Cryogenic process for crude helium recovery from natural gas

We claim: 1 . A cryogenic process to produce crude helium from pretreated natural gas consisting of 80-98 mole % methane, 3-20 mole % methane plus hydrocarbon, 0.1-5.0 mole % nitrogen %, 0.01-mole % helium, 1-10 ppmv H 2 S, 5-50 ppmv water, wherein said process comprising the steps of: a) subjecting the pretreated natural gas ( 1 ) to cooler (E 1 ) for its cooling in the temperature range of minus 70-minus 140° C.; b) subjecting a partially condensed gas ( 2 ) to throttling device (TD) to reduce its pressure and generating cold and routing a stream ( 2 A) from TD to the first flash stage (FSI) or partially condensed gas ( 2 ) direct routing to first flash stage (FSI) for generating an uncondensed gas stream ( 3 ) and liquid stream ( 4 ); c) subjecting the gas stream ( 3 ) for its cooling in a heat exchanger (E 2 ), which uses a cold process liquid streams ( 7 ) and external cold utility (ER 1 ) in the temperature range of minus 100-minus 150° C.; d) subjecting a partially condensed gas stream ( 5 ) to a second flash stage (FSII), which has 2-6 tray below the feed entry location and use helium free stripping stream ( 19 ) to generate a gas stream ( 6 ) and liquid stream ( 7 ); e) subjecting the gas stream ( 6 ) to multi streams heat exchanger (E 3 ) for its heating; f) subjecting a heated gas stream ( 6 A) along the high-pressure purge stream ( 15 D) having pressure in the range of 6-20 bars from purification system (PS) to a compressor (K 2 ) for increasing combined streams pressure in the range of 20-50 bars; g) subjecting a pressurized gas stream ( 8 ) to a water or air cooler (E 6 ), subsequently cooling of gas stream ( 9 ) to multi stream heat exchanger (E 3 ) using either process cold streams or both process cold stream and external utility, cooling of stream ( 10 ) in a heat exchanger E 5 and then stream ( 11 ) from E 5 is again routed to E 3 for its cooling and producing stream ( 12 ) having a temperature in the range of minus 80-minus 140° C.; h) subjecting a partially condensed gas stream ( 12 ) to a distillation column (DC) having multiple trays in its stripping and rectification sections and having the process stream and/or external utility coils cooler (E- 6 ) inside the DC overhead section to generate the in situ liquid for rectification section and/or reflux stream ( 16 ) at the top tray; i) cooling a gas stream ( 13 ) in a heat exchanger (E 4 ) for its partial condensation; j) subjecting a cooled gas stream ( 14 ) to a separating vessel (V 1 ) for generating the crude helium ( 15 ) and liquid stream ( 16 ) used as reflux stream in top section of DC; k) recycling a purge stream ( 15 C) having pressure in the range of 1-10 bars from the purification system to pressure increasing device (K 3 ) to produce an increased pressure stream ( 15 E), which is further routed to a gas compressor (K 2 ); l) recycling a purge stream ( 15 D) having pressure in the range of 8-20 bars from the purification system to a gas compressor (K 2 ); m) splitting the DC bottom liquid stream ( 17 ) into two streams 18 and 20 ; n) subjecting a stream 18 to throttling valve/expender (PV 1 ) to generate low-pressure stream 18 A, which is routed to exchanger E 3 for its cold recovery; o) subjecting the stream 20 to throttling valve/expander (PV 2 ) to generate low-pressure stream 20 A, which is routed to heat exchanger E 4 for its cold recovery; p) subjecting a stream 20 B either to a cold utility generation system or to multi streams heat exchanger E 3 for its cold recovery; q) subjecting a stream 7 C, stream 18 B, stream 20 B or 20 B 1 to a cold utility generation system (CUGS) for recovering their cold; r) subjecting a stream 20 C to pressure increasing device (K 4 ) with or without 7 D; s) subjecting a stream 7 E from K 4 to a gas compressor (K 1 ) for recycling the hydrocarbon stream for further processing and utilization; t) recycling a streams 18 D, 21 and 7 D to upstream process for further processing and utilization. 2 . The process as claimed in claim 1 , wherein the methane plus hydrocarbon is selected from ethane, propane, butane, isobutene, pentane, iso-pentane and hexane in any proportion. 3 . The process as claimed in claim 1 , wherein the distillation column (DC) is operating, preferably in the pressure range of 20-50 bars and most preferably in the temperature range of 20-40 bars. 4 . The process as claimed in claim 1 , wherein in another embodiment of the present invention, the throttling device (TD) is represented by throttling valve or expansion valve or similar device and the pressure increasing device (K 3 ) is represented by a compressor or ejector using compressing process stream ( 6 A), wherein K 3 may be single-stage or multistage with inter stage cooling pressure increasing device. 5 . The process as claimed in claim 1 , wherein the pressure increasing device (K 4 ) is represented by a compressor for compressing the 20 C stream or ejector using compressing process stream ( 7 D). 6 . The process as claimed in claim 1 , wherein the crude helium stream ( 15 ) after its cold recovery in a cold utility generation system (CUGS) is subjected to a known purification system (PS) for producing the pure helium stream ( 15 B). 7 . The process as claimed in claim 6 , wherein the purification system (PS) is either membranes or pressure swing adsorption or vacuum swing adsorption or a combination of thereof. 8 . The process as claimed in claim 1 , wherein the gas stream ( 13 ) from the top of DC is cooled in a heat exchanger (E 4 ) using either process cold streams ( 20 A) and external refrigeration stream (ER 2 ) in the temperature range of minus 150-minus 185° C. (or process cold streams ( 20 A) in the temperature range of minus 140-minus 165° C. 9 . The process as claimed in claim 1 , wherein stream 20 B is subjected to heat exchanger E 3 for its cold recovery prior to its routing to CUGS. 10 . The process as claimed in claim 1 , wherein external cold utility stream (ER 1 A) ( FIG. 2 ) from CUGS is used in multiple streams heat exchanger (E 3 ) to reduce stream ( 12 ) temperature in the range of minus 80-minus 120° C.