A relatively simple and energy efficient multiple stage cryogenic process for the purification of a hydrogen-rich stream by the removal of acid gases, mainly CO2 and H2S, by method of autorefrigeration and delivering or producing those acid gases, mainly CO2, at pressure sufficiently high for dispos
A relatively simple and energy efficient multiple stage cryogenic process for the purification of a hydrogen-rich stream by the removal of acid gases, mainly CO2 and H2S, by method of autorefrigeration and delivering or producing those acid gases, mainly CO2, at pressure sufficiently high for disposal by containment, commonly known as sequestration. Autorefrigeration is comprised of (a) condensing acid gases from the syngas stream by cooling the syngas, (b) separating the liquefied acid gases from the syngas, and (c) evaporating the liquefied acid gases at a pressure lower than that of the syngas to provide cooling. The process is composed of multiple autorefrigeration stages to generate multiple acid gas product streams with a pressure as high as practical in each stream so as to lessen the power needed to pressurize the acid gas streams for sequestration. The final autorefrigeration stage utilizes an antifreeze liquid that allows the final stage to operate below the freezing point of CO2; thus allowing more acid gas removal. The antifreeze liquid is an alcohol or a mixture of alcohols with a freezing point lower than about minus 110 degrees F. and a boiling point higher than about 100 degrees F. The process includes hydrogen recovery and recycle as well as recovery of the energy contained in the sulfur bearing compounds. The process is especially well suited for CO2 removal/sequestration from a coal (or petroleum coke) gasification process.
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What is claimed is: 1. A continuous process for removing acid gases from a syngas comprising a sequence of at least two stages, each stage comprising the steps of (a) condensing acid gases from the syngas by cooling the syngas by non-contact heat exchange to produce liquefied acid gases, (b) separa
What is claimed is: 1. A continuous process for removing acid gases from a syngas comprising a sequence of at least two stages, each stage comprising the steps of (a) condensing acid gases from the syngas by cooling the syngas by non-contact heat exchange to produce liquefied acid gases, (b) separating the liquefied acid gases from the syngas, and (c) evaporating the liquefied acid gases to provide the cooling of the syngas in step (a), with the stages in the sequence being designated stage 1 through stage N, the letter N representing the number of stages in the sequence, with each of the stages in the sequence cooling the syngas to a successively lower temperature as the syngas progresses from stage 1 to stage N, and each of the stages in the sequence evaporating the liquefied acid gases at successively lower pressures, said successively lower pressures being within a range of a maximum of about 800 psia to a minimum of about 6 psia, thereby separately producing an acid gas product stream from each of the stages, with stage N discharging a purified syngas, wherein at least two of the acid gas product streams from the stages are pressurized and then sequestered. 2. The process of claim 1 wherein the syngas contains water vapor and wherein the syngas is dried to a dewpoint temperature sufficiently low to prevent deposits of ice or hydrates in the process. 3. The process of claim 2 which further comprises the step of cooling the syngas before the syngas enters stage 1. 4. The process of claim 3 where N is 2 to 5. 5. The process of claim 4 wherein each of the stages comprises the steps of (a) condensing the acid gases from the syngas by cooling the syngas by non-contact heat exchange to produce the liquefied acid gases, (b) separating the liquefied acid gases from the syngas, and (c) evaporating the liquefied acid gases during the non-contact heat exchange to provide the cooling of the syngas in step (a). 6. The process of claim 5 where N is 2 and wherein unevaporated liquefied acid gases leave step (c) in stage 1 and are mixed with the liquefied acid gases of step (c) of stage 2. 7. The process of claim 5 where N is 3 and wherein unevaporated liquefied acid gases leave step (c) in stage 1 and are mixed with the liquefied acid gases of step (c) of stage 2, and further wherein unevaporated liquefied acid gases leave step (c) of stage 2 and are mixed with the liquefied acid gases of step (c) of stage 3. 8. The process of claim 5 where N is 4 and wherein unevaporated liquefied acid gases leave step (c) in stage 1 and are mixed with the liquefied acid gases of step (c) of stage 2, and further wherein unevaporated liquefied acid gases leave step (c) in stage 2 and are mixed with the liquefied acid gases of step (c) of stage 3, and further wherein unevaporated liquefied acid gases leave step (c) in stage 3 and are mixed with the liquefied acid gases of step (c) of stage 4. 9. The process of claim 5 where N is 5 and wherein unevaporated liquefied acid gases leave step (c) in stage 1 and are mixed with the liquefied acid gases of step (c) of stage 2, and further wherein unevaporated liquefied acid gases leave step (c) in stage 2 and are mixed with the liquefied acid gases of step (c) of stage 3, and further wherein unevaporated liquefied acid gases leave step (c) in stage 3 and are mixed with the liquefied acid gases of step (c) of stage 4, and further wherein unevaporated liquefied acid gases leave step (c) in stage 4 and are mixed with the liquefied acid gases of step (c) of stage 5. 10. The process of claim 5 where the coldest temperature in stage N is less than about-70째 F. and where the syngas entering stage N is mixed with an antifreeze liquid and wherein stage N comprises the steps of (a) condensing acid gases from the syngas by cooling the syngas by non-contact heat exchange to produce a mixture of liquefied acid gases and antifreeze liquid, (b) separating the mixture of liquefied acid gases and antifreeze liquid from the purified syngas, and (c) evaporating the mixture of liquefied acid gases and antifreeze liquid during the non-contact heat exchange to provide the cooling of the syngas in step (a), and wherein an unevaporated mixture of antifreeze liquid and liquefied acid gases leaves step (c) and is recycled to the syngas entering stage N and wherein freezing of the liquefied acid gases is prevented by the antifreeze within stage N. 11. The process of claim 10 wherein the antifreeze liquid is an alcohol or a mixture of alcohols with a freezing point lower than about-110째 F. and a normal boiling point higher than about 100째 F. 12. The process of claim 11 wherein the antifreeze liquid is methanol. 