JP2013022577A - Method and apparatus for recovering carbon dioxide - Google Patents

Abstract

PROBLEM TO BE SOLVED: To more efficiently recover carbon dioxide by using a compound oxide of lithium as a carbon dioxide absorbent.SOLUTION: In a step S103, amount of carbon dioxide absorbed by the absorbent arranged in an exhaust gas discharge route is measured (third step). Then in a step S104, it is determined whether an absorption rate of the absorbent which is obtained using measured absorption amount, measured exhaust gas temperature, measured carbon dioxide concentration in the exhaust gas and an absorbent characteristic, is lowered than a target absorption rate or not. When the lowering is determined (detected) (Y of step S104), the absorbent arranged in the exhaust gas discharge route is replaced in a step S 105 (fourth step).

Description

  The present invention relates to a carbon dioxide recovery method and apparatus for efficiently recovering carbon dioxide from exhaust gas containing carbon dioxide and exhausted.

  For example, a large amount of carbon dioxide is contained in exhaust gas from thermal power plants and gasoline engines. Reduction of emissions of carbon dioxide is an issue as one of the greenhouse gases that cause global warming. As a method for reducing the discharge amount of carbon dioxide into the atmosphere, there is a method for separating and collecting carbon dioxide from the exhaust gas as described above. For example, a technique has been proposed in which lithium silicate is used as an absorbent that absorbs carbon dioxide, and carbon dioxide is absorbed from exhaust gas from a boiler (see Patent Document 1).

  In the recovery of carbon dioxide using the lithium composite oxide typified by the lithium silicate described above, first, the lithium composite oxide is heated to a carbon dioxide absorption temperature (for example, 500 to 700 ° C.) to absorb the carbon dioxide. After carbon dioxide is absorbed in this manner, the lithium composite oxide is heated to a higher release temperature (for example, 700 to 850 ° C.) to release carbon dioxide from the lithium composite oxide. Carbon dioxide can be recovered by releasing carbon dioxide at a location different from the region where the exhaust gas is released.

Japanese Patent Laying-Open No. 2005-075683

  However, in the recovery of carbon dioxide using the above-described absorbent material, temperature control is performed in accordance with the characteristics of the absorbent material, but this condition is not always the optimum condition when considering the efficiency, There is a problem that efficient recovery of carbon dioxide is not considered.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to use a lithium composite oxide as a carbon dioxide absorbent so that carbon dioxide can be recovered more efficiently. .

  The carbon dioxide recovery method according to the present invention absorbs the relationship between the heating temperature, the amount of absorbed carbon dioxide, and the absorption rate of carbon dioxide with respect to the carbon dioxide concentration in the atmosphere in the absorbent material made of lithium composite oxide. A first step for determining the material characteristics; and a second step of determining a desired target absorption rate by measuring the temperature, carbon dioxide concentration, and flow rate of the exhaust gas discharged to the exhaust gas discharge path through which the exhaust gas containing carbon dioxide is discharged. A step, a third step of measuring the amount of carbon dioxide absorbed by the absorbent disposed in the exhaust gas discharge path, the measured amount of absorption, the measured temperature of the exhaust gas, the measured concentration of carbon dioxide in the exhaust gas , And the absorption material disposed in the exhaust gas discharge path, detecting that the absorption rate of the absorption material required by the absorption material characteristics has fallen below the target absorption rate And a fourth step of exchanging.

  In the carbon dioxide recovery method, in the fourth step, carbon dioxide may be replaced with an unabsorbed absorbent material.

