KR20220085903A - Apparatus for dry sorbent co2 capturing using plate heat exchanger and dry sorbent co2 capturing process using the same - Google Patents

Abstract

In the dry carbon dioxide collection device using a plate heat exchanger according to the present invention, two or more plate heat exchangers are positioned at a predetermined interval, and a dry adsorbent is fixed between the plate heat exchangers, respectively, located at the lower and upper parts in the vertical direction. Four or more beds having a lower reactor and an upper reactor, a cooling water supply unit supplying cooling water set according to an operation sequence to each of the four or more beds, an exhaust gas supply unit supplying an exhaust gas set according to an operation sequence to each of the four or more beds and a valve system for switching the exhaust gas, cooling water, steam supply at regular time intervals so that each bed sequentially operates in the adsorption step, the heating step, the desorption step and the cooling step, according to the operation sequence, the adsorption step, the heating step, The operation sequence of the desorption step and the cooling step is sequentially and repeatedly performed.

Description

Dry carbon dioxide capture device using plate heat exchanger and dry carbon dioxide capture process using same

The present invention relates to a dry carbon dioxide trapping device, and more particularly, to a dry carbon dioxide trapping device using a plate-type heat exchanger and a plate-type heat exchanger that uses a fixed bed formed of a dry absorbent to increase thermal efficiency and reduce renewable energy.

Fossil fuels are the most widely used for energy supply in modern society. As described above, although fossil fuels occupy a large part of the energy supply, carbon dioxide emissions worldwide are increasing due to the use of fossil fuels. The International Energy Agency (IEA) has established a strategy to reduce carbon dioxide emissions through the Bluemap 2050 scenario in order to reduce carbon dioxide emissions, the main culprit of greenhouse gases that cause global warming. The International Energy Agency's (IEA) target of carbon dioxide emissions by 2050 is half of the current carbon dioxide emissions, and carbon dioxide capture and treatment technology (CCS) accounts for about 20% of the strategy for reducing carbon dioxide.

CCS technology can be largely divided into a process of capturing and compressing carbon dioxide (CO ₂ ), and a process of transporting, storing, and processing. Although active research is being conducted on all processes, research on the carbon dioxide capture and compression process is being focused to improve the economic feasibility of CCS because the carbon dioxide capture and compression process accounts for 70-80% of the total CCS cost.

Representative post-combustion carbon dioxide capture technologies include wet capture technology, dry capture technology, and membrane technology. Wet capture technology usually uses an amine-based absorbent solution, absorbs carbon dioxide in the flue gas in an absorption tower by contacting it with an absorbent solution, removes carbon dioxide in the regeneration tower, regenerates the absorbent solution, and then recirculates it to the absorption tower. Such wet capture technology has the advantage of requiring low renewable energy, but has a problem in that harmful amines and amine-modified substances are released to the top of the absorption tower. In addition, the application of wet capture technology is limited depending on the concentration of carbon dioxide, the pressure of the exhaust gas to be treated, and the location for erecting a column. For example, when installed on a ship, the absorption tower is shaken, so that the exhaust and the absorbent solution do not contact each other evenly, inevitably lowering absorption performance and affecting stable process operation.

Dry carbon dioxide capture technology uses a physical or chemical adsorbent to repeatedly adsorb and desorb carbon dioxide to capture carbon dioxide. In general, chemical adsorbents with high carbon dioxide selectivity, high adsorption amount and low water adsorption are preferred. The capture process can be configured in various ways using a fluidized bed reactor, a moving bed reactor, or a fixed bed reactor. The dry carbon dioxide capture technology can be free from problems caused by the emission of amines and amine-modified products, but it is difficult to implement sensible heat recovery, so it has a disadvantage in that renewable energy is greater than the wet carbon dioxide capture process.

On the other hand, the separation membrane technology is a clean process that requires a small space, but has a limitation in the purity of the recovered carbon dioxide due to the principle constraint of physical separation and the energy requirement is large.

Korean Patent Publication No. 10-0983677

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a dry carbon dioxide capture device having high energy efficiency by reducing the energy required for desorption of the dry carbon dioxide capture process.

These and other objects and advantages of the present invention will become apparent from the following description of preferred embodiments.

The purpose is to have two or more plate heat exchangers spaced apart from each other by a predetermined interval, a dry adsorbent is fixed between the plate heat exchangers, and four having a lower reactor and an upper reactor positioned at the lower and upper parts in the vertical direction, respectively. At least one bed, a cooling water supply unit for supplying cooling water set according to the operation scheme to each of the four or more beds, an exhaust gas supply unit for supplying exhaust gas to the bed, and each bed sequentially in the adsorption step, heating step, desorption step and cooling step This is achieved by a dry carbon dioxide capture system using a plate heat exchanger that includes a valve system for switching the flue gas, cooling water and steam supplies to work at regular time intervals.

Preferably, the four or more beds sequentially repeat the operation sequence of the adsorption step, the heating step, the desorption step and the cooling step, wherein the adsorption step, the heating step, the desorption step and the cooling step are all performed in the same operation sequence. The adsorption step is performed simultaneously in different beds, and the exhaust gas supplied from the bottom direction from the exhaust gas supply unit moves upward and comes into contact with the dry adsorbent, and carbon dioxide contained in the exhaust gas is adsorbed by the dry adsorbent, and the dry type The heat of adsorption of carbon dioxide of the adsorbent is recovered through the cooling water supplied from the lower portion and transferred to a bed performing the heating step, and the heating step is performed by transferring the bed subjected to the adsorption step to the cooling water having the heat of adsorption recovered in the adsorption step and the cooling step. It is heated through cooling water having the recovered integrated heat, and in the desorption step, the bed subjected to the heating step is heated with supplied high-temperature steam to desorb carbon dioxide from the dry adsorbent, and the cooling step is heated in the desorption step The integrated heat may be recovered by supplying cooling water to the bed, and the cooling water having the recovered integrated heat may be transferred to the bed performing the heating step.