13. The process of claim 5 wherein the liquefied acid gases leaving step (b) of each stage are flashed to release combustible gases dissolved in the liquefied acid gases. 14. The process of claim 13 where the combustible gases are recycled by pressurizing the combustible gases and where the pressurized combustible gases are mixed with the syngas before the syngas enters stage 1. 15. The process of claim 5 wherein the syngas is cooled before entering stage 1 by external refrigeration. 16. The process of claim 5 wherein heat is transferred from the syngas in between one or more of the stages to the purified syngas thereby cooling the syngas and warming the purified syngas. 17. The process of claim 16 wherein heat is transferred from the syngas before entering stage 1 to the purified syngas, thereby cooling the syngas and warming the purified syngas. 18. The process of claim 17 wherein the syngas is cooled before entering stage 1 by external refrigeration. 19. The process of claim 17 wherein the syngas is dried by condensing and separating water from the syngas and wherein after removing the condensed water the syngas is further dried to a dewpoint temperature sufficiently low to prevent deposits of ice or hydrates in the process. 20. The process of claim 5 wherein one or more of the acid gas product streams from the stages are oxidized by oxygen to convert sulfur in the acid gas product streams to sulfur dioxide or sulfur trioxide. 21. The process of claim 20 wherein the oxidized acid gas product streams are cooled by heating an external process stream. 22. The process of claim 21 wherein the oxidized acid gas product streams are pressurized and then sequestered. 23. The process of claim 10 where N is 2 and wherein unevaporated liquefied acid gases leave step (c) in stage 1 and are mixed with the liquefied acid gases of step (c) of stage 2. 24. The process of claim 10 where N is 3 and wherein unevaporated liquefied acid gases leave step (c) in stage 1 and are mixed with the liquefied acid gases of step (c) of stage 2, and further wherein unevaporated liquefied acid gases leave step (c) of stage 2 and are mixed with the liquefied acid gases of step (c) of stage 3. 25. The process of claim 10 where N is 4 and wherein unevaporated liquefied acid gases leave step (c) in stage 1 and are mixed with the liquefied acid gases of step (c) of stage 2, and further wherein unevaporated liquefied acid gases leave step (c) in stage 2 and are mixed with the liquefied acid gases of step (c) of stage 3, and further wherein unevaporated liquefied acid gases leave step (c) in stage 3 and are mixed with the liquefied acid gases of step (c) of stage 4. 26. The process of claim 10 where N is 5 and wherein unevaporated liquefied acid gases leave step (c) in stage 1 and are mixed with the liquefied acid gases of step (c) of stage 2, and further wherein unevaporated liquefied acid gases leave step (c) in stage 2 and are mixed with the liquefied acid gases of step (c) of stage 3, and further wherein unevaporated liquefied acid gases leave step (c) in stage 3 and are mixed with the liquefied acid gases of step (c) of stage 4, and further wherein unevaporated liquefied acid gases leave step (c) in stage 4 and are mixed with the liquefied acid gases of step (c) of stage 5. 27. The process of claim 10 wherein the liquefied acid gases leaving step (b) of each stage are flashed to release combustible gases dissolved in the liquefied acid gases. 28. The process of claim 27 where the combustible gases are recycled by pressurizing the combustible gases and where the pressurized combustible gases are mixed with the syngas before the syngas enters stage 1. 29. The process of claim 10 wherein the syngas is cooled before entering stage 1 by external refrigeration. 30. The process of claim 10 wherein heat is transferred from the syngas in between one or more of the stages to the purified syngas thereby cooling the syngas and warming the purified syngas. 31. The process of claim 30 wherein heat is transferred from the syngas before entering stage 1 to the purified syngas thereby cooling the syngas and warming the purified syngas. 32. The process of claim 31 wherein the syngas is cooled before entering stage 1 by external refrigeration. 33. The process of claim 31 wherein the syngas is dried by condensing and separating water from the syngas and wherein after removing the condensed water the syngas is further dried to a dewpoint temperature sufficiently low to prevent deposits of ice or hydrates in the process. 34. The process of claim 10 wherein one or more of the acid gas product streams from the stages are oxidized by oxygen to convert sulfur in the acid gas product streams to sulfur dioxide or sulfur tri oxide. 35. The process of claim 34 wherein the oxidized acid gas product streams are cooled by heating an external process stream. 36. The process of claim 35 wherein the oxidized acid gas product streams are pressurized and then sequestered. 37. The process of claim 11 wherein the antifreeze liquid is ethanol. 38. The process of claim 11 wherein the antifreeze liquid is propanol. 39. The process of claim 11 wherein the antifreeze liquid is isopropanol. 40. The process of claim 11 wherein the antifreeze liquid is butanol. 41. The process of claim 11 wherein the antifreeze liquid is isobutanol. 42. The process of claim 11 where N is 2 to 20.
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이 특허에 인용된 특허 (4)
Adler Robert J. (Shaker Heights OH) Brosilow Coleman B. (Cleveland Heights OH) Brown William R. (Brecksville OH) Gardner Nelson C. (Cleveland Heights OH), Gas separation process.
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