초록 ▼

A system and method for calcination/carbonation cycle processing. The system comprises a calciner reactor for receiving partially carbonated mineral sorbent granules; a heat exchange structure for transferring heat through a wall of the calciner reactor to a granular flow of the sorbent granules for

A system and method for calcination/carbonation cycle processing. The system comprises a calciner reactor for receiving partially carbonated mineral sorbent granules; a heat exchange structure for transferring heat through a wall of the calciner reactor to a granular flow of the sorbent granules for facilitating a calcination reaction of the sorbent granules to regenerate the sorbent granules; a gas extraction unit for removing gas products from the calciner, wherein the gas products comprise carbon dioxide from the calcination reaction; a carbonator reactor for receiving the regenerated sorbent granules from the calciner reactor and for receiving a cold flue gas, such that the regenerated sorbent granules are partially carbonised while the flue gas is scrubbed and the partially carbonated sorbent granules and the scrubbed flue gas exit the carbonator reactor as respective hot materials; and a riser unit for cycling the partially carbonated sorbent granules from the carbonator reactor to the calciner reactor.

대표청구항 ▼

1. A system for calcination/carbonation cycle processing, the system comprising: mineral sorbent granules having a size distribution between about 40 microns and about 125 microns;A calciner reactor for receiving the mineral sorbent granules in a partially carbonated state, the calciner reactor bein

