System and process of capturing carbon dioxide from flue gases

Abstract

A system and a process for capturing Carbon Dioxide (CO2) from flue gases are disclosed. The process comprises feeding a flue gas comprising CO2 to at least one Rotary Packed Bed (RPB) absorber rotating circularly. A solvent may be provided through an inner radius of the RPB absorber. The solvent may move towards an outer radius of the RPB absorber. The solvent may react with the flue gas in a counter-current flow. The process further includes passing the flue gas through at least one of a water wash and an acid wash to remove traces of the solvent present in the flue gas. Finally, the solvent reacted with the CO2 may be thermally regenerated for re-utilizing the solvent back in the process.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a National Stage of PCT/GB2019/051772, filed 24 Jun. 2019, titled SYSTEM AND PROCESS OF CAPTURING CARBON DIOXIDE FROM FLUE GASES, published as International Patent Application Publication No. WO 2020/002891, which claims the benefit and priority to UK Patent Application No. 1813839.6, filed on 24 Aug. 2018, and Indian Patent Application No. 201811023872, filed 26 Jun. 2018, each of which is incorporated herein by reference in their entirety for all purposes.

FIELD OF THE DISCLOSURE

The present disclosure is generally related to a chemical process and more particularly related to a process of capturing carbon dioxide from flue gases.

BACKGROUND

The subject matter discussed in the background section should not be assumed to be prior art merely as a result of its mention in the background section. Similarly, a problem mentioned in the background section or associated with the subject matter of the background section should not be assumed to have been previously recognized in the prior art. The subject matter in the background section merely represents different approaches, which in and of themselves may also correspond to implementations of the claimed technology.

FIG. 1 illustrates a block diagram 100 of a conventional process for capturing Carbon Dioxide (CO₂) from flue gases. CO₂ is separated from a mixture of gases, using a solvent which selectively reacts with the CO₂. After the CO₂ has reacted with the solvent, the solvent can be regenerated using heat to release the CO₂ and regenerate the solvent for further CO₂ processing. A flue gas 102 containing CO₂ is contacted with a liquid solvent in a static packed column 104. The liquid solvent is cascaded over a top of the static packed column 104 and falls under gravity to a bottom where it is collected in a sump.

A second static packed column 106 having structured packing comprises wash stages to remove traces of the solvent and volatile chemicals. A gaseous mixture depleted of CO₂ passes through the wash stages to remove traces of the solvent and volatile chemicals formed through degradation reactions of the solvent components. Thus, the flue gas 108 depleted of CO₂ is released from the top of the static packed column 104. All of the wash stages occur in similar static structured packing and use water or acid for washing.

The solvent is fed into a top section of a stripper column 112 and allowed to fall under gravity over a packing material to a bottom of the stripper column 112. At the bottom, the solvent is drawn into a reboiler 114. Inside the reboiler 114, the solvent is heated to a temperature so that at an operating pressure of the stripper column 112, water present in the solvent gets vaporized to steam. The steam and the CO₂ rise to a top of the stripper column 112 where a condenser cools the steam and gas to around 40° C. This condenses the steam into water 116 and gaseous CO₂ 118. The condensed water 116 is returned to the top of the stripper column via reflux drum 120 and the gaseous CO₂ 118 used for downstream processes while the solvent at the bottom of the stripper is recycled to an absorber as a lean solvent via the heat exchanger 110, ready to repeat the absorption process again.

Utilization of static packed columns in conventional processes provides inefficient mixing of the CO₂ present in flue gases and is limited by the gravitational force under which the solvent flows, thus limiting the mass transfer with solvents and during the water and acid washes. Further, the large size of static packed columns used in conventional processes require vast amounts of space and lead to high installation and operational cost of the system. Thus, an improved system and process for capturing CO₂ from flue gases are much desired.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings illustrate various embodiments of systems, methods, and embodiments of various other aspects of the disclosure. Any person with ordinary skills in the art will appreciate that the illustrated element boundaries (e.g., boxes, groups of boxes, or other shapes) in the figures represent one example of the boundaries. It may be that in some examples one element may be designed as multiple elements or that multiple elements may be designed as one element. In some examples, an element shown as an internal component of one element may be implemented as an external component in another and vice versa. Furthermore, elements may not be drawn to scale. Non-limiting and non-exhaustive descriptions are described with reference to the following drawings. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating principles.

FIG. 1 illustrates a block diagram 100 of a conventional process for capturing Carbon Dioxide (CO₂) from flue gases, according to the prior art.

FIG. 2 illustrates a block diagram 200 of a system for capturing Carbon Dioxide (CO₂) from flue gases, according to an embodiment.

FIG. 3A illustrates a block diagram 300 illustrating functioning of a Rotary Packed Bed (RPB) absorber 302 in a system for capturing Carbon Dioxide (CO₂) from flue gases, according to another embodiment.

FIG. 3B illustrates a block diagram 3000 illustrating functioning of a Rotary Packed Bed (RPB) absorber 3020 in a system for capturing Carbon Dioxide (CO₂) from flue gases.

FIG. 4A illustrates a block diagram 400 representation of a vacuum solvent reclamation system, according to an embodiment.

FIG. 4B illustrates a block diagram 4000 representation of a vacuum solvent reclamation system, according to an embodiment.

FIGS. 5A and 5B illustrate a flowchart 500 illustrating a process of capturing Carbon Dioxide (CO₂) from flue gases, according to an embodiment.

FIG. 6 illustrates a block diagram 600 representation of a Rotary Packed Bed Absorber

FIG. 7 illustrates a graph showing vapor liquid equilibrium (VLE) relationship between partial pressure of CO₂ in the vapor phase and the loading (i.e. concentration) of CO₂ in a solvent at 40 C.

FIG. 8 illustrates a design of a system 1200 for capturing 10 tons of CO₂ per day.

DETAILED DESCRIPTION

Some embodiments of this disclosure, illustrating all its features, will now be discussed in detail. The words “comprising,” “having,” “containing,” and “including,” and other forms thereof, are intended to be equivalent in meaning and be open ended in that an item or items following any one of these words is not meant to be an exhaustive listing of such item or items, or meant to be limited to only the listed item or items.

It must also be noted that as used herein and in the appended claims, the singular forms “a,” “an,” and “the” include plural references unless the context clearly dictates otherwise. Although any systems and methods similar or equivalent to those described herein can be used in the practice or testing of embodiments of the present disclosure, the preferred systems and methods are now described.

According to a first aspect of the present disclosure, there is provided a process of capturing Carbon Dioxide (CO₂) from flue gases, the process comprising the step of: feeding a flue gas comprising CO₂ to at least one Rotary Packed Bed (RPB) absorber rotating circularly, wherein a solvent provided through an inner radius of the at least one RPB absorber moves towards an outer radius of the at least one RPB absorber, and wherein the solvent reacts with the flue gas in a counter-current flow.

Preferably, wherein the process further comprises the step of: thermally regenerating the solvent reacted with the CO₂ for re-utilizing the solvent in the process.

Further preferably, wherein the process further comprises the step of: passing the flue gas through one or both of a water wash and an acid wash to remove traces of the solvent present in the flue gas; optionally, wherein one or both of the water wash and the acid wash are conducted on separate Rotary Packed Beds (RPBs).

Advantageously, wherein a housing of the RPB or RPBs is mounted on a rotatable disk.

Preferably, wherein the step of feeding a flue gas comprising CO₂ to at least one Rotary Packed Bed (RPB) absorber rotating circularly comprises feeding the flue gas to two, three, four, five or six Rotary Packed Bed (RPB) absorbers rotating circularly.

Further preferably, wherein the two, three, four, five or six Rotary Packed Bed (RPB) absorbers rotating circularly are arranged in series on a common shaft.

Advantageously, wherein the solvent reacts with the flue gas in a counter-current flow to remove CO₂ from the flue gas and form CO₂ rich solvent.