Preferably, the bed performing the adsorption step adsorbs carbon dioxide to the dry adsorbent of the lower reactor by supplying the exhaust gas in a state in which cooling water is supplied only to the lower reactor, and heat of adsorption of the lower reactor through the cooling water supplied from the lower part is recovered and transferred to the bed performing the heating step, and after the adsorption reaction of the lower reactor is completed, carbon dioxide is adsorbed to the dry adsorbent of the upper reactor in a state where cooling water is supplied only to the upper reactor, and through the cooling water supplied from the lower part The adsorption heat of the upper reactor may be recovered and transferred to a bed performing a heating step.

Preferably, the distance between the two or more plate heat exchangers may be 3 to 5 cm.

Preferably, the four or more beds sequentially repeat the operation sequence of the adsorption step, the first heating step, the second heating step, the first desorption step, the second desorption step, the first cooling step and the second cooling step. However, the adsorption step, the first heating step, the second heating step, the first desorption step, the second desorption step, the first cooling step and the second cooling step are performed simultaneously in different beds in the same operation sequence, the adsorption step The step is to move the exhaust gas supplied from the bottom direction from the lower reactor to the upper reactor in the upper direction, contact the dry adsorbent to adsorb the carbon dioxide contained in the flue gas to the dry adsorbent of the lower reactor and the upper reactor, and reduce the carbon dioxide adsorption heat of the dry adsorbent to the lower part It is recovered through the cooling water supplied from The cooling water having residual heat and the cooling water having the integrated heat recovered in the second cooling step are heated to heat the bed heated through the first heating step, and the integrated heat recovered in the first cooling step is heated in the second heating step. After heating the eggplant to a higher temperature than the first heating step through the cooling water, the cooling water having residual heat is transferred to the bed performing the first heating step, and the first desorption step is the first desorption step of heating the bed subjected to the second heating step of the supplied high temperature. Carbon dioxide is primarily desorbed from the dry adsorbent by heating with steam, and in the second desorption step, the bed subjected to the first desorption step is heated with the supplied high-temperature steam to secondarily desorb carbon dioxide from the dry adsorbent, and In the first cooling step, the cooling water is supplied to the bed heated in the second desorption step to first recover integrated heat, and the cooling water having the recovered first integrated heat is transferred to a bed performing the second heating step, and the second heating step is performed. In the cooling step, cooling water is supplied to the bed on which the first cooling step has been performed to recover the integrated heat secondarily and to have the recovered secondary integrated heat. The cooling water may be delivered to a bed performing the first heating step.

Preferably, the bed performing the adsorption step adsorbs carbon dioxide to the dry adsorbent of the lower reactor by supplying the exhaust gas in a state in which cooling water is supplied only to the lower reactor, and heat of adsorption of the lower reactor through the cooling water supplied from the lower part is recovered and transferred to the bed performing the heating step, and after the adsorption reaction of the lower reactor is completed, carbon dioxide is adsorbed to the dry adsorbent of the upper reactor in a state where cooling water is supplied only to the upper reactor, and through the cooling water supplied from the lower part The adsorption heat of the upper reactor may be recovered and transferred to a bed performing the first heating step.

Preferably, the exhaust gas supply unit may be to supply the exhaust gas from the lower direction to the upper direction of the four or more beds.

Preferably, the cooling water supply unit may supply cooling water to the lower reactor of the bed according to an operation sequence first, then stop supplying the cooling water to the lower reactor and then supply the cooling water to the upper reactor.

Preferably, the exhaust gas supply unit may lower the desorption temperature by lowering the pressure inside the four or more beds through a blower or a vacuum pump in the desorption step.

In addition, the above object is achieved by the carbon dioxide collecting process using the dry carbon dioxide collecting device using the above-described plate heat exchanger.

The dry carbon dioxide collection device using a plate heat exchanger according to an embodiment of the present invention performs adsorption and desorption of carbon dioxide in different beds at the same time according to an operation sequence of a plurality of beds in which an absorbent in the form of a fixed bed is disposed in the plate heat exchanger, By exchanging the heat of reaction and the heat of the desorption process between different beds during carbon dioxide adsorption to recover energy, high energy efficiency is achieved while using a dry absorbent, thereby reducing the renewable energy required in the carbon dioxide capture process.

However, the effects of the present invention are not limited to the above-mentioned effects, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a block diagram of a dry carbon dioxide collecting device using a plate heat exchanger according to an embodiment of the present invention.
FIG. 2 is a detailed configuration diagram of one of the beds of FIG. 1 .
3A and 3B are views for explaining an example of an operation sequence of a dry carbon dioxide collecting device using a plate heat exchanger according to an embodiment of the present invention.
4 shows the temperature profile in the adsorption step along the reactor length when using a single reactor.
5 is a graph showing a temperature distribution ( FIG. 5A ) and a carbon dioxide adsorption amount distribution ( FIG. 5B ) for a dry carbon dioxide collecting device using a plate heat exchanger according to an embodiment of the present invention.
6 is a graph showing the energy evaluation results of the dry carbon dioxide collection device using the plate heat exchanger according to an embodiment of the present invention compared to the wet carbon dioxide collection case using a 30wt% MEA aqueous solution as an absorbent.

With reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein.

In order to clearly express various layers and regions in the drawings, the thicknesses are enlarged. Throughout the specification, like reference numerals are assigned to similar parts. When a part, such as a layer, film, region, plate, etc., is “on” another part, it includes not only cases where it is “directly on” another part, but also cases where there is another part in between. Conversely, when we say that a part is "just above" another part, we mean that there is no other part in the middle.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. In case of conflict, the present specification, including definitions, will control. Also, although methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, suitable methods and materials are described herein.

1 is a block diagram of a dry carbon dioxide collecting device using a plate heat exchanger according to an embodiment of the present invention.

FIG. 2 is a detailed configuration diagram of one of the beds of FIG. 1 .

1 and 2, the dry carbon dioxide collecting device using a plate heat exchanger according to an embodiment of the present invention includes a bed 100, a cooling water supply unit 200, an exhaust gas supply unit 300, and a valve system (not shown). include

The dry carbon dioxide collecting device using a plate heat exchanger according to an embodiment of the present invention includes four or more beds 100 .

Each bed is provided with two or more reactors, wherein the two or more reactors are arranged to be vertically spaced apart from each other. In the example of FIG. 2 , for convenience of description, it is illustrated that the lower reactor 103 includes two reactors, the lower reactor 103 and the upper reactor 104 located at the upper part.

In the present invention, instead of configuring one reactor in the bed 100, the heat transfer efficiency is increased by configuring two different lower reactors 103 and an upper reactor 104 in which plate heat exchangers spaced apart from each other by a predetermined distance in the vertical direction are installed. make it When the dry adsorbent 101 comes into contact with carbon dioxide, heat of adsorption is generated by an adsorption reaction. At this time, the exhaust gas is supplied from the bottom of the bed 100 to the top for a smooth flow of the exhaust gas containing carbon dioxide. Accordingly, in the initial stage of the adsorption reaction, only the lower reactor 103 has an adsorption reaction and the upper reactor 104 has an adsorption reaction. This does not occur, and the adsorption reaction takes place in the upper reactor 104 from the middle of the reaction. Therefore, the adsorption reaction process is divided into an initial reaction, a middle reaction, and a late reaction so that the supplied cooling water has the highest temperature, and in the initial reaction, cooling water is supplied so that only the lower reactor 103 where the adsorption reaction occurs is submerged in the cooling water, , by supplying cooling water so that both the lower reactor 103 and the upper reactor 104 are submerged in the middle reaction, the temperature of the cooling water can be made as high as possible. The configuration for increasing the heat transfer efficiency through the two different lower reactors and the upper reactor will be described in detail with reference to FIGS. 3A and 3B to be described later.

And it is preferable that the interval between the plate heat exchanger 102 provided in the lower reactor 103 and the upper reactor 104 is 3 to 5 cm. When the distance between the plate heat exchangers 102 is less than 3 cm, the required number of plate heat exchangers 102 increases, increasing the capital cost of the process, and when the gap is more than 5 cm, the dry adsorbent 101 and The amount of heat transfer between the coolant/steam becomes small, and the heat cannot be effectively recovered.

In the lower reactor 103 and the upper reactor 104 constituting the bed 100, two or more plate heat exchangers 102 installed at a predetermined interval are positioned, and the dry adsorbent 101 is disposed between the plate heat exchangers 102. ) is fixed. As described above, in the present invention, carbon dioxide is adsorbed by using a dry absorbent in the form of a fixed bed. In FIG. 2, all of the dry adsorbents 101 positioned between all the plate heat exchangers 102 are not shown for convenience of explanation, but this is for convenience of explanation, and the upper and lower reactors constituting the bed 100 are carbon dioxide In order to increase the adsorption efficiency, it is preferable to fix the dry absorbent 101 between all the plate heat exchangers 102 . As described above, in the present invention, since the carbon dioxide capture process using a fixed bed in which the dry adsorbent 101 is fixed between the plate-type heat exchanger 102 inside the upper reactor and the lower reactor to proceed with the carbon dioxide adsorption process is used, in the adsorption and desorption process, the dry process The transport of the adsorbent can be omitted.

The adsorption bed models of the lower reactor 103 and the upper reactor 104 constituting the bed 100 are shown in Equations 1 to 6 below.

The total mass balance of the gas phase is the same as in Equation 1.

(Equation 1)

In Equation 1, C [mol/m ³ ] is the gas concentration, u [m/s] is the interstitial velocity, ρ [kg/m ³ ] is the density, ε is the bed porosity, H [m] is the bed height, z [m] is the normalized axial distance from 0 to 1, r [mol/kg·s] is the carbon dioxide adsorption rate of the dry adsorbent, and the subscripts s and g are the dry adsorbent and gas, respectively.

The component mass balance formula for the gaseous carbon dioxide gas is as shown in Equation (2).

(Equation 2)

In Equation 2, y is the mole fraction of carbon dioxide, and D _ax [m ² /s] is the axial dispersion coefficient).

The energy balance of the bed is as shown in Equations 3 to 5.

(Equation 3)

(Equation 4)

(Equation 5)

Equation 3 represents the energy balance of the adsorbent, Equation 4 represents the energy balance of the gas, and Equation 5 represents the energy balance of the cooling water.