  The carbon dioxide recovery device according to the present invention is heated in an exhaust gas discharge path through which exhaust gas containing carbon dioxide is transported, an absorbent material made of lithium composite oxide disposed in the exhaust gas discharge path, and the absorbent material. A first storage portion storing the temperature, the amount of absorbed carbon dioxide, and the absorbent characteristics indicating the relationship of the carbon dioxide absorption rate to the carbon dioxide concentration of the atmosphere; and the temperature of the exhaust gas, the carbon dioxide concentration, and A second storage unit storing a desired target absorption rate determined from the flow rate, an absorption amount measuring means for measuring the amount of carbon dioxide absorbed by the absorbent, and the temperature of exhaust gas transported through the exhaust gas discharge path And exhaust gas state measuring means for measuring the carbon dioxide concentration in the exhaust gas, the amount of absorption measured by the absorption amount measuring means, the temperature of the exhaust gas measured by the exhaust gas state measuring means, the exhaust gas The absorption rate calculation means for obtaining the absorption rate of the absorbent material based on the carbon dioxide concentration therein and the absorbent material characteristics stored in the first storage unit, and the absorption rate calculated by the absorption rate calculation unit are stored in the second storage unit. And a replacement time notification means for detecting that the absorption rate is lower than the target absorption speed and notifying that the absorbent disposed in the exhaust gas discharge path is the replacement time.

  The carbon dioxide recovery device may be provided with an absorbent replacement unit that replaces the absorbent disposed in the exhaust gas discharge path upon receiving notification of replacement of the absorbent by the replacement time notification unit. The absorbent material replacement means may be replaced with an absorbent material that has not absorbed carbon dioxide.

  As described above, according to the present invention, when the absorption rate of the absorbent determined by the measured absorption amount, the measured exhaust gas temperature, and the characteristics of the absorbent is lower than the target absorption rate, the absorbent is replaced. Therefore, the lithium composite oxide is used as a carbon dioxide absorbent, and an excellent effect is obtained that carbon dioxide can be recovered more efficiently.

FIG. 1 is a flowchart for explaining a carbon dioxide recovery method according to an embodiment of the present invention. FIG. 2 is a characteristic diagram showing the change in the carbon dioxide absorption rate of the lithium silicate with respect to the amount of carbon dioxide absorbed by the lithium silicate at each exhaust gas temperature when the carbon dioxide concentration of the exhaust gas is 10%. is there. FIG. 3 is a characteristic diagram showing changes in the carbon dioxide absorption rate of the lithium silicate with respect to the amount of carbon dioxide absorbed by the lithium silicate for each exhaust gas temperature when the carbon dioxide concentration of the exhaust gas is 20%. is there. FIG. 4 is a configuration diagram showing the configuration of the carbon dioxide recovery device in the embodiment of the present invention. FIG. 5 is a flowchart for explaining another carbon dioxide recovery method in the embodiment of the present invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a flowchart for explaining a carbon dioxide recovery method according to an embodiment of the present invention.

  First, in Step S101, the relationship between the heating temperature, the amount of absorbed carbon dioxide, and the absorption rate of carbon dioxide with respect to the carbon dioxide concentration in the atmosphere is obtained as the absorbent characteristic in the absorbent material made of lithium composite oxide. (First step).

  Next, in step S102, the desired absorption speed is determined by measuring the temperature, carbon dioxide concentration, and flow rate of the exhaust gas discharged to the exhaust gas discharge path through which the exhaust gas containing carbon dioxide is discharged (second step). ).

  Next, in step S103, the amount of carbon dioxide absorbed by the absorbent disposed in the exhaust gas discharge path is measured (third step).

  Next, in step S104, the absorption rate of the absorbent determined by the measured absorption amount, the measured exhaust gas temperature, the measured carbon dioxide concentration in the exhaust gas, and the absorbent characteristics is lower than the target absorption rate. Determine if you are. Here, when it is determined (detected) that the pressure has decreased (Y in step S104), the absorbent disposed in the exhaust gas discharge path is replaced in step S105 (fourth step). For example, it may be replaced with an unabsorbed absorbent material. Moreover, you may replace | exchange for the absorber which heated more than discharge | release temperature and discharge | released carbon dioxide, and was regenerated | regenerated. Further, even if carbon dioxide is absorbed to some extent, it may be replaced if it is an absorbent material with a small amount of absorption.