Preferably, further comprising the step of: passing the CO₂ rich solvent to a stripper, wherein the stripper acts to strip CO₂ from the CO₂ rich solvent forming CO₂ lean solvent.

Further preferably, wherein the stripper is a stripper column; or, a stripper static column; or, an RPB stripper.

Advantageously, wherein the CO₂ lean solvent is re-introduced into the at least one Rotary Packed Bed (RPB) absorber rotating circularly.

Preferably, further comprising the step of: passing CO₂ rich solvent leaving the at least one Rotary Packed Bed (RPB) absorber to a Rotary Packed Bed (RPB) O₂ eliminator; or, a static packed bed O₂ eliminator; and eliminating dissolved O₂ from the solvent.

Further preferably, wherein the step of passing CO₂ rich solvent leaving the Rotary Packed Bed (RPB) absorber to a Rotary Packed Bed (RPB) O₂ eliminator; or, a static packed bed O₂ eliminator; and eliminating O₂ from the solvent eliminates 90% or more of the O₂ present in the CO₂ rich solvent.

Advantageously, each Rotary Packed Bed (RPB) has the following dimensions: radius: from 0.2 m to 1.25 m, or from 0.2 m to 0.8 m; axial length: from 0.02 m to 1.0 m, or from 0.2 m to 0.6 m; volume: from 0.04 m³ to 4.9 m³, or from 0.04 m³ to 0.6 m³.

According to another aspect of the present invention, there is provided a system for capturing Carbon Dioxide (CO₂) from flue gases, the system comprising: at least one Rotary Packed Bed (RPB) absorber configured to rotate circularly, wherein when the RPB rotates circularly a solvent provided through an inner radius of the at least one RPB absorber moves towards an outer radius of the at least one RPB absorber, and wherein the solvent reacts with flue gas in a counter-current flow to capture CO₂.

Preferably, wherein the system further comprises: components for thermally regenerating the solvent reacted with the CO₂ for re-utilizing the solvent in the process.

Further preferably, wherein the system further comprises: one or both of a water wash and an acid wash, wherein passing the flue gas through one or both of the water wash and the acid wash removes traces of the solvent present in the flue gas.

Advantageously, wherein a housing of the RPB is mounted on a rotatable disk.

Preferably, wherein the system comprises two, three, four, five or six Rotary Packed Bed (RPB) absorbers configured to rotate circularly.

Further preferably, wherein the two, three, four, five or six Rotary Packed Bed (RPB) absorbers configured to rotate circularly are arranged in series on a common shaft.

Advantageously, wherein the solvent reacts with the flue gas in a counter-current flow to remove CO₂ from the flue gas and form CO₂ rich solvent.

Preferably, further comprising: a stripper, wherein the stripper is configured to strip CO₂ from the CO₂ rich solvent forming CO₂ lean solvent.

Further preferably, wherein the stripper is an RPB stripper.

Advantageously, wherein the system is configured to re-introduce the CO₂ lean solvent into the at least one Rotary Packed Bed (RPB) absorber rotating circularly.

Preferably, further comprising: a Rotary Packed Bed (RPB) O₂ eliminator; or, a static packed bed O₂ eliminator; for eliminating O₂ from CO₂ rich solvent, the Rotary Packed Bed (RPB) O₂ eliminator; or, the static packed bed O₂ eliminator; positioned to eliminate O₂ from CO₂ rich solvent leaving the at least one Rotary Packed Bed (RPB) absorber.

Further preferably, wherein the Rotary Packed Bed (RPB) O₂ eliminator; or, a static packed bed O₂ eliminator; is configured to eliminate 90% or more of the O₂ present in the CO₂ rich solvent.

Advantageously, wherein each Rotary Packed Bed (RPB) has the following dimensions: radius: from 0.2 m to 1.25 m, or from 0.2 m to 0.8 m; axial length: from 0.02 m to 1.0 m, or from 0.2 m to 0.6 m; volume: from 0.04 m³ to 4.9 m³, or from 0.04 m³ to 0.6 m³.

The process as described in any one of the paragraphs above, or the system as described in any one of the paragraph above, wherein the solvent comprises: a tertiary amine; and/or, a sterically hindered amine; and/or, a polyamine; and/or, a carbonate buffer salt; and/or, water (optionally deionized water); optionally, water present from 10 wt % to 70 wt %.

Preferably, wherein the solvent has a viscosity from 1 cp to 100 cp.

Further preferably, wherein the solvent: is any solvent disclosed in US 2017/0274317 A1; and/or, the solvent comprises: a tertiary amine (for example, N-methyl-diethanolamine and/or 2-(diethylamino)ethanol), and/or, a sterically hindered amine (for example, 2-amino-2-ethyl-1,3-propanediol, 2-amino-2-hydroxymethyl-1,3-propanediol and/or 2-amino-2-methyl-1-propanol), and/or, a polyamine (for example, 2-piperazine-1-ethylamine and/or 1-(2-hydroxyethyl)piperazine), and/or, a carbonate buffer (for example, potassium carbonate), and/or, water (for example, deionised water).

Advantageously, wherein the solvent comprises: an amino hindered alcohol (optionally, amino-2-methyl-1-propanol), a polyamine (optionally, amino ethyl piperazine) and water.

In another aspect of the present invention, there is provided an arrangement of Rotary Packed Bed (RPB) absorbers comprising two, three, four, five or six RPB absorbers configured to rotate circularly, wherein the RPB absorbers are arranged in series on a common shaft.

In another aspect of the present invention, there is provided a vacuum solvent reclamation system for removing Heat Stable Salts, degradation products and other contaminants from Carbon Dioxide (CO₂) capture solvents, the vacuum solvent reclamation system comprising: a feed product exchanger configured to increase the temperature of Carbon Dioxide (CO₂) capture solvents; a reboiler configured to further increase the temperature of Carbon Dioxide (CO₂) capture solvents emitted from the feed product exchanger such that the Heat Stable Salts, degradation products and other contaminants accumulate in the reboiler; the feed product exchanger and the reboiler in fluid communication to permit batch or semi-batch removal of Heat Stable Salts, degradation products and other contaminants from the Carbon Dioxide (CO₂) capture solvents; and, a condenser for decreasing the temperature of cleaned Carbon Dioxide (CO₂) capture solvents emitted from the feed product exchanger.

In another aspect of the present invention, there is provided a vacuum solvent reclamation system for removing Heat Stable Salts, degradation products and other contaminants from Carbon Dioxide (CO₂) capture solvents, the vacuum solvent reclamation system comprising a reboiler configured to increase the temperature of Carbon Dioxide (CO₂) capture solvents drawn from the stripper reboiler, such that the Heat Stable Salts, degradation products and other contaminants accumulate in the reboiler. The reboiler configured to permit batch or semi-batch removal of Heat Stable Salts, degradation products and other contaminants from the Carbon Dioxide (CO₂) capture solvents. The reboiler is in communication with a condenser for decreasing the temperature of cleaned Carbon Dioxide (CO₂) capture solvents emitted from the reboiler. Advantageously, the reboiler and condenser may be in direct communication.

Preferably, wherein the vacuum solvent reclamation system is in fluid communication with a system as described in any one of the paragraphs above.

In another aspect of the present invention, there is provided a process of capturing Carbon Dioxide (CO₂) from flue gases, the process comprising the steps of:

• • providing a carbon capture solvent;
  • introducing the carbon capture solvent into a Rotary Packed Bed (RPB) absorber and a Rotary Packed Bed (RPB) stripper; and, optionally, an O₂ eliminator;
  • applying steam to a reboiler;
  • bringing the carbon capture solvent in the Rotary Packed Bed (RPB) stripper to a desired pressure;
  • pumping the carbon capture solvent around the Rotary Packed Bed (RPB) absorber and the Rotary Packed Bed (RPB) stripper;
  • introducing flue gas into the Rotary Packed Bed (RPB) absorber;
  • monitoring production of Carbon Dioxide (CO₂) from the Rotary Packed Bed (RPB) stripper;
  • starting a Rotary Packed Bed (RPB) O₂ eliminator; or, a static packed bed O₂ eliminator;
  • stopping the flow of flue gas to the Rotary Packed Bed (RPB) absorber;
  • monitoring production of Carbon Dioxide (CO₂) from the Rotary Packed Bed (RPB) stripper until Carbon Dioxide (CO₂) production has stopped;
  • stopping supply of steam to the reboiler;
  • stopping circulation of the solvent;
  • stopping rotation of the Rotary Packed Bed (RPB) stripper, absorber, water wash, acid wash and O₂ eliminator.

