is easy to install, to complete the present invention. Arrived.

The present invention has been conceived in view of the above problems, and an object of the present invention is to provide a gas collection apparatus comprising a single tower connected to an absorption tower and a stripping tower, and a gas collection method using the same.

One aspect of the present invention for achieving the above object is a gas collection device composed of a single tower in which an absorption tower and a stripping tower are connected up and down, and the absorption target gas is absorbed by absorbing the target gas contained in the mixed gas using an absorbent. An absorption tower for producing an absorbent; A stripping tower positioned at a lower end of the absorption tower, supplied with an absorbent through a pipe connected to the absorption tower, and regenerating the absorbent absorbing the collection target gas; And a circulation pump for recirculating the recycled absorbent to the absorption tower.

Another aspect of the present invention is a method of collecting gas by a gas collection device consisting of a single tower in which an absorption tower and a stripping tower are connected up and down, in which the absorption target gas contained in the mixed gas is absorbed by using an absorbent in the absorption tower. Generating an absorbent by absorbing the gas to be collected; Supplying an absorbent that has absorbed the gas to be collected to a stripping tower located at a lower end of the absorption tower through a pipe connected to the absorption tower; Regenerating an absorbent that has absorbed the gas to be collected in the stripping tower; And recycling the regenerated absorbent to the absorption tower by a circulation pump.

The gas collection device according to the present invention operates the absorption process with only one tower including an absorption tower and a stripping tower, and one circulation pump, so that the circulation flow rate of the absorbent can be maintained very stably. Drive is possible.

In addition, since there is no need to control the flow rate by a separate level control system, the manufacturing cost of equipment can be drastically reduced. In particular, based on these effects, it can be usefully used in test equipment and operation for developing absorbents.

1 is a process diagram of a conventional gas collecting device.
2 is a flow chart of a gas collecting device according to an embodiment of the present invention.
3 is a configuration diagram of a gas collection apparatus experimental facility according to an embodiment of the present invention.

Hereinafter, various aspects and various embodiments of the present invention will be described in more detail.

One aspect of the present invention is a gas collection device composed of a single tower connected to the absorption tower 201 and the stripping tower 202, and absorbs the target gas contained in the mixed gas 101 by using an absorbent. Absorption tower 201 for generating an absorbent absorbing the; A stripping tower (202) located at the bottom of the absorption tower (201), supplied through a pipe connected to the absorption tower (201), the absorbent absorbing the gas to be collected, and regenerating the absorbent from absorbing the gas to be collected (202) ; And a circulation pump 203 for recirculating the regenerated absorbent to the absorption tower 201.

The configuration of the existing absorption/detaching facility is as shown in FIG. 1, and a more detailed look at the operation method and problems are as follows. The mixed gas 101 (Solute-rich Feed Gas) in which the gas components to be removed or collected are mixed is supplied to the absorption tower 201 for absorption and the remaining gas 102 (Treated Gas) is transferred to the top of the absorption tower 201. Discharge. The absorbent is supplied to the upper part of the absorption tower 201 and comes into contact with the mixed gas 101 introduced from the lower part, and then collected in the lower part. The absorbent 104 (Rich Solvent) collected under the absorption tower 201 is pressurized by a pump 203 and supplied to the upper portion of the stripping tower 202. In the stripping tower 202, the collected gas 103 (Solute Gas) absorbed by receiving heat from the reboiler 207 attached to the lower part is removed and discharged, and the absorbent is collected downward. The regenerated absorbent 104 (Lean Solvent) collected under the stripping tower 202 is pressurized again by a pump 203 and circulated to the absorption tower 201. A heat exchanger 204 for recovering heat from the absorbent, a cooler 205 for cooling the regenerated absorbent 104 (Lean Solvent), and a condenser for condensing the absorbent and cooling the collected gas 103 (Solute Gas) ( 206), etc., are added as auxiliary equipment to operate the entire process. That is, absorption and removal are repeated using an absorbent, and a certain component is absorbed/removed from the mixed gas 101 to separate or collect. According to the typical above process, two towers for absorption and stripping, two pumps 203 for circulating the absorbent and stripped absorbent 104, condensers 206 and reboiler of stripping tower 202 207 and heat exchanger 204 can be said to be essential.