  As described above, according to the present embodiment, the carbon dioxide absorption limit amount in the carbon dioxide absorbent made of the lithium composite oxide is determined by the temperature and the carbon dioxide concentration of the exhaust gas discharged from the discharge source. The absorbent material can be replaced in a more appropriate state, and carbon dioxide can be recovered more efficiently.

  This will be described in more detail below. The carbon dioxide recovery method described above is based on knowledge obtained for the first time as a result of intensive studies by the inventors described below. The inventors have clarified that the absorption rate of carbon dioxide in a lithium composite oxide, particularly lithium silicate, varies depending on the temperature of exhaust gas and the concentration of carbon dioxide.

  FIG. 2 is a characteristic diagram showing the change in the carbon dioxide absorption rate of the lithium silicate with respect to the amount of carbon dioxide absorbed by the lithium silicate at each exhaust gas temperature when the carbon dioxide concentration of the exhaust gas is 10%. is there. FIG. 3 shows the characteristics of the change in the carbon dioxide absorption rate of the lithium silicate with respect to the amount of carbon dioxide absorbed by the lithium silicate for each exhaust gas temperature when the carbon dioxide concentration of the exhaust gas is 20%. FIG. In any of the figures, the change in weight on the horizontal axis indicates the change (state) of the amount of carbon dioxide absorbed by the lithium silicate.

  As can be seen from FIG. 2 and FIG. 3, the absorption rate of carbon dioxide varies depending on the amount of carbon dioxide already absorbed by the lithium silicate. In addition, the change in the absorption rate varies depending on the temperature of the exhaust gas discharged from the discharge source and the carbon dioxide concentration in the exhaust gas (atmosphere).

  Based on these, high-efficiency carbon dioxide absorption is realized for each emission source by determining the maximum amount of carbon dioxide to be absorbed by the absorbent according to the temperature and carbon dioxide concentration of the exhaust gas emitted from the emission source. become able to.

  For example, as shown in FIG. 2, when the carbon dioxide concentration of the exhaust gas discharged from the emission source is 10%, when the amount of carbon dioxide absorbed by the lithium silicate increases at an exhaust gas temperature of 500 ° C., the absorption rate is It goes down. In this case, when the absorption reaction proceeds to the maximum amount of carbon dioxide that can be absorbed by the lithium silicate (25 wt%), it is considered that the carbon dioxide in the exhaust gas is not absorbed by the lithium silicate.

Here, when the exhaust gas having a carbon dioxide concentration of 10% is the target as described above, the minimum absorption rate (target absorption rate) required for the absorbent is, for example, 0.08 kg / It can be set (determined) as m ³ / s. In this case, when the carbon dioxide absorbed by the lithium silicate reaches 5% by weight, the calculated carbon dioxide absorption rate of the lithium silicate is lower than the absorption rate. Therefore, the lithium silicate (absorbing material) may be replaced when the amount of carbon dioxide absorbed by the lithium silicate reaches 5% by weight and the calculated absorption rate falls below 0.08 kg / m ³ / s.

In addition, when the carbon dioxide concentration of the exhaust gas discharged from the emission source is 10% and the exhaust gas temperature is 550 ° C., the minimum required absorption rate is set to 0.08 kg / m ³ / s from the flow rate of the exhaust gas. When the carbon dioxide absorbed by the lithium silicate reaches 15% by weight, the calculated carbon dioxide absorption rate of the lithium silicate is lower than the absorption rate. In this case, the lithium silicate may be exchanged when the amount of carbon dioxide absorbed by the lithium silicate reaches 15% by weight and the calculated absorption rate falls below 0.08 kg / m ³ / s.