Embodiments of the present disclosure will be described more fully hereinafter with reference to the accompanying drawings in which like numerals represent like elements throughout the several figures, and in which example embodiments are shown. Embodiments of the claims may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. The examples set forth herein are non-limiting examples and are merely examples among other possible examples.

FIG. 2 illustrates a block diagram 200 of a system for capturing Carbon Dioxide (CO₂) from flue gases. At first, flue gas 202 may be fed into a Rotary Packed Bed (RPB) absorber 204. A solvent may be fed through an inner radius of the RPB absorber 204. In the RPB absorber 204, packing may be housed in a rotatable disk. The rotatable disk could be rotated at high speed to generate centrifugal force. The centrifugal force may be exerted upon the solvent when distributed onto the packing. Upon application of the centrifugal force, the solvent may move radially from the inner radius of the RPB absorber 204 towards an outer radius of the RPB absorber 204. The solvent may thus contact with the flue gas 202 comprising CO₂, in a cross or counter-current configuration. Such rotation of the RPB absorber 204 increases mixing between the flue gas 202 and the solvent, leading to improved mass transfer of CO₂ present in the flue gas 202 to the solvent present in the liquid phase.

Once the CO₂ is absorbed into the solvent, remaining flue gas may be cleaned in one or more water wash units 206 and 208, and/or one or more acid wash units 210. In one case, packed water wash sections can be replaced with other RPB absorbers. Wash water may be fed from an inner radius of other RPB absorber and may flow radially across the packing to an outer radius of the other RPB absorber, under centrifugal force generated by rotating motion. CO₂ depleted flue gas may be introduced from the outer radius of the other RPB absorber and may flow towards the inner radius of the other RPB absorber, thereby ensuring a counter-current contact between the wash water and the CO₂ depleted flue gas. A similar process could be applied to provide an acid wash by substituting water wash media for an appropriately concentrated solution of acidic media. Cleaned flue gas 212 obtained upon washing may be vented to atmosphere.

In one embodiment, multiple RPB absorbers, i.e., a first RPB absorber and a second RPB absorber, may be used in place of the RPB absorber 204. The first RPB absorber and the second RPB absorber may have a smaller radius and may be arranged in series on a common shaft for removing the CO₂ present in the flue gas 202. The flue gas 202, a portion of whose CO₂ has been removed in a first RPB absorber, is allowed to flow from an outlet of the first RPB absorber to an inlet of a second RPB absorber. Inside the second RPB absorber, the flue gas 202 may be contacted cross or counter-currently with a lean solvent from the stripper. The flue gas 202 obtained from the second RPB absorber may be depleted of CO₂ and may be sent for a water wash before being emitted to the atmosphere. A rich solvent from the first RPB absorber may be sent to the stripper for regeneration.

In one embodiment, the solvent leaving the second RPB absorber and entering the first RPB absorber may be cooled in a heat exchanger 214 as the solvent passes from the second RPB absorber to the first RPB absorber. A solvent rich in CO₂ 216, exiting the RPB absorber 204, may be sent to an RPB oxygen eliminator 218. The flue gas 202 present inside the RPB absorber 204 may contain oxygen (O₂) which can react with the solvent to form degradation products. This results in a requirement to remove and replace the degradation products formed from the solvent. Since the size of the RPB absorber 204 and RPB stripper 226 is much smaller than a static absorber and stripper, the residence time of the solvent and gas are much shorter. Therefore, for each cycle of the process, degradation of the solvent occurs at a much lower rate.

In one embodiment, a portion of the oxygen (O₂) present in the flue gas 202 may get absorbed into the solvent present inside the RPB absorber 204. Such absorption of the O₂ is undesirable for many reasons including oxidative degradation of the solvent and O₂ contamination of product CO₂. The dissolved O₂ may be removed from the rich solvent using the RPB O₂ eliminator; or, a static packed bed O₂ eliminator; 218. In this unit operation, O₂ is stripped from the rich solvent by contacting a small slipstream of product CO₂ gas from the rich solvent stripper counter-current to the solvent. Since the partial pressure of O₂ in the product CO₂ is low, dissolved liquid O₂ present in the solvent may get transferred from the liquid solvent to the gaseous phase. A stream containing the dissolved O₂ in gaseous form 220 may be emitted from a top of the RPB O₂ eliminator 218; or, fed back to the RPB absorber 204.

The rich solvent, when it exits the RPB absorber 204, may have from 5 to 10 mg/L of oxygen dissolved in it; or, from 10 to 15 mg/L of oxygen dissolved in it. This oxygen causes degradation of the solvent in the heat exchanger 222 and RPB stripper 226. Thus, stripping O₂ from rich solvent as it exits the absorber is desired. The rich solvent flow is 12,500 lb./h or 25 gpm. The Henry's constant of O₂ at 50° C. is ˜20,000 atm/mole fraction. It is estimated that for 95% removal of O₂, a CO₂ flow of 15 lb./hr is required. The oxygen removed would be ˜0.1 lb./hr. carried away by 15 lb./hr. of CO₂.

In one embodiment, the solvent may enter the RPB O₂ eliminator 218 from a center of a packed bed which is rotating. The solvent may be pushed from the center of the rotating packed bed to the outer radius due to centrifugal forces, as described above. While the solvent leaves an edge of the packing bed, the solvent strikes a wall of the casing of the packing bed and then drains into a sump. A small portion of stripping CO₂ 240 may be fed through a penetration in the wall of the casing and passes under pressure, counter currently, from the radius of the packed bed to the center of the packed bed. A penetration may be present at the center of the packed bed. The penetration may allow the gas to leave the RPB O₂ eliminator 218. Rotation of the packed bed may cause vigorous mixing of the solvent with the stripping gas. A CO₂ rich solvent 260 may then exit the RPB O₂ eliminator 218 and may pass to a solvent heat exchanger 222.

In another embodiment, the CO₂ rich solvent may enter the conventional (static) packed bed O₂ eliminator 218 from the top of a packed bed column. A small portion of stripping CO₂ 240 may be fed from the bottom of the packed bed column. The stripping CO₂ 240 may make counter-current gas-liquid contact. A penetration may be present at the center of the packed bed. The penetration may allow the gas to leave the conventional packed bed O₂ eliminator 218. A CO₂ rich solvent 260 may then exit the conventional (static) packed bed O₂ eliminator 218 and may pass to a solvent heat exchanger 222.

Once the CO₂ rich solvent 260 is heated in the solvent heat exchanger 222 by the CO₂ lean solvent 242, a CO₂ rich solvent present at high temperature 224 may be provided to an RPB stripper 226 and a reclaimed solvent 228 may be fed back to the RPB absorber 204. The CO₂ rich solvent present at high temperature 224 may be fed into the RPB stripper 226 through an inner radius of the RPB. The RPB stripper 226 may be rotated to generate a centrifugal force exerted upon the CO₂ rich solvent present at high temperature 224 when distributed onto the packing. Due to the centrifugal force, the CO₂ rich solvent present at high temperature 224 may move radially from the inner radius of the packing towards the outer radius of the RPB. While the CO₂ rich solvent present at high temperature 224 moves from the inner radius to the outer radius, there may be a high degree of turbulent mixing and droplet formation which may increase the effective surface area for mass transfer. At the outer radius of the RPB, the CO₂ rich solvent present at high temperature 224 may be ejected and accumulated in a solvent sump via the internal wall of RPB stripper casing.

