Cryogenic systems for removing acid gases from a hydrocarbon gas stream using co-current separation devices

What is claimed is: 1. A system for removing acid gases from a raw gas stream, comprising: a dehydration vessel for receiving the raw gas stream, and separating the raw gas stream into a dehydrated raw gas stream and a stream comprised of an aqueous fluid; a heat exchanger for cooling the dehydrated gas stream, and releasing a cooled sour gas stream; a cryogenic distillation tower that receives the cooled sour gas stream, and separates the cooled sour gas stream into (i) an overhead gas stream comprised primarily of methane, and (ii) a bottom liquefied acid gas stream comprised primarily of carbon dioxide, wherein the cryogenic distillation tower separates the cooled sour gas stream by freezing the carbon dioxide in the cooled sour gas stream; a final co-current contactor configured to (i) receive the bottom liquefied acid gas stream, (ii) receive a partially methane-enriched gas stream from a previous co-current contactor, (iii) release a final methane-enriched gas stream to the cryogenic distillation tower, and (iv) release a first partially-stripped acid gas liquid to the previous co-current contactor; and a first co-current contactor configured to (i) receive a stripping gas, (ii) receive a second partially-stripped acid gas liquid from a second co-current contactor, (iii) release a final stripped acid gas liquid, and (iv) release a first partially-methane-enriched gas stream to the second co-current contactor; and wherein the co-current contactors are arranged in series and wherein the stripping gas comprises carbon dioxide; and wherein the at least one of the co-current contactors comprise a mixing device and a coalescing device. 2. The system of claim 1 , wherein the final stripped acid gas liquid comprises about 98 mol. percent or more acid gas. 3. The system of claim 2 , wherein a substantial portion of the final stripped acid gas liquid is injected into a subsurface formation through one or more acid gas injection wells. 4. The system of claim 2 , wherein a portion of the final stripped acid gas liquid is diverted and used as at least a portion of the stripping gas via reboiling. 5. The system of claim 1 , wherein: the cryogenic distillation tower comprises a freezing zone; the freezing zone receives the cooled sour gas stream, a cold liquid spray comprised primarily of methane, and the further comprises methane from the final methane-enriched gas stream from the final co-current contacting device; and the cryogenic distillation tower further comprises refrigeration equipment downstream of the cryogenic distillation tower for cooling the overhead methane stream and returning a portion of the overhead methane stream to the cryogenic distillation tower as the cold liquid spray. 6. The system of claim 5 , further comprising: a melt tray below the freezing zone for receiving a cold slurry of acid gas particles, and delivering a substantially solids-free slurry to the final co-current contacting device as the bottom liquefied acid gas stream. 7. The system of claim 6 , wherein the bottom liquefied acid gas stream exits the cryogenic distillation tower at a temperature no greater than about −70° F. 8. The system of claim 5 , further comprising: a lower distillation zone below the freezing zone for receiving a cold slurry of acid gas particles, at least partially melting the slurry of acid gas particles into a liquid stream, and delivering the liquid stream to the final concurrent contacting device as the bottom liquefied acid gas stream. 9. The system of claim 5 , further comprising: an upper distillation zone above the freezing zone for receiving vapor from the freezing zone and releasing the overhead gas stream. 10. The system of claim 2 , wherein the system comprises only two co-current contactors for processing the bottom acid gas stream such that: the final co-current contactor is the second co-current contactor; the previous co-current contactor is the first co-current contactor; the first partially-methane-enriched gas stream released by the first co-current contactor is the partially methane-enriched gas stream received by the final co-current contactor; and the first partially-stripped acid gas liquid released by the final co-current contactor is the second partially-stripped acid gas liquid received by the first co-current contactor. 11. The system of claim 2 , wherein the system comprises three co-current contactors for processing the bottom acid gas stream, such that: the previous co-current contactor is the second co-current contactor; and the second co-current contactor is configured to (i) receive the first partially-methane-enriched gas stream from the first co-current contactor, (ii) receive the first partially-stripped acid gas liquid from the final co-current contactor, (iii) release a second partially-methane-enriched gas stream into the final co-current contactor, and (iv) release the second partially-stripped acid gas liquid into the first co-current contactor. 12. The system of claim 2 , wherein the system comprises at least three co-current contactor for processing the bottom liquefied acid gas stream, such that: the final co-current contactor, any intermediate co-contactors, the second co-current contactor and the first co-current contactor are arranged to deliver respective stripped acid gas liquids as progressively CO2-richer acid gas liquids in series, and the first co-current contactor, the second co-current contactor, any intermediate co-contactors, and the final co-current contactor are arranged to deliver the respective methane-enriched gas streams as progressively methane-enriched gas streams in series. 13. The system of claim 1 , wherein the mixing device is selected from a static mixer, an eductor, and a centrifugal mixer. 14. A system for removing acid gases from a raw gas stream, comprising: a dehydration vessel for receiving the raw gas stream, and separating the raw gas stream into a dehydrated raw gas stream and a stream comprised of an aqueous fluid; a heat exchanger for cooling the dehydrated raw gas stream, and releasing a cooled sour gas stream; a cryogenic distillation tower that receives the cooled sour gas stream, and separates the cooled sour gas stream into (i) an overhead gas stream comprised primarily of methane, and (ii) a bottom acid gas stream comprised primarily of carbon dioxide, wherein the cryogenic distillation tower separates the cooled sour gas stream by freezing the carbon dioxide in the cooled sour gas stream; a final lower co-current contactor configured to (i) receive the bottom liquefied acid gas stream, (ii) receive a partially-methane-enriched gas stream from a previous lower co-current contactor, (iii) release a final methane-enriched gas stream into the cryogenic distillation tower, and (iv) release a first partially-stripped acid gas liquid into the previous lower co-current contactor; and a first lower co-current contactor configured to (i) receive a stripping gas, (ii) receive a second stripped acid gas liquid from a second lower co-current contactor, (iii) release a final stripped acid gas liquid, and (iv) release a first partially-methane-enriched gas stream to the second lower co-current contactor; a first upper co-current contactor configured to (i) receive the overhead gas stream, (ii) receive a second partially-CO 2 -enriched reflux liquid from a second co-current contactor, (iii) release a first partially-sweetened methane gas stream to the second co-current contactor, and (iv) release a final CO 2 -enriched reflux liquid to the cryogenic distillation tower; and a final upper co-current contactor configured to (i) receive