Moreover, when the minimum required absorption rate is set to 0.1 kg / m ³ / s from the flow rate of the exhaust gas under the exhaust gas conditions, the calculation is performed when the carbon dioxide absorbed by the lithium silicate reaches 13% by weight. The carbon dioxide absorption rate of lithium silicate is lower than the absorption rate. In this case, the lithium silicate may be replaced when the absorption amount of carbon dioxide of the lithium silicate reaches 13% by weight and the calculated absorption rate is lower than 0.1 kg / m ³ / s.

  Here, as described above, for example, the upper limit absorption amount condition obtained from data such as FIG. 2 and FIG. 3 is provided as an exchange condition table as shown in Table 1 below, and this exchange condition table is referred to. By doing so, you may make it determine the replacement | exchange time of an absorber. Table 1 shows the range of carbon dioxide absorption for each temperature at which the target absorption rate is obtained.

  Here, the amount of carbon dioxide absorbed by the lithium silicate can be calculated from, for example, changes in the concentration of carbon dioxide in the exhaust gas before and after absorption of carbon dioxide and the flow rate of the exhaust gas. When measuring the absorption amount in this way, the absorption amount measuring means is configured by combining a carbon dioxide concentration measuring instrument and a calculation device that calculates the carbon dioxide absorption amount from a change in the carbon dioxide concentration measured by the measuring instrument. it can.

  The amount of carbon dioxide absorbed by the lithium silicate can be determined from the change in the weight of the lithium silicate before and after the absorption of carbon dioxide. If the change in weight is divided by the weight of lithium silicate before absorption, the amount of carbon dioxide absorbed, expressed as wt%, can be measured. In this case, the absorption amount measuring means can be constituted by a weight sensor that outputs a value obtained by dividing the change in the weight of the lithium silicate by the weight of the lithium silicate before absorption. What is necessary is just to provide a weight sensor in the location where an absorber is arrange | positioned.

  Lithium silicate generates heat when carbon dioxide is absorbed, and the amount of heat generated depends on the amount of carbon dioxide absorbed. Therefore, if the temperature change of the lithium silicate is measured, the calorific value is obtained from the measured temperature change, and the absorption amount can be obtained from the obtained calorific value. When measuring the amount of absorption in this way, measuring the amount of absorption by combining a temperature measuring device that measures the temperature of the absorbent and a calculation device that calculates the carbon dioxide absorption amount from the change in temperature measured by the temperature measuring device. Means can be configured.

  Furthermore, when the temperature of the exhaust gas discharged from the discharge source and the carbon dioxide concentration are constant, the amount of carbon dioxide absorbed by the lithium silicate (absorption amount) can also be calculated from the time of the absorption reaction. In this case, it is possible to obtain in advance the amount of time for which the absorption rate becomes lower than the absorption rate (target absorption rate) at which the lithium silicate is set, so that the absorption will occur as the required time elapses. The material may be exchanged.

  The above-described replacement may be performed, for example, by switching the exhaust gas flow path to a path in which another lithium silicate is disposed. After the exchange, the lithium silicate whose carbon dioxide absorption has reached the exchange condition is heated again to the carbon dioxide release temperature to release the carbon dioxide and regenerate as the above-described absorbent to be exchanged. Can be used.

  As explained above, carbon dioxide that cannot be absorbed in the exhaust gas by exchanging the absorbent material by limiting the range of the amount of carbon dioxide absorbed so that the optimum absorption rate can be obtained Can be suppressed, and carbon dioxide can be recovered more efficiently.

  Next, a carbon dioxide recovery device for carrying out the carbon dioxide recovery method in the present embodiment described above will be described with reference to FIG. FIG. 4 is a configuration diagram showing the configuration of the carbon dioxide recovery device 400 in the embodiment of the present invention.