In one embodiment, solvent 230 accumulated in the solvent sump may be transferred to a reboiler 232. The solvent 230 may be heated in the reboiler 232. A temperature inside the reboiler 232 may be set to vaporize water present in the solvent 230. The water may be vaporized at an operating pressure of the RPB stripper 226. Steam formed in the reboiler 232 may be introduced to the outer radius of the RPB stripper 226.

In one embodiment, a take-off point may be present at the inner radius of the RPB stripper 226 for receiving the steam and the CO₂ out of the RPB stripper 226. The steam and the CO₂ may be transferred to a condenser 234. Inside the condenser 234, the steam present with the CO₂ may be condensed into a condensate 238, i.e., water. The water upon condensation may be separated from the CO₂ in a reflux vessel 236. Condensation of the steam in the condenser 234 may cause a pressure drop to be induced across the stripper packing. Such pressure drop may provide a driving force for the water and the CO₂ to leave the RPB stripper 226. The CO₂ may be directed to a down-stream unit 240 for down-stream processing.

In one embodiment, the condensate 238 may be mixed with the CO₂ rich solvent present at high temperature 224 before the condensate 238 enters the RPB stripper 226 via the inner radius of the packed bed. A CO₂ lean solvent 242 produced in the reboiler 232 may be returned to the process through the solvent heat exchanger 222.

FIG. 3A illustrate a block diagram 300 showing functioning of a Rotary Packed Bed (RPB) absorber 302 in a system for capturing Carbon Dioxide (CO₂) from flue gases. At first, flue gas 304 may be fed to the RPB absorber 302 and may be reacted with a solvent. The RPB absorber 302, placed on a rotatable disk, rotates and thus centrifugal force acts upon the RPB absorber 302. The solvent may thus contact the flue gas 302 comprising CO₂ in a cross or counter-current configuration. Once the CO₂ is absorbed into the solvent, remaining flue gas may be cleaned using water wash and/or acid wash.

In one embodiment, wash water may be fed through an inner radius 306 of the RPB absorber 302. The wash water may thus flow radially, across a packing of the RPB absorber 302, to an outer radius of the RPB absorber 302, under the action of the centrifugal force. During the water wash, CO₂ depleted flue gas to be processed may be introduced from the outer radius of the RPB absorber 302 and may flow towards the inner radius 306, thereby ensuring a counter-current contact between the wash water and the CO₂ depleted flue gas. Similarly, a concentrated solution of acidic media may be used for providing the acid wash to the CO₂ depleted flue gas. Successive to the water wash and the acid wash, cleaned CO₂ depleted flue gas 308 may be vented.

In one embodiment, multiple RPB absorbers, i.e., a first RPB absorber and a second RPB absorber, may be used in place of the RPB absorber 302. The first RPB absorber and the second RPB absorber may have a smaller radius and may be arranged in series on a common shaft for removing the CO₂ present in the flue gas 304 The flue gas 304 a portion of whose CO₂ has been removed in a first RPB absorber, is allowed to flow from an outlet of the first RPB absorber to an inlet of a second RPB absorber. Inside the second RPB absorber, the flue gas 304 may be contacted cross or counter-currently with a lean solvent from the stripper. The flue gas 304 obtained from the second RPB absorber may be depleted of CO₂ and may be sent for water wash before being emitted to the atmosphere. A rich solvent from the first RPB absorber may be sent to the stripper for regeneration.

In one embodiment, solvent rich in CO₂ 310, exiting the RPB absorber 302, may be sent to an RPB O₂ eliminator 312. A portion of oxygen (O₂) present in the flue gas 304 may get absorbed into the solvent present inside the RPB absorber 302 Such absorption of the oxygen (O₂) is undesirable for reasons stated above. The oxygen (O₂) may be removed from the rich solvent using the RPB O₂ eliminator 312. Since the partial pressure of O₂ in the product CO₂ is low, liquid dissolved O₂ present in the solvent may get transferred to a gaseous phase. A stream 314 may be emitted from a top of the RPB O₂ eliminator 312. Successively, a CO₂ rich solvent 316 may then exit the RPB deaerator 312 and may be provided to a solvent heat exchanger 318.

Once the CO₂ rich solvent 316 is heated in the solvent heat exchanger 318 by the CO₂ lean solvent 350, a CO₂ rich solvent present at high temperature 320 may be provided to an RPB stripper 322. A cooled CO₂ lean solvent 324 to the RPB absorber 302 upon processing. The CO₂ rich solvent present at high temperature 320 may be fed into the RPB stripper 322. The RPB stripper 322 may be rotated to generate a centrifugal force exerted upon the CO₂ rich solvent present at high temperature 320 when distributed onto the packing. Due to the centrifugal force acting upon the RPB stripper 322, the CO₂ rich solvent present at high temperature 320 may be ejected and accumulated in a solvent sump via the internal wall of RPB stripper casing.

In one embodiment, solvent 328 accumulated in the solvent sump may be transferred to a reboiler 330. The solvent 328 may be heated in the reboiler 330. Steam formed in the reboiler 330 may be introduced to an outer radius of the RPB stripper 322. A take-off point may be present at an inner radius of the RPB stripper 322 for receiving the steam and CO₂ out of the RPB stripper 322. The steam and the CO₂ may be transferred to a condenser for condensing the steam present with the CO₂ into a condensate. The water upon condensation may be separated from the CO₂. Condensation of the steam in the condenser may cause a pressure drop to be induced across the stripper packing. Such pressure drop may provide a driving force for the water and the CO₂ to leave the RPB stripper 322. The CO₂ 332 separated from the water may be directed for down-stream processing with a small portion of the CO₂ 332 may be fed into O₂ eliminator 312.

In one embodiment, the cooled CO₂ lean solvent 324 may pass to the RPB absorber 302 via a thermal reclaimer 326.

FIG. 3B illustrate a block diagram 3000 showing functioning of a Rotary Packed Bed (RPB) absorber 3020 in a system for capturing Carbon Dioxide (CO₂) from flue gases In one embodiment, as an alternative to the configuration of FIG. 3A, the thermal reclaimer 3260 may be positioned on a connecting point between the stripper reboiler 3300 and the solvent heat exchanger 3180. In one embodiment, the solvent heat exchanger 3180 and RPB absorber 3020 are in direct communication. The other components of the block diagram 3000 correspond to the components of the FIG. 3A with a “0” added at the end of the respective reference number, e.g. 312 in FIG. 3A is 3120 in FIG. 3B etc.

In one embodiment, Lean Solvent 402 from lean solvent cooler outlet may be taken into a vacuum solvent reclamation system, as shown in block diagram 400 of FIG. 4A. The thermal vacuum solvent reclamation system may be operated to remove Heat Stable Salts (HSS), degradation products, and other contaminants from the solvent while the concentrations are more than 2 wt. %. The vacuum solvent reclamation system may include an input of the lean solvent 402 fed to a feed product exchanger 404. The feed product exchanger 404 increases temperature of the mixture from 40° C. to 165° C. by heating with vapors 412 from Reboiler 408.

The lean solvent 406 from the feed product exchanger 404 may then be passed to a reboiler 408. The reboiler 408 may cycle thermic fluid in and out and may increase the temperature of the solvent from 165° C. to 180° C. Sodium Hydroxide may be added in Reboiler 408 to liberate carbon capture solvent from heat stable salts and degradation products. In an embodiment, Residue 410 at the end of operation may be sent to an incinerator for disposal. Vapor components 412 of the mixture via the feed product exchanger 404 may be provided to a condenser 416. The vapor components 412 may be condensed into a liquid 418 before being sent to an absorber. The thermal reclaiming system may be operated in semi-batch mode allowing the HSS and impurities to accumulate in the reboiler 408. After the batch completion, water may be added in Reboiler 408 when the liquid level is low in order to facilitate the withdrawal of residue 410.