In Equations 3 to 5, a [m ² /m ³ ] means the heat transfer area per unit volume between the gas and the adsorbent. and c [J/kg K] is specific heat, T [K] is temperature, U [W/m ² K] is heat transfer coefficient, ΔH _CO2 [J/mol] is heat of adsorption, λ _ax [W/m K] is It means the effective thermal conductivity in the axial direction. In addition, B [m] is the depth of the plate heat exchanger, 2 b [m] is the distance between the plate heat exchangers, N is the number of plate heat exchangers, q _cw [m ³ /h] is the volume flow rate of the coolant it means. Meanwhile, the subscripts h, hs, and sg denote cooling water, between cooling water and adsorbent, and between adsorbent and gas, respectively.

(Equation 6)

In Equation 6, m is the flow rate of steam, λ is the latent heat of steam, and ∂Th/∂t is the temperature change of steam with time.

In particular, in the present invention, since the adsorption reaction proceeds through the two reactors of the lower reactor and the upper reactor, T _h ( z ) of Equations 3 and 5 is the lower section from z = 0 to 0.5 and z = 0.5 to 1.0 It is calculated independently for the upper section of , and it is possible to reduce the regeneration energy of the dry adsorbent by operating the lower reactor according to time, stopping the upper reactor, stopping the lower reactor after a certain period of time, and operating the upper reactor.

The momentum balance equation is the same as Equation 7, which is used to calculate the pressure drop in the bed.

(Equation 7)

In Equation 7, g [m/s ² ] is the acceleration due to gravity, and the change in the superficial velocity of the gas is calculated by Equation 6 above.

The adsorption isothermal equation of the adsorbent used in the present invention is as shown in Equation 8 below.

(Equation 8)

In Equation 8, q _e [kg-CO ₂ /kg-sorbent] and q _m [kg-CO ₂ /kg-sorbent] are the equilibrium carbon dioxide adsorption amount and the maximum carbon dioxide adsorption amount, respectively, and K[bar ^-1 ] is is the adsorption equilibrium constant, P _CO2 [kPa] is the partial pressure of carbon dioxide, and t and t' are constants.

In addition, the relational expression of the equilibrium constant K in Equation 8 is the same as Equation 9.

(Equation 9)

In Equation 9, K ₀ and E are constants, and R [kJ/mol·K] is an ideal gas constant.

In addition, the relational expression of q _m in Equation 8 is the same as Equation 10.

(Equation 10)

In Equation 10, q _mo and are constants, and T ₀ is 273K as a reference temperature. And the relational expression of t is the same as Equation 11.

(Equation 11)

In Equation 11, t ₀ and d are constants.

The type of dry adsorbent used in the present invention is preferably a chemical adsorbent such as a PEI/TEPA-based amine-functionalized adsorbent capable of adsorbing a large amount of carbon dioxide at a low temperature and desorbing a large amount of carbon dioxide at a high temperature that is not too high. If desorption is considered, it is possible to use a physical adsorbent such as zeolite 13X or zeolite 5A.

In addition, the dry adsorbent is preferably used in the form of pellets by extruding the adsorbent in powder form. If a separate binder is used, process operation may be difficult due to agglomeration, and the adsorption performance may be very poor.

The cooling water supply unit 200 supplies cooling water to each of the four or more beds 100 using a pump or the like. At this time, the cooling water supply unit 200 supplies cooling water according to an operation sequence determined to each of the four or more beds 100 through valve control through the valve system. In this case, the method of supplying the cooling water of the cooling water supply unit 200 and the type of cooling water may be a method generally used in the carbon dioxide collecting device.

The exhaust gas supply unit 300 is individually connected to the lower portion of each of the four beds 100 , and supplies the exhaust gas according to an operation sequence determined to each of the four or more beds 100 through valve control through a valve system. In this case, the method of supplying the exhaust gas of the exhaust gas supply unit 300 may be a method generally used in the carbon dioxide collecting device.

In addition to the role of supplying the exhaust gas to the four beds 100 in the adsorption step through the blower or vacuum pump, the exhaust gas supply unit 300, the pressure inside the bed 100 in the desorption step can play a role in lowering The exhaust gas supply unit 300 lowers the pressure inside the bed 100 through a blower or a vacuum pump in the desorption step to lower the desorption temperature, thereby reducing the energy consumption of the process, and amine-functionalized dry adsorbent reduce the rate of denaturation of

In the present invention, the high-temperature steam supplied as a heat source for performing the desorption step in each bed 100 is applied to the bed performing the desorption step according to the operation sequence among the four beds 100 through valve control through the valve system. By supplying high-temperature steam, it is heated to the temperature at which the desorption reaction occurs. Preferably, high-temperature steam is used to increase the temperature of the bed performing the desorption step, but is not limited thereto, and various methods capable of supplying a heat source may be used. At this time, the high-temperature steam supplied to the bed 100 is supplied in the form of steam during the supply process, and is discharged as a condensate after heating the bed 100 . As an example, the high-temperature steam used in the present invention may be supplied from a facility/facility in which the collecting device according to the present invention is installed. For example, when the present invention is installed in a power plant facility, a method in which high-temperature steam is supplied through the power plant facility and used, and then the condensate is delivered again and circulated may be used.

In the present invention, rather than using one bed, four or more beds 100 are used, and the four or more beds 100 do not perform the same operation and process at the same time, but individually perform different process steps. At this time, the valve system sequentially switches the exhaust gas, cooling water, and steam supply at regular time intervals to operate in the adsorption step, the heating step, the desorption step, and the cooling step.