  First, the carbon dioxide recovery device 400 includes an exhaust gas discharge path 401 through which exhaust gas containing carbon dioxide is transported, and an absorber 402 made of a lithium composite oxide disposed in the exhaust gas discharge path 401. The exhaust gas is discharged from a discharge source 410 such as a power generation facility, a boiler, or an incineration facility, and is transported through an exhaust gas discharge path 401. In this way, carbon dioxide in the exhaust gas is absorbed by the absorbent 402 in the process of being transported by the exhaust gas discharge path 401.

  Also, the carbon dioxide recovery device 400 stores absorbent material characteristics indicating the relationship between the heating temperature, the amount of absorbed carbon dioxide, and the carbon dioxide absorption rate with respect to the carbon dioxide concentration in the atmosphere in the absorbent material 402. The first storage unit 403, the second storage unit 404 storing the desired target absorption rate determined from the temperature, carbon dioxide concentration and flow rate of the exhaust gas, and the carbon dioxide absorbed by the absorbent 402 An absorption amount measuring unit 405 that measures the amount, and an exhaust gas state measuring unit 406 that measures the temperature of the exhaust gas transported through the exhaust gas discharge path 401 and the carbon dioxide concentration in the exhaust gas are provided.

  The absorbent material characteristics and the target absorption rate may be measured in advance. Absorber characteristics may be obtained by experiments on the lithium composite oxide to be used. Further, for example, if the exhaust gas state measurement unit 406 has a function of measuring the flow rate in addition to the temperature and carbon dioxide concentration of the exhaust gas, the emission source can be measured by measuring each value using these measurement functions. It is possible to obtain the target absorption rate for the exhaust gas discharged from 410. Further, if the exhaust gas state measurement unit 406 sequentially obtains the above-described state quantities, the target absorption rate can be automatically changed in accordance with the change in the state of the exhaust gas.

  Further, the absorption amount measuring unit 405 is based on a carbon dioxide concentration measuring device provided in the exhaust gas discharge path 401 on the discharge side from the place where the absorbent material 402 is disposed, and a change in the carbon dioxide concentration measured by the measuring device. What is necessary is just to be comprised from the calculation apparatus which calculates the carbon dioxide absorption amount. For example, the amount of carbon dioxide absorbed by a lithium composite oxide such as lithium silicate can be calculated from the change in the concentration of carbon dioxide in the exhaust gas before and after absorption of carbon dioxide and the flow rate of the exhaust gas.

  The absorption amount measuring unit 405 is composed of a weight sensor that continuously measures the weight of the absorbent material 402 and outputs the measurement result as a value obtained by dividing the measurement result by the weight of the absorbent material in the initial state (before absorption). If it is. The amount of carbon dioxide absorbed by the absorbent can be determined from the change in the weight of the absorbent before and after absorption of carbon dioxide.

  In addition, the absorption amount measuring unit 405 may be configured to include a temperature measuring device that measures the temperature of the absorbent material 402 and a calculation device that calculates the carbon dioxide absorption amount from a change in temperature measured by the temperature measuring device. Good. The absorbent material generates heat when carbon dioxide is absorbed, and the amount of heat generated depends on the amount of carbon dioxide absorbed.

  Further, the carbon dioxide recovery device 400 is stored in the first storage unit 403, the absorption amount measured by the absorption amount measurement unit 405, the exhaust gas temperature measured by the exhaust gas state measurement unit 406, and the carbon dioxide concentration in the exhaust gas. An absorption rate calculation unit 407 that obtains an absorption rate of the absorbent material 402 based on the absorbent material characteristics, and detects that the absorption rate calculated by the absorption rate calculation unit 407 is lower than the target absorption rate stored in the second storage unit 404. And a replacement time notification unit 408 for notifying that the absorbent material 402 arranged in the exhaust gas discharge path 401 is in the replacement time. For example, the replacement time notification unit 408 includes a display unit (not shown), and displays on the display unit a message prompting replacement of the absorbent material 402 in a state where the user can visually recognize the display unit.