In another embodiment, Lean Solvent 4020 from a lean solvent pump discharge may be taken into a vacuum solvent reclamation system, as shown in block diagram 4000 of FIG. 4B. The temperature of the Lean Solvent 4020 may be 120° C. The thermal vacuum solvent reclamation system may be operated to remove Heat Stable Salts (HSS), degradation products, and other contaminants from the solvent while the concentrations are more than 2 wt. %. The vacuum solvent reclamation system may include an input of the lean solvent 4020 fed to a Reboiler 4080.

The reboiler 4080 may circulate thermic fluid and may increase the temperature of the solvent from 120° C. to 180° C. Sodium Hydroxide 4200 may be added in Reboiler 4080 to liberate solvent from Heat Stable Salts and degradation products. In an embodiment, demineralized water 4220 may be added in Reboiler 4080. In an embodiment, medium pressure steam 4240 may be added to Reboiler 4080 and medium pressure steam 4260 may be removed from Reboiler 4080. Residue 4100 at the end of operation may be sent to an incinerator for disposal. Vapor components 4120 of the mixture may pass to a condenser 4160. In an embodiment, cooling water 4300 may be added to condenser 4160 and cooling water 4320 may be removed from condenser 4160. The vapor components 4120 may be condensed into a liquid 4180 before being sent as treated solvent to an absorber via a heat exchanger (not shown). The vapor components 4120 may be sent to an absorber via a vacuum pump 4280. The thermal reclaiming system may be operated in semi-batch mode allowing the HSS and impurities to accumulate in the reboiler 4080. After the batch completion, water may be added in Reboiler 4080 when the liquid level is low in order to facilitate the withdrawal of residue 4100.

An inherent advantage of using RPB strippers compared to the static bed stripper columns is increased mixing in the RPB strippers that results in better mass transfers of CO₂ from liquid to a gaseous phase. This enables utilization of an RPB stripper of much smaller size than a conventionally used stripper. Further advantages of utilizing the system and the process for capturing Carbon Dioxide (CO₂) from flue gases may include: lower energy requirement to capture unit mass of CO₂ due to less water in solvent, smaller and lower capital cost carbon capture plant due to higher rates of mass transfer, lower solvent degradation and make-up requirement due to shorter exposure to oxygen, lower energy requirements to capture unit mass of CO₂ due to inter-stage cooling increasing the CO₂ loading into the solvent, and lower solvent degradation and make-up requirements due to more uniform temperature profile in RPB absorber, shorter solvent residence time in the RPB absorber and RPB stripper.

Further advantages of utilizing the system and the process for capturing Carbon Dioxide (CO₂) from flue gases may include: smaller size and hence lower capital cost for water wash and acid wash, reduced capital cost by mounting the RPB, absorber, water wash, acid wash, and stripper on a single shaft, lower capital cost of oxygen eliminator, lower formation of aerosols due to removal of temperature bulge in RPB absorber, and utilization of vacuum thermal reclaimer and hence less degradation and high recovery of the solvent.

FIG. 5 illustrates a flowchart 500 of a process of capturing Carbon Dioxide (CO₂) from flue gases, according to an embodiment. FIG. 5 comprises a flowchart 500 that is explained in conjunction with the elements disclosed in FIG.s explained above.

The flowchart 500 of FIG. 5 shows the architecture, functionality, and operation for capturing Carbon Dioxide (CO₂) from flue gases. It should also be noted that in some alternative implementations, the functions noted in the blocks may occur out of the order noted in the drawings. For example, two blocks shown in succession in FIG. 5 may, in fact, be executed substantially concurrently or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. In addition, the process descriptions or blocks in flow charts should be understood as representing decisions made by a hardware structure such as a state machine. The flowchart 500 starts at step 502 and proceeds to step 526.

At step 502, recirculation of wash water and acid water may be started in the process. At step 504, rotation of an RPB absorber and an RPB stripper may be started. Further, the presence of liquid solvent in a reboiler and an absorber sump may be ensured at step 506. Steam may be applied to the reboiler and stripper pressure may be allowed to reach a set point pressure at step 508. Recirculation of lean and rich solvent recirculation pumps may be started at step 510. The flow of flue gas may be started into the process at step 512. Production of CO₂ from the RPB stripper may be monitored at step 514. Thereafter, RPB O₂ eliminator may be started while product CO₂ is available from the RPB stripper at step 516. The flow of the flue gas may be stopped at step 518. It may wait until production of the product CO₂ stops at step 520. Supply of steam to the reboiler may be stopped at step 522, and recirculation of solvent may be stopped at step 524. Finally, rotation of the RPB stripper, RPB absorber, water wash, acid wash, and O₂ eliminator may be stopped at step 526.

FIG. 6 illustrates a block diagram 600 representation of a Rotary Packed Bed Absorber test rig, according to an embodiment. The Rotary Packed Absorber test rig allows for the testing of solvents under various conditions, and allows temperature and flow to be measured at critical locations. A simulated flue gas is created by mixing CO₂ 602 with air 610 via mass flow controller 604 and mass flow controller 612, respectively. The simulated flue gas is fed into humidifier 606 which has a supply of hot water 614. The temperature of the simulated flue gas post humidifier 606 is measured and controlled by temperature measurement and controller 616. The simulated flue gas may then be fed into Rotary Packed Bed Absorber 626. The Rotary Packed Bed Absorber has an inner diameter of 0.08 meters and an outer diameter of 0.3 meters, providing a radial packed depth of 0.11 meters. The length of the packed bed along the axis of rotation is 0.02 meters. The Rotary Packed Bed Absorber 626 is housed in a poly propylene case with an internal diameter of 0.36 meters. The Rotary Packed Bed Absorber 626 is driven by a synchronous electric motor with a maximum speed of 3000 rpm.

Rotary Packed Bed Absorber 626 is fed solvent from amine feed tank 608, where the solvent is heated by hot water system 622 at location 620 of the amine feed tank 608 using circulated hot water. The flow of the solvent from amine feed tank 608 is measured at flow measurement 618 and the temperature of the solvent from amine feed tank 608 is measured at temperature measurement 628. The temperature of the gas out 632 from the Rotary Packed Bed absorber 626 is measured by temperature measurement 630. The temperature of the amine out 636 is measured by the temperature measurement 634.

EXAMPLES

Example 1: Determining the Operating Conditions for a Range of Solvents

In this example, the operating conditions for a range of solvents were determined. Table 1 shows the operating conditions for the solvents.

CO₂ absorption was measured for a range of solvent flow rates and speeds of rotation. The range of the parameter settings is shown in Table 1.

TABLE 1
The range of parameter settings for a range of solvents.
		Speed of rotation	Liquid to gas
	Solvent	rpm	ratio kg/kg
	30 wt. % Mono Ethanol Amine	600-450	2.8-3.7
	90 wt. % Mono Ethanol Amine	600-1150	0.9-1.2
	43 wt. % CDRMax	600-1150	1.8 2.5
	55 wt. % CDRMax	600-1450	1.5-2.4
	43 wt. % CDRMax second pass	600-1150	1.8-2.5

For each test the inlet CO₂ 602 was constant at 12 mol. %, which is a similar concentration to coal flue gas, and the temperature of the liquid solvent was 40° C. The liquid to gas ratio is a critical parameter for a carbon capture process, as absorbers show higher performance with an increased liquid flow rate until the absorber reaches its flooding point. An optimum flow rate may be found by considering the increased stripper duty required with increased amounts of solvent, which may be only lightly load with CO₂. The increased stripper duty increases the necessary energy to perform the carbon capture process. The test results shown in Table 1 allow for the calculation of the number of transfer units required (NTU_OG). From the results on 30 wt. % MEA with a speed of rotation of 600 rpm and an L/G of 3.3, the inlet CO₂ was 12.1% and the outlet CO₂ was 9.1%. Therefore, the number of transfer units required is:

${\mathrm{NTU}}_{\mathrm{OG}}=\ln \frac{12.1}{9.1}=0.28$ Further, the Packed Height is equal to the overall gas phase Height of a Transfer Unit (HTU_OG) multiplied by the Number of Overall Gas phase transfer Units (NOG). Given that the radius of the test apparatus was 0.11 m, the H=0.11 meters, and the NTU=0.28, the height of overall gas phase transfer unit is:

${\mathrm{HTU}}_{\mathrm{OG}}=\frac{r_o-r_i}{{\mathrm{NTU}}_{\mathrm{OG}}}=\frac{0.11}{0.28}=0.39m$

The height of a gas transfer unit was found to be 0.39 meters. This shows a significant reduction in size of a gas phase transfer unit for a Rotary Packed Bed absorber compared to a static bed absorber. Table 2 shows the test results from five solvent trails, according to an embodiment.