The biggest problem in this process is the two pumps 203 which are driving devices. The absorbent of the two towers (absorption tower 201 and stripping tower 202) must be supplied stably and uniformly, and the liquid level of both bottom tanks must be maintained within a certain range. To this end, two pumps 203 should be used as metering pumps or a system for controlling the flow rate should be provided. In addition, since the liquid level of both top and bottom tanks should be continuously measured and linked with the flow control of the pump 203, a flow control system and a liquid level control system must be attached to each of the pumps 203. However, the flow rate control is continuously destabilized by the liquid level control system, causing a problem in that the liquid flow rate in the tower changes.

In order to solve this problem, the present inventors constructed a single tower in which the absorption tower 201 and the stripping tower 202 are connected in series, and a new gas collection device and operation method using only one liquid circulation pump 203 Was derived. The gas collecting device of the present invention controls the flow rate required for absorption and stripping operation with only one circulation pump 203, so that the flow rate is kept constant and stable, so that the flow rate of the absorbent flowing in the tower can be kept constant and stably. In addition, there is no need to have a separate flow control system and level control system, so there is an advantage that the configuration is simple and stable operation is possible. In addition, since the configuration is simplified, installation is easy and installation cost is reduced, it can be used in small-scale test facilities, that is, pilot facilities or applied facilities for developing absorbents.

A configuration diagram of a gas collecting device according to an embodiment of the present invention is shown in FIG. 2. According to the specific example shown in FIG. 2, it is composed of one tower including an absorption tower 201 and a stripping tower 202, a circulation pump 203, an auxiliary heat exchanger 204, and the like.

A more detailed look at the configuration and operation method of the gas collection device according to the above embodiment is as follows. The mixed gas 101 (Solute-rich Feed Gas) in which the gas component to be collected is mixed is supplied to the lower part of the absorption tower 201 located at the top of the tower for absorption, and the remaining gas 102 (Treated Gas) is supplied to the upper part of the tower. To discharge. After the absorbent is supplied to the upper portion of the absorption tower 201 and comes into contact with the introduced mixed gas 101, the absorbent gas is collected under the absorption tower 201 in a saturated state. The absorbent 104 (Rich Solvent) which absorbs the gas to be collected collected under the absorption tower 201 is freely dropped due to the difference in liquid height and is introduced into the upper part of the stripping tower 202. In the stripping tower 202, the collected gas 103 (Solute Gas) removed by receiving heat from the reboiler 207 attached to the lower part is discharged to the upper part of the stripping tower 202 (the middle part of the entire tower). The absorbent is collected at the bottom of the tower. The recycled absorbent 104 (Lean Solvent) collected in the lower part of the tower is pressurized by the circulation pump 203 and circulated to the upper part of the tower. That is, the absorption and stripping process may be completed with one tower and one pump 203 in which the absorption tower 201 and the stripping tower 202 are connected vertically. Since the circulating flow rate of the absorbent is regulated by the pump 203 circulated in the stripping tower 202, the flow rate of the absorbent injected from the absorption tower 201 to the stripping tower 202 is the absorption and stripping process without separate flow control. The basic operating conditions can be provided perfectly.

According to one embodiment, the gas collecting device may further include a reboiler 207 connected to the stripping tower and supplying a heat source required for regeneration of an absorbent that has absorbed the gas to be collected.

According to another embodiment, it may further include a pressure regulating device positioned in the pipe to equally adjust the operating pressure of the absorption tower 201 and the operating pressure of the stripping tower 202. When the operating pressure condition of the absorption tower 201 is different from the operating pressure condition of the stripping tower 202, an absorbent that has absorbed the gas to be collected collected under the absorption tower 201 is added to the stripping tower 202. It falls freely and cannot be put in. When the operating pressure condition of the absorption tower 201 is higher than the operating pressure of the stripping tower 202, an absorbent may be supplied to the stripping tower 202 after adjusting the pressure by installing a control valve in the pipe. Conversely, when the operating pressure of the absorption tower 201 is lower than that of the stripping tower 202, a pump capable of pressurizing may be required. Even when the control valve or the pump is added, the effect of the present invention of configuring the absorption tower and the stripping tower into one tower is obvious. In addition, if the configuration of the present invention is applied, the circulating flow rate of the absorbent liquid is controlled by only one pump circulating in the stripping tower, so if the flow rate of the absorbent liquid introduced from the absorption tower to the stripping tower is the same as the flow rate of the pump circulating in the stripping tower, absorption The bottom level of the tower and stripping tower is also automatically maintained, allowing stable operation. That is, because the operating pressures of the absorption tower and the stripping tower are different, when the absorption liquid is injected from the absorption tower to the stripping tower, even when a control valve or a pump is used, one tower can be used and the instrumentation system can be reduced. It is self-evident.