  According to the carbon dioxide recovery device 400 in the present embodiment described above, when the absorption rate of the absorbent 402 is lower than the target absorption rate, a replacement instruction is notified by the replacement time notification unit 408, so a more appropriate state In this way, the absorbent material can be replaced, and carbon dioxide can be recovered more efficiently.

  Note that the carbon dioxide recovery device 400 includes a carbon dioxide recovery path 411 in which an absorbent 412 to be regenerated that has absorbed carbon dioxide is disposed, a heating unit 413 that heats the absorbent 412 to a discharge temperature or higher, and carbon dioxide recovery. A carrier gas supply unit 414 that supplies carbon dioxide as a carrier gas to the path 411 is provided. These absorbent regenerators regenerate by releasing carbon dioxide from the absorbent 412 that has absorbed carbon dioxide.

  As described above, when the replacement instruction is notified, the absorbent material 402 may be replaced with the absorbent material regenerated by the absorbent material regeneration unit. Further, the absorbent material 402 when the replacement instruction is notified may be regenerated by the absorbent material regenerating unit.

  Further, the carbon dioxide recovery device 400 may be provided with an absorbent material exchanging means for exchanging the absorbent material 402 in response to a notice of replacement of the absorbent material 402 by the exchange time notification unit 408. For example, the absorbent material replacement means replaces the absorbent material 402 that has absorbed carbon dioxide with the regenerated absorbent material 412. The absorbent material exchange means is composed of a fluidized bed such as a belt conveyor.

  Next, as shown in Table 1, the carbon dioxide recovery method using the upper limit absorption amount condition (exchange condition table) obtained from data such as FIG. 2 and FIG. 3 will be described with reference to the flowchart of FIG. explain.

  First, in step S501, the temperature, carbon dioxide concentration, and flow rate of the exhaust gas discharged to the exhaust gas discharge path of the carbon dioxide recovery device are measured. From these measurement results, the absorbent (lithium) disposed in the exhaust gas discharge path is measured. Silicate) to determine the absorption rate (target absorption rate) necessary to absorb carbon dioxide in the exhaust gas.

Next, in step S502, the replacement condition is determined with reference to the replacement condition table 501 from the determined target absorption speed. In the exchange condition table 501, for example, a range of carbon dioxide absorption at each temperature at which the target absorption rate is obtained as shown in Table 1 is set as the exchange condition. For example, when the target exhaust gas temperature is 550 ° C. and the determined target absorption rate is 0.08 kg / m ³ / s, the exchange condition is “0 to 15% by weight”, and the measured carbon dioxide If the amount of absorption exceeds 15% by weight, it will be replaced.

  Next, in step S503, the amount of carbon dioxide absorbed by the absorbent material (carbon dioxide absorption amount) is measured. For example, the measurement result of the carbon dioxide concentration in the exhaust gas being transported through the exhaust gas discharge path after the place where the absorbent material is placed, and the carbon dioxide in the exhaust gas being transported through the exhaust gas discharge path before the place where the absorbent material is placed What is necessary is just to obtain | require carbon dioxide absorption from the difference with the measurement result of a density | concentration, and the flow volume measurement result of waste gas.

  Next, in step S504, it is determined whether or not the measured carbon dioxide absorption is within the determined exchange condition range. Here, when it is determined that the measured carbon dioxide absorption amount is not within the range of the determined exchange condition (NO in step S504), the process proceeds to step S505, for example, transportation of exhaust gas in the exhaust gas discharge path is stopped ( In step S506, the absorbent material is replaced. At this time, the regenerating operation is also stopped and replaced with a regenerated absorbent material. Thereafter, in step S507, the transportation of the exhaust gas in the exhaust gas discharge path is started and the absorption is resumed.

  On the other hand, when it is determined that the measured carbon dioxide absorption amount is within the determined exchange condition range (YES in step S504), the process returns to step S501, and steps S501 to S504 are repeated. If the exhaust gas conditions do not change, step S503 and step S504 may be repeated. In addition, the carbon dioxide absorption amount in step S503 is a cumulative value. For example, the calculated result may be stored in a predetermined storage unit, and the newly measured / calculated result may be added.