TABLE 2
Test results from five solvent trials.
				43 wt %
		90		CDRMax
	30 wt.	wt.	43 wt %	Solvent
	%	%	CDRMax	Second	55 wt %
Solvent	MEA	MEA	Solvent	pass	CDRMax
L/G (Liquid flow	3.30	1.10	2.20	2.20	1.90
rate to gas flow
rate ratio)
NTU	0.28	0.71	0.35	0.27	0.51
HTU	0.39	0.15	0.32	0.40	0.22
Area of TU/m2	0.23	0.09	0.19	0.24	0.13
NTU required	2.30	2.30	2.30	0.23	2.30
Scale factor for 90%	8.22	3.24	6.58	8.53	4.51
removal
Method 1-	Radius	0.90	0.36	0.72	0.94	0.50
radius	Required/m
basis
Method 2-	Area	1.93	0.30	1.23	2.07	0.58
area basis	Required/
	m2
	Ro/m	0.82	0.35	0.67	0.85	0.47
	Ri/m	0.04	0.04	0.04	0.04	0.04
	Ro-Ri/m	0.78	0.31	0.63	0.81	0.43
MEA = Mono Ethanol Amine, TU = transfer units, NTU = number of transfer units

For each solvent a range of liquid to gas ratio and speed of rotation were tested. The testing provides a method for determining the size of rotary packed bed absorber required for a 90% CO₂ capture at 600 rpm.

Example 2: Determining Operating Parameters Required to Maximize Recovery of Solvents by Simulating the Vacuum Thermal Reclaimer

In this example, Table 3 illustrates the experimental results of a vacuum thermal reclaimer system. A sample of solvent from an operating CO₂ capture plant was reclaimed in an experimental setup. The recoveries achieved are shown in Table 3. Furthermore, simulations were performed for sensitivity analysis and optimize the operating parameters to maximize the recovery and minimize the energy requirement.

TABLE 3
Experimental results of a vacuum thermal reclaimer system.
Vacuum Thermal Reclaimer Experimental Results
		Inlet	Recovered
Parameters	UOM	Solvent	Solvent	Residue	Recovery
Total Sample	wt %	100	98.1	1.9	98.1%
CDRMax	wt %	99.4	98.1	1.3	98.6%
Heat Stable Salts	wt %	0.6	0.0	0.6	0.0%
UOM = unit of measurement

In this example, the operating parameters required to maximize the recovery of the solvent CDRMax was determined using a vacuum thermal reclaimer simulation. Table 4 illustrates a table showing the Vacuum Thermal Reclaimer Simulation Results, according to an embodiment. The optimum case results at a temperature of 165° C. and 0.75 bar(a) are tabulated in the table illustrated by Table 4.

TABLE 4
The vacuum thermal reclaimer simulation results.
		Inlet	Recovered		Recovery,
Parameters	UOM	Solvent	Solvent	Residue	%
Total Flow	kg/hr	5235.9	4935.2	143.8	94.3%
CO2	kg/hr	157	157	0	100%
CDRMax	kg/hr	4999.7	4935.2	64.6	98.7%
Heat Stable Salts	kg/hr	79.2	0	79.2	0.0%
UOM = Unit of measurement

Example 3: The Relationship of CO₂ in the Vapor Phase and the Loading (i.e. Concentration) of CO₂ in a Solvent at 40° C.

In this example, the relationship between CO₂ in the vapor phase and the loading (i.e. concentration) of CO₂ in a solvent at 40° C. was determined. FIG. 7 illustrates a graph showing vapor liquid equilibrium (VLE) relationship between partial pressure of CO₂ in the vapor phase and the loading (i.e. concentration) of CO₂ in a solvent at 40° C.

Example 4: Viscosity of Unloaded CO₂ Solvent and Loaded CO₂ Solvent

In this example, the viscosity of an unloaded CO₂ solvent and loaded CO₂ solvent was determined. Table 5 shows unloaded (no CO₂) solvent viscosity and CO₂ loaded solvent viscosity at 40° C.

TABLE 5
The viscosity of CO2 loaded and unloaded (no CO2) solvents.
		CO2 loaded Viscosity,
	Unloaded	cP @40 C.
	Viscosity,	CO2 loading,	Viscosity,
Solvent	cP @40 C.	mol/L	cP
40% DEEA + 10% AEP	4.472	2.000	12.59
10% AHPD + 10% AEP	1.370	0.597	1.78
10% AEPD + 10% AEP	1.470	0.658	1..86
30% AEPD + 15% AEP	3.759	2.020	8.77
30% AHPD + 15% AEP	4.004	2.050	10.62

In Table 5, the components are given in weight %. The balance in each case is demineralised water.

DEEA=2-(diethylamino)ethanol

AHPD=2-amino-2-hydroxymethyl-1,3-propanediol

AEPD=2-amino-2-ethyl-1,3-propanediol

AEP=2-piperazine-1-ethylamine

Example 5: Methodology of Sizing for RPB Scale Up

In this example, a design of a RPB that allows for a target of 10 tons of CO₂ capture per day from a “coal style” flue gas that contains 10 vol. % CO₂ at a capture rate of 90% was determined.

In this example, using empirical relationships, the inner diameter (d_i), outer radius (r_o), inner radius (r_i) and axial length (z) of an RPB are determined. The parameters are then used to determine the cross-sectional area and total volume of the RPB required.

In this example, the inner diameter (d_i) of the RPB was sized to include room for the liquid distribution mechanism, whilst avoiding liquid entrainment and excessive gas velocities during operation of the RPB.

In this example, the axial length (z) was determined to give the minimum permissible sizing whilst allowing sufficient packing volume for the required amount of mass transfer to take place without incurring flooding.

In conventional static systems the Height of the packing (H) required for the specified degree of mass transfer is determined by the following expression. Where the Height of the packing (H) is the product of the overall gas phase Height of a Transfer Unit (HTU_OG) and the Number of Transfer Units for the gas phase (NTU_OG):H=NTU_OGHTU_OG

In RPB applications the packing requirements differ from conventional static columns, as they are not linear with respect to height of the packing. Instead, an analogy is used where

the cross-sectional area of the packing (π(r_o²−r_i²)) is equivalent to Height of the packing (H) in a conventional system. This is expressed in relation to the overall gas phase Area of a Transfer Unit (ATU_OG) and the overall Number of Transfer Units for the gas phase (NTU_OG) in the following equation:π(r_o²−r_i²)=NTU_OGATU_OG

To determine the cross-sectional area of the packing ((π(r_o²−r_i²)), both NTU_OG and ATU_OG must be known and can be derived experimentally using the following expressions, where y_in is the inlet mole fraction of the component to be absorbed; y_out is the outlet mole fraction of the component to be absorbed; Q_G is the volumetric gas flow; z is the axial length of the RPB and K_Ga is the gas phase mass transfer coefficient:

${\mathrm{NTU}}_{\mathrm{OG}}=\ln \frac{y_{\mathrm{in}}}{y_{\mathrm{out}}}$ ${\mathrm{ATU}}_{\mathrm{OG}}=\frac{Q_G}{{\mathrm{zK}}_{G}a}$

In this example, the solvent trials were carried out with a prototype RPB absorber. A lean solvent with a CO₂ concentration of 0.1 mole of CO₂ per mole of solvent alkalinity was used to simulate the expected conditions in a real CO₂ capture plant. This resulted in gas phase mass transfer coefficients that were measured in conditions representative of an operational CO₂ capture plant.