1. A system for calcination/carbonation cycle processing, the system comprising: mineral sorbent granules having a size distribution between about 40 microns and about 125 microns;A calciner reactor for receiving the mineral sorbent granules in a partially carbonated state, the calciner reactor being configured for granular flow of the partially carbonated sorbent granules under gravitational forces at a residence time of from 1 to 10 seconds;a heat exchange structure for transferring heat from hot flue gas through a wall of the calciner reactor to a granular flow of the sorbent granules for facilitating a calcination reaction of the sorbent granules to regenerate the sorbent granules;a gas extraction unit for removing gas products from the calciner, wherein the gas products comprise carbon dioxide from the calcination reaction;a carbonator reactor located below the calciner reactor for receiving the regenerated sorbent granules from the calciner reactor and for receiving a cold flue gas, such that the regenerated sorbent granules are partially carbonised while the flue gas is scrubbed and the partially carbonated sorbent granules and the scrubbed flue gas exit the carbonator reactor as respective hot materials; anda riser unit for cycling the partially carbonated sorbent granules from the carbonator reactor to the calciner reactor. 2. The system as claimed in claim 1, wherein the calciner reactor comprises: a feeder unit for the granules;a retort chamber having the feeder unit located at a top portion thereof, whereby the sorbent granules move through the retort chamber under gravitational forces in a granular flow; andthe heat exchange structure is thermally coupled to a wall of the retort chamber for providing heat to the granules inside the retort chamber through heat transfer through the wall of the retort chamber. 3. The system as claimed in claim 2, wherein the riser unit pneumatically cycles the partially carbonated sorbent granules from a base of the carbonator reactor to the feeder unit at the top of the retort chamber. 4. The system as claimed in claim 2, further comprising a mixer means disposed inside the retort chamber, the mixer means imparting at least horizontal forces on the granules moving through the chamber such that the granules are moved towards the wall of the retort chamber for facilitating the heat exchange to the granules through the wall of the retort chamber. 5. The system as claimed in claim 2, wherein the gas extraction unit comprises a gas/particles separator structure disposed inside the calcination reactor and coupled to exhaust openings of the retort chamber for facilitating separation of the gas products from the granules. 6. The system as claimed in claim 1, wherein the gas extraction unit comprises a vacuum pump for removing the gas products from the calciner reactor. 7. The system as claimed in claim 1, wherein a gas used to pneumatically cycle the granules from the carbonator to the calciner is steam. 8. The system as claimed in claim 1, wherein the calciner reactor comprises a plurality of retort chambers, each retort chamber comprising a feeder unit located at a top portion of said each retort chamber, whereby the granules move through said each retort chamber under gravitational forces in a granular flow; the heat exchange structure is thermally coupled to a wall of said each retort chamber for providing heat to the sorbent granules inside said each retort chamber through heat transfer through the wall of said each retort chamber; and the gas extraction unit removes the gas products from said each retort chamber. 9. The system as claimed in claim 1, comprising a plurality of carbonator reactors, wherein the regenerated sorbent granules are fed serially through the plurality of carbonator reactors. 10. The system as claimed in claim 1, further comprises a bleed unit for bleeding a portion of the calcinated granules from the ealciner reactor prior to the carbonator reactor, and a feed unit for feeding a corresponding portion of fresh calcinated granules into the carbonator reactor. 11. The system as claimed in claim 1, further comprising means for scrubbing dust from the gas products comprising the carbon dioxide. 12. The system as claimed in claim 1, further comprising means for cooling the gas products comprising the carbon dioxide. 13. The system as claimed in claim 1, further comprising means for compressing the gas products comprising the carbon dioxide. 14. The system as claimed in claim 1, wherein the calciner reactor is configured for a residence time of said partially carbonated sorbent granules of about 1.5 seconds. 15. The system as claimed in claim 1, wherein the riser uses steam as a transport fluid. 16. The system as claimed in claim 15, wherein the steam is superheated steam. 17. The system as claimed in claim 1, wherein the calciner reactor is configured for a residence time of said partially carbonated sorbent granules of about 1.5 seconds. 18. A system for calcination/carbonation cycle processing, the system comprising: mineral sorbent granules having a size distribution between about 40 microns and about 125 microns;A calciner reactor for receiving the mineral sorbent granules in a partially carbonated state, the calciner reactor being configured for granular flow of the partially carbonated sorbent granules under gravitational forces at a residence time of from 1 to 10 seconds;a heat exchange structure for transferring heat from hot flue gas through a wall of the calciner reactor to a granular flow of the sorbent granules for facilitating a calcination reaction of the sorbent granules to regenerate the sorbent granules;a gas extraction unit for removing gas products from the calciner, wherein the gas products comprise carbon dioxide from the calcination reaction;a carbonator reactor for receiving the regenerated sorbent granules from the calciner reactor and for receiving a cold flue gas, such that the regenerated sorbent granules are partially carbonised while the flue gas is scrubbed and the partially carbonated sorbent granules and the scrubbed flue gas exit the carbonator reactor as respective hot materials; anda riser red to use steam as a transport fluid for cycling the partially carbonated sorbent granules from the carbonator reactor to the calciner reactor. 19. The system as claimed in claim 18, wherein the steam is superheated steam. 20. A method for calcination/carbonation cycle processing, the method comprising the steps of: receiving partially carbonated mineral sorbent granules having a size distribution between about 40 microns and about 125 microns in a calciner reactor;providing for movement of the sorbent granules through the calciner reactor under gravitational forces in a granular flow at a residence time of from 1 to 10 seconds;transferring heat from hot flue gas through a wall of the calciner reactor to the granular flow of the sorbent granules for facilitating a calcination reaction of the sorbent granules to regenerate the sorbent granules;removing gas products from the calciner, wherein the gas products comprise carbon dioxide from the calcination reaction;receiving the regenerated sorbent granules from the calciner reactor and a cold flue gas in a carbonator reactor located below the calciner reactor, such that the regenerated sorbent granules are partially carbonised while the flue gas is scrubbed and the partially carbonated sorbent granules and the scrubbed flue gas exit the carbonator reactor as respective hot materials; andcycling the partially carbonated sorbent granules from the carbonator reactor to the calciner reactor by a riser unit. 21. The method as claimed in claim 20, wherein the cycling of the partially carbonated sorbent granules uses steam as a sorbent trans tort fluid in the riser unit.