  The present invention is not limited to the embodiment described above, and many modifications and combinations can be implemented by those having ordinary knowledge in the art within the technical idea of the present invention. It is obvious. For example, although lithium silicate has been described as an example of the lithium composite oxide, the present invention is not limited to this, and may be lithium zirconate, lithium ferrite, or the like.

  400 ... carbon dioxide recovery device, 401 ... exhaust gas discharge path, 402 ... absorbent, 403 ... first storage unit, 404 ... second storage unit, 405 ... absorption amount measurement unit, 406 ... exhaust gas state measurement unit, 407 ... absorption rate Calculation unit, 408 ... replacement time notification unit, 410 ... discharge source, 411 ... carbon dioxide recovery path, 412 ... absorbent, 413 ... heating unit, 414 ... carrier gas supply unit.

Claims (5)

A first step of obtaining, as an absorbent material property, a relationship between a heating temperature, an amount of absorbed carbon dioxide, and an absorption rate of carbon dioxide with respect to an atmospheric carbon dioxide concentration in an absorbent material made of a lithium composite oxide;
A second step of determining a desired target absorption rate by measuring a temperature, a carbon dioxide concentration, and a flow rate of the exhaust gas discharged to an exhaust gas discharge path through which exhaust gas containing carbon dioxide is discharged;
A third step of measuring the amount of carbon dioxide absorbed by the absorbent disposed in the exhaust gas discharge path;
The absorption rate of the absorbent determined by the measured amount of absorption, the measured temperature of the exhaust gas, the measured carbon dioxide concentration in the exhaust gas, and the characteristics of the absorbent is lower than the target absorption rate. And a fourth step of exchanging the absorbent disposed in the exhaust gas discharge path. The carbon dioxide recovery method according to claim 1,
In the fourth step, the carbon dioxide recovery method is characterized in that carbon dioxide is replaced with an unabsorbed absorbent material. An exhaust gas discharge route through which exhaust gas containing carbon dioxide is transported;
An absorbent material composed of a lithium composite oxide disposed in the exhaust gas discharge path;
A first storage unit storing an absorbent material characteristic indicating a relationship between a heating temperature, an amount of absorbed carbon dioxide, and an absorption rate of carbon dioxide with respect to an atmospheric carbon dioxide concentration in the absorbent material;
A second storage unit storing a desired absorption rate determined by the temperature, carbon dioxide concentration, and flow rate of the exhaust gas;
Absorption amount measuring means for measuring the amount of carbon dioxide absorbed by the absorbent,
Exhaust gas state measuring means for measuring the temperature of the exhaust gas transported through the exhaust gas exhaust path and the concentration of carbon dioxide in the exhaust gas;
The absorption amount measured by the absorption amount measuring means, the temperature of the exhaust gas measured by the exhaust gas state measurement means, the carbon dioxide concentration in the exhaust gas, and the absorbent material characteristics stored in the first storage unit An absorption rate calculating means for obtaining an absorption rate of the absorbent material;
It is detected that the absorption rate calculated by the absorption rate calculation means is lower than the target absorption rate stored in the second storage unit, and the absorbent disposed in the exhaust gas discharge path is in a replacement period. A carbon dioxide recovery apparatus comprising: a replacement time notification means for notifying The carbon dioxide recovery device according to claim 3,
A carbon dioxide recovery device comprising: an absorbent material replacement means for receiving the notification of replacement of the absorbent material by the replacement time notification means and replacing the absorbent material disposed in the exhaust gas discharge path. The carbon dioxide recovery apparatus according to claim 4, wherein
The carbon dioxide recovery device characterized in that the absorbent replacement means replaces carbon dioxide with an absorbent that has not been absorbed.

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