In the solvent trials for this example, the gas phase mass transfer coefficients had to be calculated. The cross-sectional area, axial length, volumetric gas flow were already known, and the inlet mole fraction of CO₂ in the gas (y_in) and outlet mole fraction of CO₂ in the gas (y_out) were both measured.

In this example, by using the K_Ga value for a solvent of interest allows the scaling of the radial depth to achieve 90% CO₂ capture from a 10 vol. % CO₂ flue gas.

Example 6: Size of RPB to Capture 1 Ton Per Day CO₂

In this example, the size of a RPB that allows for a target of 1 ton of CO₂ capture per day from a flue gas.

TABLE 6
Size parameters of a RPB that captures 1 ton of CO2 per day
from a flue gas that contains 10 vol. % CO2 at a capture rate of 90%.
Technology	RBP
	Radius	Axial Length	Volume
Vessel	m	m	m3
RPB Absorber	0.574	0.064	0.033
RPB Stripper	0.144	0.024	0.002

Table 6 shows that the dimensions of the RPB absorber and stripper are all less than one meter. The RPB absorber and stripper are relatively small and compact.

Example 7: Design of RPB to Capture 10 Tons of CO₂ Per Day

In this example, the design of a RPB that allows for a target of 10 tons of CO₂ capture per day from a flue gas that contains 10 vol. % CO₂ at a capture rate of 90% was determined.

FIG. 8 illustrates a system for capturing CO₂ 1200. The system for capturing CO₂ 1200 can be used to capture 10 tons of CO₂ per day. The solid lines in FIG. 8 depict the path of liquids, whilst the dashed lines depict the path of gases.

In this example, flue gas 1201 enters the system 1200 through inlet 1201. In one example, the flue gas 1201 contains 10 vol. % CO₂ and is at a temperature of 140° C. The flue gas upon entering system 1200 may pass through a fan 1202. The fan 1202 may be required to overcome the pressure drop in the ductwork as well as the downstream process.

In this example, two operations may be carried out in the system for capturing CO₂ 1200.

In the first unit operation, the flue gas 1201 may be cooled in a Direct Contact Cooler (DCC) 1203 by using a loop of water that passes through DCC drum 1204, DCC recirculating pump 1205 and a heat exchanger/DCC cooler 1206. The DCC 1203 may be a RPB. The water may be cooled in a heat exchanger/DCC cooler 1206. Any excess condensate from the flue gas 1201 may be purged via outlet 1207.

The second unit operation may be a SO_x column 1208, which may be used to remove acid gas species such as SO_x and NO_x via an alkali wash. The SO_x column 1208 may be a RPB. A recirculating loop of water passes through SO_x drum 1209, SO_x recirculating pump 1210 and SO_x cooler 1211. The water may be dosed with an alkali 1212 by using a dosing pump 1213. The water may contact the flue gas 1201 in the SO_x column 1208. Excess liquid may be purged from the loop via outlet 1214.

In this example, the flue gas 1201 may then pass into a Carbon Capture Absorber vessel 1215. The Carbon Capture Absorber vessel 1215 may be a RPB. The flue gas 1201 may be contacted with a counter current carbon capture solvent. The Carbon Capture Absorber 1215 has two stages of packing in which the flue gas 1201 and carbon capture solvent are contacted. Between the two stages of packing, the temperature of the carbon capture solvent may be controlled by an intercooling heat exchanger composed of an intercooling exchanger 1218, intercooling pump 1217 and intercooling drum 1216. The flue gas 1201, which may now be depleted of CO₂, leaves the Carbon Capture Absorber and passes to a Water Wash vessel 1219. The Water Wash vessel 1219 may be a RPB. The carbon capture solvent, which may now be rich in CO₂, may leave the Carbon Capture Absorber via a Rich Solvent Drum 1220; from the Rich Solvent Drum 1220 the carbon capture solvent enters an O₂ eliminator 1222 via a Rich Booster Pump 1221.

In this example, the CO₂ depleted flue gas 1201 may enter the Water Wash vessel 1219. In the Water Wash vessel 1219, the CO₂ depleted flue gas 1201 may be contacted with two recirculating loops of water across two stages of Water Wash packing 1223 and 1226, which are configured in series. Each loop of water 1223 and 1226 is circulated with a wash water pump 1224 and 1227 and cooled in a heat exchanger 1225 and 1228 before being returned to the Water Wash vessel 1219. The treated flue gas 1201 may then pass out of outlet 1229.

In this example, the CO₂ rich carbon capture solvent enters the O₂ eliminator 1222. The O₂ eliminator 1222 may be a RPB. In the O₂ eliminator 1222, the CO₂ rich carbon capture solvent may be contacted with a flow of carbon dioxide. The CO₂ and entrained oxygen may then be returned to the Absorber 1215. The carbon capture solvent, which has had oxygen removed, may be pump through a Surge Drum 1230, Rich Solvent Pump 1231 and a Cross-over Heat Exchanger 1232 into the Stripper vessel 1233. A lean cooler 1242 may be positioned between the Cross-over Heat Exchanger 1232 and the Absorber 1215.

In this example, vapor which is generated in a reboiler 1238 may be fed into the Stripper vessel 1233 and used to heat and strip the CO₂ from the carbon capture solvent. The Stripper vessel 1233 may be a RPB. A vapor, comprised of steam, vaporized solvent components and CO₂ gas, from the Stripper vessel 1233 enters the Reflux Exchanger 1234 where it may be reduced in temperature from 120° C. to 40° C. This causes steam and solvent components to condense into the liquid phase. The stream then passes into the reflux tank 1235 where the gaseous CO₂ disengages from the liquid components. The liquid components are then returned as reflux into the carbon capture solvent inventory. The liquid reflux may be pumped by the Reflux Pump 1236 to the Stripper vessel 1233 while the CO₂ passes out of the Reflux Exchanger via outlet 1237 as a pure (>95%) stream of CO₂. A slipstream of the pure (>95%) stream of CO₂ is returned to the O₂ eliminator 1222 where it acts as a purge gas in an O₂ elimination process.

In this example, the operating pressure of the stripper vessel was 1 bar(g) and the steam that entered the reboiler had an operating pressure of 3.5 bar(g) (saturated). The design pressure of the Stripper, Reboiler, Reflux Exchanger, Reflux Tank, Steam & Condensate system was 10 bar(g).

In this example, the carbon capture solvent (that no longer contains CO₂) leaves the Stripper vessel 1233 via the reboiler 1238 where it may be pumped using the Lean Solvent Pump 1239 through the Cross-over Heat Exchanger 1232 and back into the Carbon Capture Absorber vessel 1215 via a lean cooler 1242.

In this example, the DCC 1203, SO_x column 1208 and the Water Wash 1219 may be situated on separate RPB shafts.

Example 8: Sizing RPB Process Equipment

In this example, process simulation software, such as ProTreat™ (as provided by Optimized Gas Treating, Inc.), was used to size conventional static technology and then the methodology of example 5 was used to size the RPB equipment.

Table 7 illustrates the comparative process equipment dimensions for a RPB and conventional static technologies that can capture 10 tons of CO₂ per day from a 10 vol. % CO₂ flue gas source.

TABLE 7
comparative process equipment dimensions for a RPB and conventional
static technologies that can capture 10 tons of CO2 per day from a 10
vol. % CO2 flue gas source.
	RPB	Conventional (static)
		Axial				Vol-
Technology	Radius	Length	Volume	Diameter	Height	ume
Type Vessel	m	m	m3	m	m	m3
DCC	0.52	0.34	0.28	0.72	5.00	2.04
SO2 Absorber	0.32	0.29	0.10	0.72	5.00	2.04
CO2 Absorber	0.72	0.23	0.38	0.67	12.00	4.23
O2 Eliminator	0.72	0.23	0.38	N/A	N/A	N/A
Stripper	0.25	0.23	0.05	0.43	8.00	1.16
Water Wash	0.56	0.57	0.55	0.63	6.00	1.87

Table 7 shows comparative data for the equipment dimensions of a RPB and a conventional static equivalent technology. Table 7 shows that the volume of the packing required to achieve 90% CO₂ capture for the RPB process equipment is reduced by, or close to, an order of magnitude.