More specifically, the four or more beds 100 sequentially repeat the operation sequence of the adsorption step, the heating step, the desorption step, and the cooling step, but all of the adsorption step, the heating step, the desorption step and the cooling step must be performed in the same sequence. performed simultaneously in more than one bed. That is, in the present invention, the four or more beds 100 are adsorption steps, heating steps, desorption steps and cooling steps in the same sequence according to the operation sequence are necessarily performed simultaneously in at least one bed 100, and four or more beds ( 100) sequentially performs an adsorption step, a heating step, a desorption step, and a cooling step, so that the adsorption step, the heating step, the desorption step and the cooling step are performed by different beds in one operation sequence. Through this, in the present invention, based on the same sequence, all of the adsorption step, the heating step, the desorption step and the cooling step are simultaneously performed for four or more beds 100, and the adsorption step, the heating step, the desorption step and the cooling step are sequentially performed Repeat on each bed.

In the present invention, the adsorption step moves the exhaust gas supplied from the bottom direction from the exhaust gas supply unit 300 to the top direction to contact the dry adsorbent 101 to adsorb the carbon dioxide contained in the exhaust gas to the dry adsorbent 101, and the dry adsorbent ( 101) and the heat of adsorption of carbon dioxide are recovered through the cooling water supplied from the bottom and transferred to the bed performing the heating step. At this time, the bed performing the adsorption step performs a primary adsorption step of adsorbing carbon dioxide to the dry adsorbent 101 by supplying exhaust gas in a state in which cooling water is supplied so that only the lower reactor 103 is in contact, and then the upper reactor 104 is used. ), by performing the secondary adsorption step in a state in which the cooling water is supplied so that only the contact, the temperature of the cooling water supplied to the bed performing the heating step is increased as much as possible.

In the heating step, the bed on which the adsorption step has been performed is heated through the cooling water having the heat of adsorption recovered in the adsorption step and the cooling water having the integrated heat recovered in the cooling step.

Next, in the desorption step, the bed subjected to the heating step is heated with supplied high-temperature steam to desorb carbon dioxide from the dry adsorbent, and in the cooling step, cooling water is supplied to the bed heated in the desorption step to recover integrated heat and recover The cooling water having the integrated heat is transferred to the bed performing the heating step.

As such, in the dry carbon dioxide collecting device using a plate heat exchanger according to an embodiment of the present invention, each of four or more different beds 100 performs different stages of the above-described adsorption step, heating step, desorption step, and cooling step at the same time. In this case, the heat of adsorption generated in the bed performing the adsorption step is recovered through the cooling water and transferred to the bed performing the heating step, and the integrated heat recovered in the cooling step after desorption is also recovered through the cooling water to perform the heating step. By transferring it to the bed, the temperature of the bed performing the heating step can be increased to significantly reduce the energy that must be additionally supplied in the desorption step.

3 to 7 show a case in which the dry carbon dioxide trapping device using a plate heat exchanger according to an embodiment of the present invention is filled with a dry adsorbent called SiO2/0.37EB-PEI in which an amine polymer called PEI is functionalized as SiO2 as EB and supported. An example of the operation is described.

3A and 3B are views for explaining an example of an operation sequence of a dry carbon dioxide collection device using a plate heat exchanger according to an embodiment of the present invention, and FIG. 3A is an operation state of the first to seventh beds in one operation sequence. and FIG. 3B shows the entire operation sequence.

3A and 3B illustrate an operation sequence using a dry carbon dioxide collecting device using a plate heat exchanger using a total of seven beds of the first to seventh beds 110 to 170 as an example.

In one operation sequence, the first bed 110 performs an adsorption step, moving the exhaust gas supplied from the bottom direction from the lower reactor to the upper reactor in the upper direction, and contacting the dry adsorbent to lower the carbon dioxide contained in the exhaust gas. A second bed that adsorbs to the dry adsorbent of the reactor and recovers the heat of adsorption generated by the adsorption reaction of the dry adsorbent and carbon dioxide through the cooling water supplied from the bottom (S1) through the cooling water supplied from the bottom to perform the first heating step ( 120) (S2).

At this time, the first bed 110 performing the adsorption step adsorbs carbon dioxide to the dry adsorbent of the lower reactor 103 by supplying the exhaust gas in a state in which the cooling water is supplied only to the lower reactor 103, and the cooling water supplied from the lower part The heat of adsorption of the lower reactor 103 is recovered and transferred to the bed performing the heating step, and after the adsorption reaction of the lower reactor 103 is finished, the cooling water is supplied only to the upper reactor 104 in the state of the upper reactor 104. Carbon dioxide is adsorbed to the dry adsorbent, and heat of adsorption of the upper reactor 104 is recovered through cooling water supplied from the bottom and transferred to the second bed 120 performing the first heating step.

In the same operation sequence, the second bed 120 performs the first heating step in the current operation sequence after performing the adsorption step in the previous operation sequence, and having the heat of adsorption recovered in the adsorption step from the first bed 110 A seventh bed receiving the cooling water (S1), receiving the cooling water having the residual heat recovered in the second heating step from the third bed 130 performing the second heating step (S9), and performing the second cooling step The second bed 120 is heated by receiving the cooling water having the integrated heat recovered in the second cooling step transferred from 170 (S5).

