The present invention relates to a method of controlling a gas separation plant, to a plant thus controlled and also to its use for separation of gas mixtures, especially in the processing of biogas or natural gas, or syngas.
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1. An apparatus for separating gases, comprising as membrane separation stages at least a feed stream separation stage, a retentate separation stage and a permeate separation stage and also at least one compressor arranged on the feed side of said feed stream separation stage and/or at least one vac
1. An apparatus for separating gases, comprising as membrane separation stages at least a feed stream separation stage, a retentate separation stage and a permeate separation stage and also at least one compressor arranged on the feed side of said feed stream separation stage and/or at least one vacuum pump arranged downstream of said feed stream separation stage, whereinsaid feed stream separation stage separates a feed stream, consisting of two or more components, into a first permeate stream and a first retentate stream,said retentate separation stage divides said first retentate stream into a second permeate stream and a second retentate stream, wherein the second permeate stream is supplied to a permeate control means located downstream of said retentate separation stage and wherein said second permeate stream is supplied to said feed stream downstream of said permeate control means, and wherein said second retentate stream is removed as product or further processed,said permeate separation stage divides said first permeate stream into a third retentate stream and a third permeate stream, wherein said third retentate stream is supplied to a retentate control means located downstream of said permeate separation stage and wherein said third retentate stream is supplied to said feed stream downstream of said retentate control means, and wherein said third permeate stream is removed as product or further processed or discarded,said permeate control means can raise or lower the permeate pressure of said retentate separation stage and is controlled on the basis of measured values from one or more measuring means in said first retentate stream and/or one or more measuring means in said second retentate stream,and/orsaid retentate control means can raise or lower the retentate pressure of said permeate separation stage and is controlled on the basis of measured values from one or more measuring means in said first permeate stream and/or one or more measuring means in said third permeate stream. 2. The apparatus according to claim 1, wherein said first permeate stream is not subjected to recompression, and/orgas separation membrane modules having a mixed gas selectivity CO2/CH4 of not less than 30 are used at least in said feed stream separation stage,and/orat least one of said membrane separation stages comprises more than one gas separation membrane module interconnected in parallel and/or series,and/orthe gas separation membrane module(s) consist(s) of hollow fibre membranes and/or flat membranes,and/orsaid apparatus is configured such that the gas volume recycled in said second permeate stream and in said third retentate stream amounts in total to less than 60% by volume of the volume of a raw gas stream,and/orsaid apparatus is configured such that a concentration of at least one permeate gas of said feed stream separation stage, after returning said second permeate stream and said third retentate stream, is raised in said feed stream by not less than 2% as compared with the concentration in a raw gas stream. 3. The apparatus according to claim 2, wherein gas separation membrane modules having a mixed gas selectivity CO2/CH4 of not less than 30 are used in all three membrane separation stages. 4. The apparatus according to claim 2, wherein said apparatus is configured such that a concentration of at least one permeate gas of said feed stream separation stage, after returning said second permeate stream and said third retentate stream, is raised in said feed stream by 3 to 40% compared with the concentration in said raw gas stream. 5. The apparatus according to claim 1, wherein said second permeate stream and said third retentate stream are led to the suction side of said compressor,and/or in thatthe compressor is a multi-stage compressorand/orthat the compressor is a multi-stage compressor and said second permeate stream and/or said third retentate stream is/are introduced into said compressor between two compression stages,and/orin that said compressor is arranged in said apparatus such that it generates a pressure gradient in said feed stream separation stage. 6. The apparatus according to claim 1, wherein said apparatus comprises a controller means which adapts a rotary speed of said compressor to changes in said second permeate stream and/or said third retentate stream and/or said raw gas stream,and/or in thatsaid apparatus is configured such that the supplied amount of raw gas is regulated to adjust to changes in the amount of recycled gas from said second permeate stream and/or said third retentate stream. 7. The apparatus according to claim 1, wherein flow meters are used as measuring means in said first retentate stream and/or in said first permeate stream or in thatan online or offline measuring means is used in said second retentate stream and/or in said third permeate stream to determine the composition of the particular gas mixture. 8. The apparatus according to claim 1, wherein the membranes in the membrane separation stages comprise a separation-active layer of amorphous or partly crystalline materials chosen from polyimides, polyamides, polysulphones, cellulose acetates and derivatives, polyphenylene oxides, polysiloxanes, polymers having intrinsic microporosity, mixed matrix membranes, facilitated transport membranes, polyethylene oxides, polypropylene oxides and mixtures thereof. 9. The apparatus according to claim 8, wherein the material used for the separation-active layer of the membranes is a polyimide of units of the general formulae A and B: wherein x is in the range of from 0 to 0.5 and y is in the range of from 0.5 to 1, and wherein R1 and R2 are each independently chosen from one or more of L1, L2, L3 and L4 . 10. The apparatus according to claim 1, wherein not less than 95% of the feed stream separation stage retentate component led into said apparatus is removed via said second retentate stream,and/or in thatnot more than 5% of feed stream separation stage retentate component led into said apparatus is removed via said third permeate stream. 