ATR-based hydrogen process and plant

The invention claimed is: 1. A plant for producing a H 2 -rich stream from a hydrocarbon feed, said plant comprising: a reforming section comprising an autothermal reformer (ATR), said ATR being arranged to receive a hydrocarbon feed and convert it to a stream of syngas, and at least one fired heater, said at least one fired heater being arranged to pre-heat said hydrocarbon feed prior to the hydrocarbon feed being fed to the ATR; a shift section, said shift section comprising a high temperature shift unit, said high temperature shift unit being arranged receive a stream of syngas from the ATR and shift it in a high temperature shift step, thereby providing a shifted syngas stream; a CO 2 removal section, arranged to receive the shifted syngas stream from said shift section and separate a CO 2 -rich stream from said shifted syngas stream, thereby providing a CO 2 -depleted shifted syngas stream; and a hydrogen purification unit, arranged to receive said CO 2 -depleted shifted syngas stream, from said CO 2 removal section, and separate it into a high-purity H 2 stream and an off-gas stream, wherein: (a) said plant is arranged to feed at least a part of the off-gas stream from said hydrogen purification unit as an off-gas recycle stream to a feed side of the ATR; (b) said plant is arranged to feed at least a part of the off-gas stream from said hydrogen purification unit as an off-gas recycle stream to a feed side of the shift section; and/or (c) said plant further comprises at least one prereformer unit arranged upstream the ATR, said prereformer unit being arranged to pre-reform said hydrocarbon feed prior to it being fed to the ATR and wherein said plant is arranged to feed at least a part of the off-gas stream from said hydrogen purification unit as an off-gas recycle stream to a feed side of the prereformer unit, said plant further comprising: (i) a compressor arranged for compressing said off-gas recycle stream, and a membrane separation unit for separating the thus compressed off-gas recycle stream into a permeate membrane stream and a retentate membrane stream, said compressor being arranged upstream of said membrane separation unit, said permeate membrane stream being hydrogen rich, and wherein a. said plant is arranged for recycling said permeate membrane stream, optionally via a compressor, to the feed side of the hydrogen purification unit, and/or b. said plant is arranged for mixing said permeate membrane stream with said high purity hydrogen stream from the hydrogen purification unit, and for recycling said membrane retentate as fuel for said at least one fired heater; or (ii) a compressor arranged for compressing said off-gas recycle stream, and a CO 2 separation unit for removal of CO 2 from the thus compressed off-gas recycle stream into a CO 2 -rich off-gas stream and a CO 2 -lean off-gas stream, said compressor being adapted upstream said CO 2 separation unit, and wherein said plant is arranged for recycling said CO 2 -lean off-gas stream, optionally via a compressor, to: (a) the feed side of the ATR; (b) the feed side of the shift section; (c) the feed side of the hydrogen purification unit; and/or (d) said at least one fired heater as fuel. 2. The plant according to claim 1 , wherein said off-gas recycle stream is mixed with hydrocarbon feed before being fed to the feed side of the ATR. 3. The plant according to claim 1 , wherein said off-gas recycle stream is mixed with hydrocarbon feed before being fed to the feed side of the prereformer unit. 4. The plant according to claim 1 , wherein the high temperature shift unit comprises a promoted zinc-aluminium oxide based high temperature shift catalyst. 5. The plant according to claim 1 , wherein said plant is arranged to feed at least a part of the off-gas stream from said hydrogen purification unit as fuel for said fired heater. 6. The plant according to claim 1 , wherein the hydrogen purification unit is selected from a pressure swing adsorption (PSA) unit, a hydrogen membrane or a cryogenic separation unit. 7. The plant according to claim 1 , wherein the CO 2 removal section is selected from an amine wash unit, or a CO 2 membrane, or a cryogenic separation unit. 8. The plant according to claim 1 , wherein the shift section comprises one or more additional high temperature shift units in series. 9. The plant according to claim 1 , wherein said shift section further comprises one or more additional shift units downstream the high temperature shift unit. 10. The plant according to claim 9 , wherein the one or more additional shift units are one or more medium temperature shift units and/or one or more low temperature shift units. 11. The plant according to claim 1 , further comprising a methanol removal section arranged between the shift section and said CO 2 removal section, said methanol removal section being arranged to separate a methanol-rich stream from said shifted syngas stream. 12. The plant according to claim 1 , the CO 2 removal section is a CO 2 membrane, said CO 2 membrane is arranged to produce a hydrogen-rich permeate stream for further enrichment in said hydrogen purification unit and a hydrogen-lean retentate stream, wherein: said plant is arranged to feed at least a part of the hydrogen-lean retentate stream from said CO 2 membrane as a hydrogen recycle stream to the feed side of the ATR; said plant is arranged to feed at least a part of the hydrogen-lean retentate stream from said CO 2 membrane as a hydrogen recycle stream to the feed side of the shift section; and/or said plant is arranged to feed at least a part of the hydrogen-lean retentate stream from said CO 2 membrane as a hydrogen recycle stream to the inlet of the CO 2 membrane. 13. The plant according to claim 1 , wherein the CO 2 removal section is a cryogenic separation unit, said cryogenic separation unit is arranged to produce a cryogenic unit off-gas stream and said CO 2 -depleted shifted syngas stream, wherein; said plant is arranged to feed at least a part of the off-gas stream from said cryogenic separation unit as a cryogenic off-gas recycle stream to the feed side of the ATR; said plant is arranged to feed at least a part of the off-gas stream from said cryogenic separation unit as a cryogenic off-gas recycle stream to the feed side of the shift section; and/or said plant is arranged to feed at least a part of the off-gas stream from said cryogenic separation unit as a cryogenic off-gas recycle stream to the feed side. 14. The plant according to claim 1 , said plant further comprising option (i). 15. The plant according to claim 1 , said plant further comprising option (ii). 16. A process for producing a H 2 -rich stream from a hydrocarbon feed, said process comprising the steps of: providing a plant according to claim 1 ; supplying a hydrocarbon feed to the ATR, and converting it to a stream of syngas; supplying a stream of syngas from the ATR to the shift section, and shifting it in a high temperature shift step, thereby providing a shifted syngas stream; supplying the shifted gas stream from the shift section to the CO 2 removal section, and separating a CO 2 -rich stream from said shifted syngas stream, thereby providing a CO 2 -depleted shifted syngas stream; supplying said CO 2 -depleted shifted syngas stream from said CO 2 removal section to a hydrogen purification unit, and separating it into a high-purity H 2 stream and an off-gas stream; and, at least one step selected from: feeding at least a part of the off-gas stream from said hydrogen purification unit as an off-