According to another embodiment, a heat exchanger 204 located between the absorption tower 201 and the stripping tower 202 may further include a heat exchanger 204 for recovering heat of an absorbent absorbing the supplied gas to be collected. .

According to another embodiment, a cooler 205 for cooling the absorbent recirculated by the circulation pump 203 may be further included. The absorbent material recovered by removing the gas to be collected through the cooler 205 is cooled to the level of the absorption tower 201 and recycled.

According to another embodiment, a condenser 206 for condensing the gas to be collected separated by regeneration of the absorbent that has absorbed the gas to be collected in the stripping tower 202 may be further included.

According to another embodiment, the absorbent may be one or more selected from amine-based, amino acid salt, inorganic salt-based solution, aqueous ammonia or metal ion salt solution, and the gas to be collected is carbon dioxide, sulfur dioxide, nitrogen dioxide, hydrogen sulfide, or sulfurized It may be one or more selected from carbonyls, but is not limited thereto. The gas collecting device and the gas collecting method of the present invention may be applied without being limited to the type of gas, and the absorbent may also be appropriately selected according to the type of the gas to be collected.

Another aspect of the present invention is a method of collecting gas by a gas collection device consisting of a single tower in which the absorption tower 201 and the stripping tower 202 are connected up and down, in which the absorption tower 201 is mixed using an absorbent. Generating an absorbent that absorbs the gas to be collected by absorbing the gas to be collected contained in the gas 101; Supplying an absorbent that has absorbed the gas to be collected to a stripping tower 202 located at the lower end of the absorption tower 201 through a pipe connected to the absorption tower 201; Regenerating an absorbent that has absorbed the gas to be collected in the stripping tower (202); And recirculating the regenerated absorbent to the absorption tower 201 by a circulation pump 203. It provides a gas collection method comprising a.

Hereinafter, a preferred embodiment is presented to aid the understanding of the present invention. However, these examples are for describing the present invention in more detail, and the scope of the present invention is not limited thereto, and various changes and modifications are possible within the scope and spirit of the present invention. It will be self-evident to those who have knowledge.

Example 1.

Construction and installation of experimental equipment for gas collection device

For the implementation of the present invention, an experimental facility of a gas collection device in which the actual process was reduced was installed, and the configuration diagram is shown in FIG. 3.

The absorption tower 201 at the top of the tower and the stripping tower 202 at the bottom of the tower were filled with a 1/4 inch raschig ring in a 2 inch diameter glass column, and the filling height was 50 cm and 45 cm, respectively. I made it possible. Condensers 206 were installed above the absorption tower 201 and above the stripping tower 202, respectively, and brine was supplied at 20°C. A reboiler 207 having a diameter of 15 cm and a height of 40 cm made of glass was installed under the stripping tower 202 and the outer wall was heated with an electric heater. A circulation pump 203 was installed to recirculate the absorption solution, and before being supplied to the top of the tower, the 20°C brine was supplied through the cooler 205. The electric heater of the reboiler 207 was controlled so that the temperature in the reboiler 207 was maintained at a set temperature by using a temperature indicator (TIC). In FIG. 3, PG and FI denote a pressure gauge and a flow meter, respectively, and TI denotes a temperature sensor for measuring temperatures in several places.

How to operate the gas collection device experiment facility

The prepared absorbent is filled in about 5L in the reboil 207. The temperature is maintained by circulating brine of an appropriate temperature (20°C) in the condenser 206 and the cooler 205. The mixed gas 101 (Feed Gas) is injected into the lower portion of the absorption tower 201. The remaining gas 102 (Treated Gas) passing through the absorption tower 201 filling layer is cooled and condensed through a condenser 206 installed thereon, and then discharged to the outside.

The absorption solution stored in the reboiler 207 is injected into the upper portion of the absorption tower 201 at an appropriate flow rate using the circulation pump 203. The absorption solution is in countercurrent contact with the mixed gas 101 supplied from the lower portion of the absorption tower 201 and absorbs/removes a component to be separated (Solute). The absorbent 104 (Rich Solvent) absorbing the collected gas (Solute) is temporarily collected under the absorption tower 201 and then freely fallen to be introduced into the upper part of the stripping tower 202. The absorbent 104 (Rich Solvent) is in contact with the heated gas coming up from the reboiler 207 while passing through the packed bed of the stripping tower 202 to remove the absorbed components. The removed collected gas 103 (solute gas containing some moisture) is cooled and condensed by passing through a condenser 206 installed on the stripping tower 202, and then discharged to the outside. The removed absorbent 104 (Lean Solvent) is circulated through the circulation pump 203 again. The concentration of the solute to be collected of the input mixed gas 101 and the discharged mixed gas 101 is measured, and a sample of the recycled absorbent 104 (Lean Solvent) is intermittently taken to obtain a collection target component (solute). Measure the concentration of.