And in the same operation sequence, the third bed 130 performs the first heating step in the previous operation sequence and then performs the second heating step in the current operation sequence, the sixth bed 160 performing the first cooling step. ) received from the cooling water having the integrated heat recovered in the first cooling step (S6) to heat the third bed 130 to a higher temperature than the first heating step, and then heat the cooling water having residual heat in the first heating step is transferred to the second bed 120 that performs (S9).

As such, in the present invention, by performing the first heating step and the second heating step as an intermediate process before proceeding to the desorption step immediately after the adsorption step, the heat energy obtained in the first and second cooling steps and the second heating step is recovered By heating in advance, it is possible to reduce thermal energy for heating to a temperature required in the desorption step.

In addition, in the same operation sequence, the fourth bed 140 performs the first desorption step in the current operation sequence after performing the second heating step in the previous operation sequence, and performs the desorption step by the supplied high-temperature steam The desorption reaction is carried out by heating to a temperature that can be achieved.

In addition, in the same operation sequence, the fifth bed 150 performs the first detachment step in the previous operation sequence and then performs the second detachment step in the current operation sequence, and performs the same operation as the first detachment step. Separately dividing the first desorption step and the second desorption step is to match the operation sequence because the desorption process requires a longer time compared to the adsorption process.

Through the first desorption step and the second desorption step, the fourth bed 140 and the fifth bed 150 receive carbon dioxide from the bottom while being heated to the desorption temperature, desorb the carbon dioxide adsorbed to the dry adsorbent, and then return carbon dioxide again regenerated to adsorb.

In addition, in the same operation sequence, the sixth bed 160 performs the first cooling step in the current operation sequence after performing the second detachment step in the previous operation sequence, and the second through the coolant S4 provided from the coolant supply unit. While cooling the bed cooled to a high temperature in the desorption step, the integrated heat is recovered and the cooling water having the first integrated heat is transferred to the third bed 130 performing the second heating step (S6).

In addition, in the same operation sequence, the seventh bed 170 performs the first cooling step in the previous operation sequence and then performs the second cooling step in the current operation sequence. While cooling the partially cooled bed to a temperature suitable for the desorption reaction in the cooling step, the integrated heat is recovered and the cooling water having the secondary integrated heat is transferred to the second bed 120 performing the first heating step (S5) do.

In the present invention, the first cooling step and the second cooling step are separately performed in order to recover the integrated heat in the cooling step as much as possible and to increase the cooling efficiency. Since the first desorption step and the second desorption step are performed at a high temperature, whereas the adsorption step is performed at a lower temperature than the desorption step, the bed after the desorption step is cooled to perform the adsorption step again. At this time, since the sixth bed 160 performing the first cooling step is cooled through the cooling water immediately after performing the second desorption step, the integrated heat recovered through the cooling water is higher and thus has a higher temperature. On the other hand, since the seventh bed 170 performing the second cooling step is primarily cooled through the first cooling step, the integrated heat recovered through the coolant than the sixth bed 160 performing the first cooling step It has a relatively low temperature.

Therefore, the cooling water having the first integrated heat having a relatively high temperature is transferred to the third bed 130 performing the second heating step (S6) to heat the third bed 130, and then cooling water having residual heat The second bed 120 is additionally heated by transferring (S9) to the second bed 120 again. In addition, the cooling water having the secondary integrated heat having a relatively low temperature is transferred to the second bed 120 performing the first heating step (S5) to heat the second bed 120 .

The above-described adsorption step, first heating step, second heating step, first desorption step, second desorption step, first cooling step and second cooling step are performed simultaneously in different beds in the same sequence. And as shown in Fig. 3b, in one sequence, the adsorption step, the first heating step, the second heating step, the first desorption step, the second desorption step, the first cooling step and the second cooling step are performed simultaneously in different beds. After that, in the next operation sequence, each bed performs the next step, respectively. In this process, the energy generated or provided in each step is recovered by the cooling water and transferred to the bed performing other steps to be utilized, thereby reducing the renewable energy required in the desorption step.

4 shows the temperature profile in the adsorption step along the reactor length when using a single reactor. In FIG. 4 , the x-axis represents the length of the reactor (vertical height), where 0 represents the bottom of the reactor and 1 represents the top of the reactor. And the y-axis represents the measured temperature.

Referring to FIG. 4 , at the beginning of the adsorption reaction in the adsorption step, since the exhaust gas supplied from the lower part performs an adsorption reaction from the lower part of the reactor, heat of adsorption according to the adsorption reaction is generated at the lower part of the reactor (about 40% of the lower part), whereas In the upper part of the reactor (about 40 to 100% from the lower part), there is hardly any adsorption reaction with carbon dioxide in the exhaust gas, so no heat of adsorption is generated. As such, in the initial stage of the adsorption reaction, only the lower portion of the reactor generates heat of adsorption due to the adsorption reaction. Therefore, when cooling water is supplied to the upper part of the reactor where no heat of adsorption is generated, the temperature of the cooling water cannot be sufficiently raised through the recovery of heat of adsorption. Therefore, in the present invention, after separating the reactor provided in the bed into a lower reactor 103 and an upper reactor 104, respectively, at the beginning of the reaction, an adsorption step is performed in a state in which cooling water is supplied only to the lower reactor 103, so that the cooling water The heat of adsorption is recovered.