11. A method of controlling a gas separation plant, wherein a gas mixture comprising a more readily permeating component A and a less readily permeating component B is separated in an apparatus according to claim 1, said method comprising i. selecting a setpoint range for a concentration of said component B in the second retentate stream, or for a parameter correlating with said concentration of component B in the second retentate stream, lowering the pressure of the second permeate stream by the permeate control means until said concentration or parameter correlating with concentration of component B in the second permeate stream is within the setpoint range for component B in the second permeate stream, if the concentration or parameter correlating with concentration for a component B is below the setpoint range in the second retentate stream, and raising the pressure of the second permeate stream by the permeate control means until said concentration or parameter correlating with concentration of component B in the second permeate stream is within the setpoint range for component B in the second permeate stream, if the concentration or parameter correlating with concentration for a component B is above the setpoint range in the second retentate stream;and/orii. selecting a setpoint range for a concentration of said component B in the third permeate stream, or for a parameter correlating with said concentration of a component B in the third permeate stream, raising the pressure of the third retentate stream by the retentate control means until said concentration or parameter correlating with concentration of component B in the third retentate stream is within the setpoint range for component B in the third retentate stream, if the concentration or parameter correlating with concentration for a component B is below the setpoint range in the third permeate stream, and lowering the pressure of the third retentate stream by the retentate control means until said concentration or parameter correlating with concentration of component B in the third retentate stream is within the setpoint range for component B in the third retentate stream, if the concentration or parameter correlating with concentration for a component B is above the setpoint range in the third permeate stream. 12. The method according to claim 11, wherein the concentration of component B in the second permeate stream and/or the third retentate stream is determined online and/or offline. 13. A method of controlling a gas separation plant, wherein an apparatus according to claim 1 is used, said method comprising i. selecting a setpoint range for a parameter of the second retentate stream correlated by a calibration curve with a volume flow of the first retentate stream, lowering pressure of said second permeate stream by the permeate control means until said parameter of the second retentate stream is within the setpoint range when the volume flow of first retentate stream increases, andraising pressure of said second permeate stream by the permeate control means until said parameter of the second retentate stream is within the setpoint range when the volume flow of said first retentate stream decreases;and/orii. selecting a setpoint range for a parameter of the third permeate stream correlated by a calibration curve with a volume flow of the first permeate stream, raising pressure of said third retentate stream by said retentate control means until said parameter of the third permeate stream is within the setpoint range when the volume flow of said first permeate stream increases, andlowering a pressure of said third retentate stream by said retentate control means until said parameter of the third permeate stream is within the setpoint range when the volume flow of said first permeate stream increases. 14. The method according to claim 13, wherein a calibration curve containing a correlation between a volume flow rate and pressure of a gas stream is used as a control curve to maintain a concentration of a component in a different gas stream. 15. The method according to claim 11, wherein a pressure drop across said feed stream separation stage is set at from 1 to 30 bar,and/ora pressure drop across said feed stream separation stage and said retentate separation stage is set at from 1 to 100 bar. 16. The method according to claim 15, wherein the pressure drop across said feed stream separation stage is set at from 3 to 10 bar,and/orthe pressure drop across said feed stream separation stage and said retentate separation stage is set at from 10 to 70 bar. 17. The method according to claim 11, wherein a driving force used for gas separation is a partial pressure difference between a retentate side and a permeate side of at least one of the membrane separation stages, wherein said partial pressure difference is generated by said at least one compressor, which is arranged on the feed side of said feed stream separation stage, and optionally by said at least one vacuum pump in said second and/or third permeate stream and/or by a permeate-side purge gas stream,and/or in thata pressure of the permeate of said feed stream separation stage is in an equal or elevated state relative to an ambient pressure, so there is still a partial pressure difference between a retentate and a permeate of said permeate separation stage and hence there is a driving force in the event that said permeate of said permeate separation stage is at ambient pressure or negative pressure is applied. 18. The method according to claim 11, wherein a controller means adapts a rotary speed of said compressor to changes in the second permeate stream and/or said third retentate stream and/or a raw gas stream,and/orchanging amounts of recycled gas from said second permeate stream and/or said third retentate stream are equalized, by a regulation of the supplied amount of raw gas, preferably via a raw gas control means, preferably without changing the rotary speed of said compressorora performance of the gas separation plant is raised or lowered by changing a volume throughput of said compressor, whereina resultant change in a volume flow of said first retentate stream is counteracted by selecting a setpoint range for a parameter of the second retentate stream correlated by a calibration curve with a volume flow of the first retentate stream, lowering pressure of said second permeate stream by the permeate control means until said parameter of the second retentate stream is within the setpoint range when the volume flow of first retentate stream increases, and raising pressure of said second permeate stream by the permeate control means until said parameter of the second retentate stream is within the setpoint range when the volume flow of said first retentate stream decreasesand/ora resultant change in a volume flow of said first permeate stream is counteracted by selecting a setpoint range for a parameter of the third permeate stream correlated by a calibration curve with a volume flow of the first permeate stream, raising pressure of said third retentate stream by said retentate control means until said parameter of the third permeate stream is within the setpoint range when the volume flow of said first permeate stream increases, and lowering a pressure of said third retentate stream by said retentate control means until said parameter of the third permeate stream is within the setpoint range when the volume flow of said first permeate stream increases. 19. The method according to claim 11, wherein said method is practised in the context of operating a biogas plant, wherein the rotary speed of the compressor and hence the volume throughput of said compressor is controlled according to said biogas plant fill level and/or via fermenter pressure or intermediate store fill level, in order that the fill level in the fermenter and/or intermediate store may be changed or kept constant,orthe gas mixture used is chosen from mixtures of predominantly but not exclusively carbon dioxide and methane, predominantly but not exclusively hydrogen and methane, predominantly but not exclusively carbon monoxide and hydrogen, raw biogas, and raw natural gas. 20. A biogas plant comprising an apparatus according to claim 1.
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이 특허에 인용된 특허 (11)
Prasad Ravi, Advanced membrane system for separating gaseous mixtures.
Prasad Ravi (East Amherst NY) Cook Pauline J. (Kenmore NY), Start-up and shut down processes for membrane systems and membrane systems useful for the same.
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