Example 2.

The gas to be collected was collected using the experimental equipment prepared in Example 1. Using water as the absorbent absorbs the SO ₂ in the gas mixture 101 that includes SO ₂ - was stripped. 5 L of distilled water was charged into the reboiler 207, and the absorbent (water) was circulated at a flow rate of 2.5 L/hr using the circulation pump 203. A mixed gas 101 mixed with nitrogen gas to have 100 ppm of SO ₂ was added to the lower end of the absorption tower 201 at a flow rate of 500 L/hr. 20 ℃ brine was supplied to the condenser 206 and the cooler 205, and the temperature of the reboiler 207 was heated to maintain 85°C. The average concentration of SO ₂ in the mixed gas 101 to be introduced was 105.1 ppm. Experimental results As can be seen in Table 1 below, the average concentration of SO ₂ in the remaining gas 102 was 71.1 ppm and the SO ₂ absorption (removal) rate was 32.3%. As the SO ₂ meter, a 43i-HL model manufactured by Thermo Scientific was used.

As can be seen in Table 1 below, the experimental facility was able to operate very stably for 28 hours or more. In particular, even after stopping and restarting the operation several times, it was confirmed that the level of the reboiler 207 was automatically maintained constant within 5 minutes after the pump was driven, and the towers (absorption tower 201 and stripping tower 202) were operated stably. I did. The operating time is the total operating time of the actual absorption-and-stripping experiment excluding the interruption time.

Driving time
(hr) Raw material mixture gas
SO ₂ concentration
(ppm) In the absorption tower
Absorption solution
Temperature(℃) Rebuild
Temperature(℃) Rest gas
SO ₂ concentration
(ppm) Absorption rate
(%) 15.3 103.1 22.5 85.0 70.5 31.6 22.2 107.1 22.5 85.0 69.8 34.8 28.2 105.2 23.1 85.0 73.0 30.6

Example 3.

The SO ₂ concentration of the raw material mixture gas 101 was 1000 ppm, and water was used as an absorbent, and absorption-degreasing experiments were conducted in the same manner as in Example 2 above. The experiment was conducted until the concentration of the remaining gas 102 was kept constant, and after 8 hours as shown in the following table as a result of the experiment, the absorption rate was maintained at about 24%. As can be seen in Table 2 below, the towers (absorption tower 201 and stripping tower 202) were operated very stably. In particular, even if the flow rate of the circulation pump 203 was changed within the range of 1.8 to 3.1 L/hr during operation, the liquid level of the reboiler 207 was automatically maintained constant within 5 minutes.

Driving time
(hr) Raw material mixture gas
SO2 concentration
(ppm) In the absorption tower
Absorption solution
Temperature(℃) Rebuild
Temperature(℃) Rest gas
SO ₂ concentration
(ppm) Absorption rate
(%) 6.7 1000 22.5 85.0 804 19.6 8.7 1022 22.2 85.0 774 24.3 14.8 1029 22.5 85.0 786 23.6

Example 4.

Hydorxylethyl dimethylpiperazinium chloride ([HEDMP]Cl) was prepared and used as an absorbent, and the concentration of SO _{2 in the} raw material mixture gas 101 was fixed to 1000 ppm, and absorption-degreasing experiments were conducted with the same apparatus and operation method as in Example 2. I did.

As can be seen in Table 3 below, it was possible to operate the absorption / stripping facility very stably for 100 hours or more. In addition, by using the experimental apparatus embodying the present invention, the performance of the absorbent was stably confirmed for a long period of time, and the change in the absorption rate, the change in the concentration of the absorption solution, and the denaturation were confirmed. In the table, the'SO ₂ concentration of the lean solvent' is a value obtained by taking a sample from the absorption solution circulated by the pump 203 and analyzing it by NMR (Nuclear magnetic resonance). The NMR peak was shifted according to the amount of SO ₂ dissolved in the absorbent ([HEDMP]Cl), and the concentration of SO ₂ was quantified therefrom. It is expressed as the number of moles of SO ₂ dissolved per mole of absorbent.

