Circulating fluidized bed connected to a desublimating heat exchanger

The invention claimed is: 1. A method for separating condensable vapors from gases to form a solid, comprising: providing a bed of particles located in a first chamber; providing a plurality of conduits positioned inside the first chamber; providing a separator for separating particles; providing a top aperture coupling the first chamber with the separator or a side port coupling the first chamber with the separator; providing a conduit oriented to transport substances from the first chamber to the separator; providing a heat exchanger; passing a process stream that includes carbon dioxide and at least one carrier gas through the bed of particles located in the first chamber, the bed of particles comprising a portion of solid particles and the plurality of conduits for holding cooling substances; fluidizing a portion of the solid particles of the bed, wherein some of the portion of the solid particles exits the first chamber via the top aperture into the separator or via a side port into the separator; cooling the at least one carrier gas, wherein the at least one carrier gas exits the first chamber via the conduit oriented to transport substances to the separator; receiving in the separator the portion of the solid particles and the at least one carrier gas; separating, via the separator, the portion of the solid particles from the at least one carrier gas; sending the portion of the solid particles to the heat exchanger located outside of the first chamber; subcooling the portion of the solid particles in the heat exchanger; and, reinjecting all of the portion of the solid particles in the heat exchanger into the bed of particles of the first chamber so as to desublimate a second portion of carbon dioxide located in the first chamber. 2. The method of claim 1 , wherein the process stream consists of solid carbon dioxide and gaseous N2. 3. The method of claim 1 , wherein the bed of particles comprises solid particles selected from the group consisting of solid carbon dioxide, metal particles, salts, seed particles, and combinations thereof. 4. The method of claim 1 , the process stream comprising gaseous carbon dioxide and at least one carrier gas selected from the group consisting of N2, CH4, syngas, H2, CO, argon, oxygen, and combinations thereof. 5. The method of claim 1 , a pressure within the bed of particles being in a range from either atmospheric pressure to 17 psi or from atmospheric pressure to 7 psi, wherein the receiving in a separator the portion of the solid particles further comprises separating the solid particles into a plurality of groups of solid particles, sending at least one of the plurality of the groups of solid particles to a location for further processing, and sending at least one of the plurality of the groups of solid particles to a heat exchanger. 6. The method of claim 1 , wherein the separator is either a single-stage cyclonic separator or multistage cyclonic separator. 7. The method of claim 1 , wherein a temperature within the bed of particles is lowered to less than −78° C. and wherein the step of sending to the separator further comprises sending a portion of the solid particles to a second cyclonic separator for further processing of the solid particles, sending a portion of the solid particles from the cyclonic separator to the heat exchanger, and sending the remainder of the solid particles from the second cyclonic separator to a location for further processing. 8. The method of claim 1 , wherein the bed of particles includes particles having an average particle size in a range from 0.05 mm to 20 mm, and wherein the step of subcooling decreases the temperature of the solid particles to below −140° C. 9. The method of claim 1 , wherein the bed of particles includes particles having an average particle size in a range from 0.05 mm to 12 mm, and wherein the step of subcooling decreases, on average, the temperature of solid particles by at least 35 degrees Celsius. 10. The method of claim 8 , wherein impingement of fluidized particles on a surface of a conduit the first chamber removes at least a portion of condensed solid buildup from the surface of the conduit of the first chamber. 11. The method of claim 9 , wherein the step of reinjecting all of the portion of the solid particles in the heat exchanger into the bed of particles of the first chamber is performed at a steady state in which a rate of buildup of condensed solid on the interior surface of the first chamber is approximately the same as a rate of removal of condensed solids therefrom by impingement of the fluidized particles on the interior surface of the first chamber. 12. The method of claim 1 , wherein the step of subcooling in the heat exchanger further comprises contacting the portion of the solid particles with a chilled pelletizing head, deforming the solid particles, and breaking the solid particles into uniform pieces. 13. The method of claim 12 , wherein the step of breaking the solid particles further consists of breaking the solid particles into spheroid pieces. 14. The method of claim 12 , wherein the step of breaking the solid particles further comprises breaking the solid particles into cylindrical pieces with porosity less than 70% and specific gravity between 1.2 and 1.5. 15. The method of claim 12 , further comprising compressing, in a first sector of the heat exchanger, the solid carbon so that the carbon dioxide has a porosity of less than 55% and a specific gravity between 0.7 and 1.5 and the step of compressing occurs, in a second sector of the heat exchanger, simultaneously with the step of breaking the solid particles. 16. A method for separating condensable vapors from gases to form a solid, comprising: cooling a process stream that includes condensable vapors using one or more up-stream heat exchangers prior to passing the process stream through a process stream inlet of a particle bed vessel; passing the process stream that includes carbon dioxide and at least one carrier gas through a bed of particles of a particle bed vessel, the bed of particles comprising a plurality of solid particles consisting essentially of a plurality of solid particles selected from the group consisting of sulfur dioxide, sulfur trioxide, carbon dioxide, water, nitrogen dioxide, and nitric oxide and a plurality of conduits for holding cooling substances; fluidizing a portion of the solid particles of the bed, wherein some of the portion of the solid particles exits the first chamber via a top aperture coupled to a multi-stage cyclonic separator or via a side port coupled to the multi-stage cyclonic separator; cooling the at least one carrier gas, wherein the at least one carrier gas exits the first chamber via a conduit oriented to transport substances to the multi-stage cyclonic separator; receiving in the multi-stage cyclonic separator the portion of the solid particles and the at least one carrier gas; separating, via the multi-stage cyclonic separator, the portion of the solid particles from the at least one carrier gas; separating, via the multi-stage cyclonic separator, the portion of the solid particles into at least three groups based on size; removing, via the multi-stage cyclonic separator, the at least one carrier gas via a gas outlet of the multi-stage cyclonic separator; sending at least one group of the portion of the solid particles to a heat exchanger located outside of the first chamber; subcooling the portion of the solid particles in the heat exchanger to a temperature that lowers solid carbon dioxide to a lower temperature; and, reinjecting all of the porti