초록 ▼

Biogas containing H2S and CO2 is upgraded by removing H2S using PTSA and CO2 using two stages of gas separation membranes. The first stage permeate may optionally be used a regeneration gas stream. The second stage permeate may optionally be used a cool down gas stream. The PTSA unit includes two or

Biogas containing H2S and CO2 is upgraded by removing H2S using PTSA and CO2 using two stages of gas separation membranes. The first stage permeate may optionally be used a regeneration gas stream. The second stage permeate may optionally be used a cool down gas stream. The PTSA unit includes two or more adsorbent beds each selective for water, VOCs, and H2S over CO2 and for H2S over methane.

대표청구항 ▼

1. A biogas upgrading method based upon PTSA and gas separation membranes, comprising the steps of: compressing a stream of biogas with a main compressor;feeding, to a PTSA unit, a PTSA feed gas stream withdrawn from an outlet of the main compressor;removing H2S from the PTSA feed gas stream with th

1. A biogas upgrading method based upon PTSA and gas separation membranes, comprising the steps of: compressing a stream of biogas with a main compressor;feeding, to a PTSA unit, a PTSA feed gas stream withdrawn from an outlet of the main compressor;removing H2S from the PTSA feed gas stream with the PTSA unit, the PTSA unit comprising two or more adsorbent beds each of which is selective for water, VOCs, and H2S over CO2 and for H2S over methane, each of said beds being subjected to a PTSA cycle comprising the phases of: adsorption of water, VOCs, and H2S from the PTSA feed gas stream; depressurization; thermal regeneration using a regeneration gas stream in which adsorbed water, VOCs, and H2S are desorbed; cool down using a cool down gas stream; and repressurization;withdrawing an H2S-depleted PTSA product stream from the PTSA unit;feeding the PTSA product stream to a first gas separation membrane stage comprising one or more gas separation membranes selective for CO2 and O2 over methane;withdrawing, from the first gas separation membrane stage, a first stage permeate stream enriched in CO2 and O2 and deficient in methane compared to the PTSA product stream and a first stage retentate stream deficient in CO2 and O2 and enriched in methane compared to the PTSA product stream;feeding the first stage retentate stream to a second gas separation membrane stage comprising one or more gas separation membranes selective for CO2 and O2 over methane; andwithdrawing, from the second gas separation membrane stage, a second stage permeate stream enriched in CO2 and deficient in methane compared to the first stage retentate stream and a second stage retentate stream deficient in CO2 and enriched in methane compared to the first stage retentate stream, wherein the second stage retentate stream is a product natural gas stream, wherein the repressurization of the beds is performed with one or more of the PTSA feed gas stream, the PTSA product gas stream, the first stage retentate stream, and the second stage retentate stream. 2. The method of claim 1, wherein the compressed feed gas is cooled prior to introduction to the PTSA. 3. The method of claim 1, wherein some or all of the second stage permeate stream is the cool down gas stream and the cool down gas stream is received from the PTSA unit by a suction inlet of the main compressor where it is combined with the compressed biogas stream. 4. The method of claim 1, wherein the second stage permeate stream is received at and compressed by a secondary compressor and the compressed second stage permeate stream is fed to the first gas separation stage along with the PTSA product stream. 5. The method of claim 1, wherein a waste gas comprised of the regeneration gas stream and the H2S, water, and VOCs desorbed from one or more adsorbent beds of the PTSA unit is thermally oxidized at a thermal oxidizer. 6. The method of claim 1, wherein the regeneration gas stream is comprised of some or all of the first stage permeate stream which has been heated to a temperature above the PTSA feed gas temperature. 7. The method of claim 6, wherein a waste gas stream comprised of the regeneration gas stream and the H2S, water, and VOCs desorbed from one or more adsorbent beds of the PTSA unit is thermally oxidized at a thermal oxidizer. 8. The method of claim 6, wherein some or all of the second stage permeate stream is the cool down gas stream and the cool down gas stream is received from the PTSA unit at a suction inlet of the main compressor where it is combined with the compressed biogas stream. 9. The method of claim 1, further comprising the step of, removing amounts of H2S present in the PTSA feed gas stream by an H2S removal unit prior to feeding the PTSA feed gas stream to the PTSA unit, wherein the PTSA unit removes amounts of water and VOCs from the PTSA feed gas stream and also amounts of the H2S remaining in the PTSA feed gas stream after treatment by the H2S removal unit. 10. The method of claim 1, wherein the regeneration gas stream is heated to the temperature above the PTSA feed gas temperature through heat exchange, at a heat exchanger, with cooling oil circulating through the first compressor. 11. The method of claim 10, wherein some or all of the regeneration gas stream is the first stage permeate stream. 12. The method of claim 1, wherein a waste gas comprised of the regeneration gas stream and the H2S, water, and VOCs desorbed from one or more adsorbent beds of the PTSA unit is thermally oxidized at a thermal oxidizer and the regeneration gas stream is heated to the temperature above the PTSA feed gas temperature through heat exchange, at a heat exchanger, with hot gas produced in the thermal oxidizer. 13. The method of claim 1, wherein the PTSA unit comprises first and second adsorbent beds, and the PTSA unit cycle comprises: a first phase during which the first bed undergoes adsorption and the second bed undergoes depressurization and then thermal regeneration;a second phase during which the first bed undergoes adsorption and the second bed undergoes cool down and then repressurization;a third phase during which the second bed undergoes adsorption and the first bed undergoes depressurization and then thermal regeneration; anda fourth phase during which the second bed undergoes adsorption and the first bed undergoes cool down and then repressurization. 14. The method of claim 1, wherein the PTSA unit comprises first, second, and third adsorbent beds, and the PTSA unit cycle comprises: a first phase during which the first bed undergoes adsorption, the second bed undergoes cool down and then repressurization, and the third bed undergoes depressurization and then thermal regeneration;a second phase during which the second bed undergoes adsorption, the third bed undergoes cool down and then repressurization, and the first bed undergoes depressurization and then thermal regeneration; anda third phase during which the third bed undergoes adsorption, the first bed undergoes cool down and then repressurization, and the second bed undergoes depressurization and then thermal regeneration. 15. The method of claim 1, wherein the PTSA unit comprises first, second, third, and fourth adsorbent beds, and the PTSA unit cycle comprises: a first phase during which the first and fourth beds undergo adsorption, the second bed undergoes cool down and then repressurization, and the third bed undergoes depressurization and then thermal regeneration;a second phase during which the first and second beds undergo adsorption, the third bed undergoes cool down and then repressurization, and the fourth bed undergoes depressurization and then thermal regeneration;a third phase during which the second and third beds undergo adsorption, the fourth bed undergoes cool down and then repressurization, and the first bed undergoes depressurization and then thermal regeneration; anda fourth phase during which the third and fourth beds undergo adsorption, the first bed undergoes cool down and then repressurization, and the second bed undergoes depressurization and then thermal regeneration.