driving
time
(hr) Raw material mixture gas
SO2 concentration
(ppm) In the absorption tower
Absorption solution
Temperature(℃) Rebuild
Temperature(℃) Lean
solvent
SO ₂ concentration
(mol/mol) Rest gas
SO ₂ concentration
(ppm) Absorption rate
(%) 7.25 962.5 18.7 99.8 0.05 12.3 98.7 16.58 977.5 18.3 99.9 0.13 42.5 95.7 25.83 990.0 18.3 100.0 0.23 69.5 93.0 35.75 977.5 18.4 100.0 0.34 74.2 92.4 45.00 987.5 17.9 100.2 0.42 103.1 89.6 52.67 1007.5 18.2 100.0 0.49 163.8 83.7 62.10 990.0 17.0 100.1 0.54 189.2 80.9 73.17 987.5 17.1 100.0 0.68 232.0 76.5 84.50 995.0 17.0 100.4 0.75 319.0 67.9 95.50 990.0 17.2 100.3 0.83 416.6 57.9 103.83 995.0 17.4 100.3 0.80 378.6 61.9

Therefore, through the above embodiments, it was confirmed that the gas collection device and the gas collection method of the present invention can operate the gas collection device stably and conveniently only with a simple facility including one tower and one pump connected to the absorption tower and the stripping tower. I did. In addition, it was confirmed that it is suitable for manufacturing and experimenting with a small-scale test facility for developing absorbents because it is easy to install with a simplified configuration and reduces installation cost.

The above-described Examples and Comparative Examples are examples for explaining the present invention, and the present invention is not limited thereto. Since those of ordinary skill in the art to which the present invention pertains will be able to implement the present invention by various modifications therefrom, the technical protection scope of the present invention should be determined by the appended claims.

101: mixed gas
102: remaining gas
103: trapping gas
104: absorbent/regenerated absorbent
201: absorption tower
202: stripping tower
203: circulation pump
204: heat exchanger
205: cooler
206: condenser
207: Repitch

Claims (10)

As a gas collection device consisting of a single tower in which the absorption tower and the stripping tower are connected vertically,
An absorption tower for generating an absorbent that absorbs the gas to be collected by absorbing the gas to be collected contained in the mixed gas using an absorber;
Located at the lower end of the absorption tower, an absorbent absorbing the collection target gas is supplied through a pipe connected to the absorption tower, and removes the collection target gas from the absorbent absorbing the collection target gas, and the collection target gas is A stripping tower for regenerating the stripped absorbent;
A reboiler connected to the stripping tower and supplying a heat source necessary for regeneration of the absorbent absorbing the gas to be collected to the stripping tower;
A pressure regulating device positioned in the pipe and adjusting the operating pressure of the absorption tower and the operating pressure of the stripping tower equally or differently; And
And a circulation pump for recirculating the recycled absorbent to the absorption tower. The method of claim 1,
The pressure regulating device is a gas collecting device for differently controlling the operating pressure of the absorption tower and the operating pressure of the stripping tower. The method of claim 1,
A gas collecting device further comprising a heat exchanger positioned between the absorption tower and the stripping tower and recovering heat of the absorbent that has absorbed the supplied gas to be collected. The method of claim 1,
A gas collecting device further comprising a cooler for cooling the absorbent recycled by the circulation pump. The method of claim 1,
A gas collecting device further comprising a condenser for condensing the gas to be collected separated by regeneration of an absorbent that has absorbed the gas to be collected in the stripping tower. In the method of absorbing, removing, and separating the gas to be collected by a gas collection device consisting of a single tower in which the absorption tower and the stripping tower selected from among claims 1 to 5 are connected vertically,
Generating an absorbent that absorbs the gas to be collected by absorbing the gas to be collected contained in the mixed gas using an absorber in the absorption tower;
Supplying an absorbent that has absorbed the gas to be collected to a stripping tower located at a lower end of the absorption tower through a pipe connected to the absorption tower;
Removing and discharging the absorbed gas to be collected from the absorbent absorbing the gas to be collected in the stripping tower, and regenerating the removed absorbent; And
Recirculating the regenerated absorbent to the absorption tower by a circulation pump; Including,
The step of regenerating the removed absorbent is performed by a heat source supplied by a reboiler. The method of claim 6,
The gas collection method is a gas collection method that recovers only the removed gas to be collected. The method of claim 6,
And recovering heat of the absorbent that has absorbed the supplied gas to be collected by a heat exchanger positioned between the absorption tower and the stripping tower. The method of claim 6,
And cooling the absorbent recirculated by the circulation pump by a cooler. The method of claim 6,
And condensing the gas to be collected separated by regeneration of an absorbent that has absorbed the gas to be collected in the stripping tower by a condenser.

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