Example 9: Sizing Auxiliary Process Equipment Used in RPB Containing System

In this example, process simulation software, such as ProTreat™ (as provided by Optimized Gas Treating, Inc.), was used to size auxiliary process equipment used in an RPB containing system according to example 8.

Tables 8, 9 and 10 illustrate the equipment dimensions for a RPB technology that can capture 10 tons of CO₂ per day from a 10 vol. % CO₂ flue gas source. In the tables, the specification of the pumps, fans, heat exchangers and tanks required for such a plant is shown.

TABLE 8
Specification parameters of pumps and fans for RPB technology.
			Operating	Discharge		Material
		Capacity	Temperature	Pressure	Power	of
Name	Type	m3 hr−1	° C.	bar(a)	kW	construction
DCC Recirc.	Centrifugal	14.8	N/A	4.3	2.35	304 SS
Pump
SOx Recirc.	Centrifugal	14.8	43	4.3	2.35	304 SS
Pump
Rich Solvent	Centrifugal	5.6	46	5.8	1.2	304 SS
Pump
Lean Solvent	Centrifugal	6	120	4.4	0.95	304 SS
Pump
Gas Booster	Centrifugal	3,700	150	0.13	17	304 SS
Fan				(dP)
Water Wash	Centrifugal	5.1	60	2.7	0.51	304 SS
Recirc. Pump 1
Water wash	Centrifugal	6.1	40	3.2	0.74	304 SS
Recirc. Pump 2
Water wash	Centrifugal	0.23	40	2.0	0.02	304 SS
condensate
Pump
Steam	Centrifugal	0.7	140	3.3	0.1	304 SS
Condensate
Pump
Reflux Pump	Centrifugal	0.28	120	3.4	0.04	304 SS
Solvent Makeup	Centrifugal/	0.2	Ambient	1.8	0.01	304 SS
	PD pump
Alkali Dosing	Centrifugal	0.2	Ambient	1.8	0.01	304 SS
Pump
Rich Booster	Centrifugal	5.6	46	2	0.5	304 SS
Pump
Intercooling	Centrifugal	4.6	55	2.7	0.46	304 SS
Pump

TABLE 9
Specification parameters of heat exchangers for RPB technology.
		Heat	Design
		Duty	Pressure
Name	Type	MJ hr−1	bar(g)	MoC
DCC Cooler	Plate and Frame	950	3.0	SS304 L
SOx Cooler	Plate and Frame	172	3.0	SS304 L
Intercooling Exchanger	Plate and Frame	239	4.5	SS304 L
Cross-over HX	Plate and Frame	1372	5.0	SS316 L
Reflux Exchanger	Shell and Tube	580	2.0	SS304 L
Lean Cooler	Plate and Frame	183	4.5	SS304 L
Water Wash Cooler 1	Plate and Frame	252	3.5	SS304 L
Water Wash Cooler 2	Plate and Frame	308	3.5	SS304 L
Stripper Reboiler	Kettle Type	1560	1.0	SS316 L

TABLE 10
Specification parameters of tanks for RPB technology.
		Operating	Operating
	Volume	Temperature	Pressure
Name	m3	° C.	bar(g)	MoC
DCC Drum	0.3	56	0	304 SS
SOx Drum	0.3	44	0	304 SS
Intercooling Drum	0.09	61	0	304 SS
Rich Solvent Drum	0.12	46	0	304 SS
WW Drum 1	0.1	58	0	304 SS
WW Drum 2	0.12	50	0	304 SS
Surge Drum	0.12	46	0	304 SS
Reflux Tank	0.12	120	1	304 SS
Solvent Storage	2.60	40	0	304 SS
Tank
Steam Condensate	N/A	N/A	N/A	CS + 1.5
Drum				mm CA

The present application shows that the volume of the packing required to achieve 90% CO₂ capture for the RPB process equipment is reduced by, or close to, an order of magnitude. This is beneficial at least because of the reduction in capital expenditure and reduction in size in providing the same or a greater CO₂ capture capability. Utilising RPBs as described in the present application provides benefits over known systems.

Although the present disclosure and its advantages have been described in detail, it should be understood that various changes, substitutions, and alterations can be made herein without departing from the disclosure as defined by the appended claims. Moreover, the scope of the present application is not intended to be limited to the particular embodiments of the process, machine, manufacture, composition of matter, means, methods and steps described in the specification. As one will readily appreciate from the disclosure, processes, machines, manufacture, compositions of matter, means, methods, or steps, presently existing or later to be developed that perform substantially the same function or achieve substantially the same result as the corresponding embodiments described herein may be utilized. Accordingly, the appended claims are intended to include within their scope such processes, machines, manufacture, compositions of matter, means, methods, or steps.

When used in this specification and claims, the terms “comprises” and “comprising” and variations thereof mean that the specified features, steps or integers are included. The terms are not to be interpreted to exclude the presence of other features, steps or components.

The features disclosed in the foregoing description, or the following claims, or the accompanying drawings, expressed in their specific forms or in terms of a means for performing the disclosed function, or a method or process for attaining the disclosed result, as appropriate, may, separately, or in any combination of such features, be utilised for realising the invention in diverse forms thereof.

Claims

1. A system for capturing Carbon Dioxide (CO2) from flue gases, the system comprising: at least one Rotary Packed Bed Direct Contact Cooler (RPBDCC);at least one Rotary Packed Bed (RPB) absorber configured to rotate circularly and located downstream of the at least one Rotary Packed Bed Direct Contact Cooler (RPBDCC), wherein when the RPB rotates circularly a solvent provided through an inner radius of the at least one RPB absorber moves towards an outer radius of the at least one RPB absorber, and wherein the solvent reacts with flue gas in a counter-current flow to capture CO2; anda Rotary Packed Bed O2 eliminator that removes dissolved O2 from the CO2 rich solvent leaving the at least one RPB absorber.

2. The system of claim 1, wherein the system further comprises at least one of: components for thermally regenerating the solvent reacted with the CO2 for re-utilizing the solvent in the process; andone or both of a water wash and an acid wash, wherein passing the flue gas through one or both of the water wash and the acid wash removes traces of the solvent present in the flue gas.

3. The system of claim 1, wherein a housing of the RPB is mounted on a rotatable disk.

4. The system of claim 1, wherein the system comprises two, three, four, five or six RPB absorbers configured to rotate circularly.

5. The system of claim 4, wherein the two, three, four, five or six RPB absorbers configured to rotate circularly are arranged in series on a common shaft.

6. The system of claim 1, wherein the solvent reacts with the flue gas in a counter-current flow to remove CO2 from the flue gas and form CO2 rich solvent.

7. The system of claim 6, further comprising: a stripper, wherein the stripper is configured to strip CO2 from the CO2 rich solvent forming CO2 lean solvent.

8. The system of claim 7, wherein at least one of: the stripper is Rotary Packed Bed stripper, and the system is configured to re-introduce the CO2 lean solvent into the at least one Rotary Packed Bed (RPB) absorber rotating circularly.

9. The system of claim 1, wherein the Rotary Packed Bed O2 eliminator is configured to eliminate 90% or more of the O2 present in the CO2 rich solvent.

10. The system of claim 1, wherein each RPB has the following dimensions: radius: from 0.2 m to 1.25 m,axial length: from 0.02 m to 1.0 m, andvolume: from 0.04 m3 to 4.9 m3.

11. The system of claim 1, wherein each RPB has the following dimensions: radius from 0.2 m to 0.8 m,axial length from 0.2 m to 0.6 m, andvolume from 0.04 m3 to 0.6 m3.