Also, in the middle of the adsorption reaction, it can be seen that the heat of adsorption is reduced at the lower position of the reactor as the adsorption reaction is largely completed, and the heat of adsorption is most generated at the center of the reactor. In addition, it can be seen that in the latter half of the adsorption reaction, the adsorption reaction is terminated at the overall position of the reactor, so that additional heat of adsorption is hardly generated. As such, in the early stage of the adsorption reaction, the heat of adsorption due to the adsorption reaction is intensively generated at the lower position of the reactor, and in the middle of the adsorption reaction, the heat of adsorption due to the adsorption reaction is intensively generated at the middle position of the reactor. Therefore, in the present invention, the reactor in the bed is divided into a lower reactor 103 and an upper reactor 104, the plate heat exchangers of each reactor are installed 3 to 5 cm apart, and then, at the beginning of the adsorption reaction where the exhaust gas starts to be injected, the lower reactor Heat of adsorption is recovered by supplying cooling water only to (103), stopping the supply of cooling water to the lower reactor 103 at the point in time when the mid-adsorption reaction is in progress after the initial adsorption reaction, and supplying cooling water only to the upper reactor 104 to bring the heat of adsorption into contact. By recovering it, the temperature of the cooling water according to the recovery of the adsorption heat can be made as high as possible. That is, in the present invention, by separately controlling the supply of cooling water to the lower reactor 103 and the upper reactor 104, the maximum heat can be provided to the bed performing the heating step by maximally increasing the temperature of the cooling water that has recovered the heat of adsorption.

5 is a graph showing a temperature distribution ( FIG. 5A ) and a carbon dioxide adsorption amount distribution ( FIG. 5B ) for a dry carbon dioxide collecting device using a plate heat exchanger according to an embodiment of the present invention. This graph was obtained under the condition of a carbon dioxide recovery rate of 90%.

The temperature distribution was first sampled at 120 s after the end of the adsorption step. After that, when the first heating step and the second heating step are finished, 360 seconds is reached, and the desorption step is finished at 600 seconds. After that, the first cooling step and the second cooling step are performed for 240 seconds, and the adsorption step is started again and the cycle is repeated. At this time, it can be seen that the temperature of the second cooling step is high. At this time, the remaining integrated heat is recovered by the cooling water and then transferred to the bed of the heating step, thereby recycling the energy of the cooling step.

FIG. 5b shows the distribution of the amount of carbon dioxide adsorbed, and it can be seen that the adsorption amount at the bottom of the reactor is the largest and decreases toward the outlet after the adsorption step is completed.

As the bed is heated in the heating steps 1 and 2, it can be seen that a part of the adsorbed carbon dioxide is desorbed, moves toward the outlet of the bed, and is re-adsorbed. In addition, it can be seen that a significant amount of carbon dioxide is desorbed at 600 sec at the end of the desorption step in which high-temperature steam is supplied.

6 is a graph showing the energy evaluation results of the dry carbon dioxide collection device using the plate heat exchanger according to an embodiment of the present invention compared to the wet carbon dioxide collection case using a 30wt% MEA aqueous solution as an absorbent. Energy is expressed as electrical energy and represents the total energy required to liquefy 1 ton of carbon dioxide to a state of 150 bar and 313 K, which is the standard condition for underground storage. In the figure, W _liq is the compression energy required for liquefaction after collection, W _blower is the blower driving energy, and W _stm is the value obtained by converting the steam energy required for desorption into equivalent electric energy assuming a Carnot engine with an efficiency of 75%.

Referring to FIG. 6 , comparing the energy evaluation result of the dry carbon dioxide capture device using a plate heat exchanger according to an embodiment of the present invention with a conventional wet carbon dioxide capture device (MEA) based on a 30 wt% MEA aqueous solution, the capture energy It can be seen that (W _blower +W _stm ) is 132.3 kWh/t-CO2, which is greatly improved compared to 173.2 kWh/t-CO2 in the wet process.

As described above, the dry carbon dioxide collection device using a plate heat exchanger according to an embodiment of the present invention forms a kind of simulated moving-bed (SMB) and controls the flow of cooling water and exhaust gas with respect to the dry adsorbent fixed bed in the operation sequence. By supplying differently through valve control, the amount of energy required for regeneration of the adsorbent in the carbon dioxide capture process can be reduced by recovering and recycling the thermal energy generated in each step.

Although preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention as defined in the following claims are also provided. is within the scope of the

100: bed 101: dry adsorbent
102: plate heat exchanger 103: bottom reactor
104: upper reactor
110: first bed 120: second bed
130: third bed 140: fourth bed
150: 5th bed 160: 6th bed
170: 7th bed
200: coolant supply
300: exhaust gas supply unit

Claims (10)

four or more beds in which two or more plate heat exchangers are spaced apart from each other by a predetermined interval, a dry adsorbent is fixed between the plate heat exchangers, and each having two or more reactors in a vertical direction;
a cooling water supply unit supplying cooling water set according to an operation sequence to each of the four or more beds;
an exhaust gas supply unit for supplying exhaust gas set according to an operation sequence to each of the four or more beds; and
a valve system for switching the cooling water, the exhaust gas, and the supplied high-temperature steam at regular time intervals so that the four or more beds sequentially operate in the adsorption step, the heating step, the desorption step, and the cooling step;
Including, a dry carbon dioxide capture device using a plate heat exchanger. According to claim 1,
The four or more beds sequentially repeat the operation sequence of the adsorption step, the heating step, the desorption step, and the cooling step,
The adsorption step, the heating step, the desorption step and the cooling step are all performed simultaneously in different beds in the same one operation sequence,
The adsorption step moves the exhaust gas supplied from the bottom direction from the exhaust gas supply unit to the top direction, contacts the dry adsorbent to adsorb the carbon dioxide contained in the exhaust gas to the dry adsorbent, and transfers the heat of adsorption of the dry adsorbent and carbon dioxide from the bottom It is recovered through the supplied cooling water and transferred to a bed performing a heating step,
In the heating step, the bed that has performed the adsorption step in the previous operation sequence is heated through the cooling water having the heat of adsorption recovered in the adsorption step and the cooling water having the integrated heat recovered in the cooling step,
In the desorption step, the bed subjected to the heating step in the previous operation sequence is heated with supplied high-temperature steam to desorb carbon dioxide from the dry adsorbent,
In the cooling step, cooling water is supplied to the bed heated in the desorption step to recover integrated heat, and the cooling water having the recovered integrated heat is transferred to the bed performing the heating step. 3. The method of claim 2,
The bed performing the adsorption step adsorbs carbon dioxide to the dry adsorbent of the reactor located at the lower portion by supplying the exhaust gas in a state in which cooling water is supplied only to the lower reactor among the two or more reactors, and is located at the lower portion through the cooling water supplied from the lower portion The adsorption heat of the reactor is recovered and transferred to a bed performing a heating step,
After the adsorption reaction of the lower reactor is completed, carbon dioxide is adsorbed to the dry adsorbent of the upper reactor while cooling water is supplied only to the upper reactor among the two or more reactors, and the heat of adsorption of the upper reactor is absorbed through the cooling water supplied from the lower part recovered and transferred to a bed performing a heating step;
Dry carbon dioxide capture device using plate heat exchanger. According to claim 1,
The distance between the two or more plate heat exchangers is 3 to 5 cm, a dry carbon dioxide collecting device using a plate heat exchanger. According to claim 1,
The four or more beds sequentially repeat the operation sequence of the adsorption step, the first heating step, the second heating step, the first desorption step, the second desorption step, the first cooling step and the second cooling step,
the adsorption step, the first heating step, the second heating step, the first desorption step, the second desorption step, the first cooling step and the second cooling step are performed simultaneously in different beds in the same one operation sequence,
The adsorption step moves the exhaust gas supplied from the bottom direction from the lower reactor to the upper reactor in the upper direction, contacts the dry adsorbent to adsorb the carbon dioxide contained in the flue gas to the dry adsorbent of the lower reactor and the upper reactor, and the heat of adsorption of the dry adsorbent and carbon dioxide is recovered through the cooling water supplied from the bottom and transferred to the bed performing the first heating step,
In the first heating step, the cooling water having the heat of adsorption recovered in the adsorption step, the cooling water having the residual heat recovered in the second heating step, and the integrated heat recovered in the second cooling step for the bed that has performed the adsorption step in the previous operation sequence It is heated through cooling water having
In the second heating step, the bed heated through the first heating step in the previous operation sequence is heated to a higher temperature than the first heating step through the cooling water having the integrated heat recovered in the first cooling step, and then the cooling water having residual heat. transfer to the bed performing the first heating step,
In the first desorption step, carbon dioxide is primarily desorbed from the dry adsorbent by heating the bed subjected to the second heating step in the previous operation sequence with supplied high-temperature steam,
In the second desorption step, carbon dioxide is secondarily desorbed from the dry adsorbent by heating the bed that has performed the first desorption step in the previous operation sequence with supplied high-temperature steam,
In the first cooling step, cooling water is supplied to the bed that has performed the second desorption step in the previous operation sequence to recover integrated heat and transfer the cooling water having the recovered first integrated heat to the bed performing the second heating step do,
In the second cooling step, the cooling water is supplied to the bed that has performed the first cooling step in the previous operation sequence to recover the integrated heat secondarily, and the cooling water having the recovered secondary integrated heat is transferred to the bed performing the first blood flow step A dry carbon dioxide capture device using a plate heat exchanger. 6. The method of claim 5,
The bed performing the adsorption step adsorbs carbon dioxide to the dry adsorbent of the lower reactor by supplying the exhaust gas in a state in which cooling water is supplied only to the lower reactor, and recovers heat of adsorption of the lower reactor through the cooling water supplied from the lower part and heats it pass to the bed to perform the steps,
After the adsorption reaction of the lower reactor is completed, carbon dioxide is adsorbed to the dry adsorbent of the upper reactor in a state where cooling water is supplied only to the upper reactor, and the heat of adsorption of the upper reactor is recovered through the cooling water supplied from the lower part to perform the first heating step Passing on to Peter to perform,
Dry carbon dioxide capture device using plate heat exchanger. According to claim 1,
The exhaust gas supply unit supplies the exhaust gas from the lower direction to the upper direction of the four or more beds, a dry carbon dioxide collecting device using a plate heat exchanger. According to claim 1,
The cooling water supply unit first supplies cooling water to the lower reactor of the bed according to an operation sequence, then stops supplying the cooling water to the lower reactor and then supplies the cooling water to the upper reactor, a dry carbon dioxide collecting device using a plate heat exchanger. 3. The method of claim 2,
The exhaust gas supply unit lowers the pressure inside the four or more beds through a blower or a vacuum pump in the desorption step to lower the desorption temperature, a dry carbon dioxide collecting device using a plate heat exchanger. A carbon dioxide capture process using the dry carbon dioxide capture device using the plate heat exchanger according to claim 1.

Images