Abstract:
An improved process and apparatus is disclosed for rejecting nitrogen from a gaseous nitrogen-methane mixture while the nitrogen content of the mixture varies widely. The process, which is especially suited for recovery of nitrogen in an enhanced oil reservoir flooding project which employs nitrogen for flooding the reservoir; utilizes a modified dual distillation column arrangement including a relatively high pressure fractionator which lacks a conventional reboiler and a low pressure fractionator which lacks a conventional overhead condenser for liquid reflux.

Description:
This invention relates to separating nitrogen and hydrocarbons in a normally gaseous mixture containing nitrogen in variable amounts. In one aspect it relates to an apparatus and a process employing a modified dual distillation column arrangement for rejecting nitrogen from a gaseous stream. In another aspect it relates to an improved method for recovering nitrogen from a hydrocarbon stream containing C 2  and heavier hydrocarbon components. 
     BACKGROUND OF THE INVENTION 
     Interest in separation and recovery of nitrogen from a hydrocarbon gas stream, which contains variable amounts of nitrogen, comes primarily from recovery of nitrogen from gas streams associated with enhanced oil recovery (EOR) projects employing nitrogen for miscible flood of oil reservoirs. In these miscible flooding projects a nitrogen rejection unit (NRU) for producing a nitrogen product pure enough to allow the recovered nitrogen to be reinjected into the oil reservoir is required. In addition the NRU must have capacity for handling the gaseous feed mixture with a minimum of equipment changes while the nitrogen content of the recovered gas changes widely during the comparatively long life of the enhanced recovery project, and also while providing a fuel gas product stream of acceptable heating value, for example 875 btu/scf. 
     In response to the nitrogen recovery problem associated with enhanced oil recovery projects, several methods of separating nitrogen from methane have been developed. A commonly used method employs an integrated dual distillation column arrangement in which a high pressure column provides a rough nitrogen/methane split and a low pressure column makes the specification product. Generally these prior art methods have been designed for gaseous mixtures having a relatively low concentration of heavy hydro-carbons and/or a relatively unchanging nitrogen concentration in the gaseous mixture being processed, and therefore require equipment changes during the duration of the enhanced oil recovery project to accommodate the changing levels of nitrogen present in the gas to be processed. 
     Accordingly, it is an object of this invention to provide an improved integrated dual distillation system for removing nitrogen from a gaseous mixture containing nitrogen and hydrocarbon components. 
     It is another object of this invention to provide an improved process for removing nitrogen from natural gas wherein the nitrogen concentration in the natural gas may vary from the naturally occurring concentration to as high as 75% or more. 
     It is yet another object of this invention to provide an improved process for treating a miscible flood gas wherein the miscible flood gas contains nitrogen along with a relatively high concentration of heavy hydrocarbons. 
     BRIEF SUMMARY OF THE INVENTION 
     In accordance with the present invention there is provided a method and an apparatus for improving process flow in an integrated dual distillation operation, which separates nitrogen and methane, in a system employing a high pressure (HP) fractionator and a low pressure (LP) fractionator, the method comprises the steps of: 
     (a) sufficiently cooling at least a portion a feedstream, essentially free of heavy hydrocarbons, comprising a gaseous nitrogen-methane mixture at a pressure of at least 400 psia so as to provide an at least partially condensed feedstream; 
     (b) separating said at least partially condensed feed stream in a first phase separator and withdrawing from said first phase separator a first stream comprising gaseous nitrogen-methane and a second stream comprising liquid nitrogen-methane, wherein said first stream is enriched in nitrogen and said second stream is enriched in methane; 
     (c) sufficiently cooling said first stream so as to provide an at least partially condensed first stream and introducing said at least partially condensed first stream into a middle portion of said HP fractionator; 
     (d) sufficiently expanding said second stream so as to provide an at least partially vaporized second stream and introducing said at least partially vaporized second stream into a lower portion of said HP fractionator, wherein said at least partially condensed first stream and said at least partially vaporized second stream are simultaneously fractionated in said HP fractionator at conditions sufficient to produce a third stream predosinately comprising gaseous nitrogen and a fourth stream predominately comprising liquid methane; 
     (e) sufficiently cooling said third stream so as to provide a partially condensed third stream; 
     (f) separating said partially condensed third stream in a second phase separator and withdrawing from said second phase separator a fifth stream predominately comprising liquid nitrogen and a sixth stream predominately comprising gaseous nitrogen; 
     (g) introducing said fifth stream into said HP fractionator as a liquid reflux; 
     (h) sufficiently cooling said sixth stream so as to provide an at least partially condensed sixth stream; 
     (i) separating said at least partially condensed sixth stream in a third phase separator and withdrawing a seventh stream predominately comprising liquid nitrogen and an eighth stream predominately comprising gaseous nitrogen from said third phase separator; 
     (j) introducing said seventh stream into a middle portion of said LP fractionator; 
     (k) expanding at least a portion of said eighth stream in an expander prior to introducing said eighth stream into an upper portion of said LP fractionator; 
     (l) recovering an overhead stream from said LP fractionator as a nitrogen product stream; 
     (m) withdrawing a bottom stream from said LP fractionator; and 
     (n) combining said bottom stream with said fourth stream to form a hydrocarbon product gas stream. 
     Further aspects and additional advantages of the invention will be apparent from the following detailed description of the preferred embodiment of the invention as illustrated by the drawings in which: 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a schematic diagram illustrating process flow for nitrogen rejection according to this invention in a system employing dual distillation columns. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     In treating a miscible flood gas, I have discovered an improved process for separating gaseous nitrogen and methane. As used herein a miscible flood gas is a mixture containing nitrogen, methane, ethane, some heavier hydrocarbon components and possibly some CO 2 , wherein the nitrogen content can vary widely during the comparatively long life of the enhanced recovery program. 
     In a preferred embodiment of the invention, CO 2  and heavy hydrocarbons are first removed from a miscible flood gas stream and the flood gas, now essentially free of heavy hydrocarbons, is passed to a dual distillation system employing a high pressure fractionator which utilizes an overhead liquid reflux but does not utilize a reboiler, and a low pressure fractionator which utilizes a reboiler but does not utilize an overhead liquid reflux. A high purity nitrogen stream and a high btu content hydrocarbon gas stream are produced in accordance with the present invention. 
     It will be appreciated by those skilled in the art that, since FIG. 1 is schematic only, many items of equipment which would be needed for successful operation of a commercial plant have been omitted for the sake of clarity. Such items of equipment would include, for example, temperature, flow and pressure measurement instruments and corresponding process controllers, pumps, compressors, additional heat exchangers, valves, etc. All these items would be provided in accordance with standard chemical engineering practice to maintain desired conditions throughout the process and are not necessary to describe the present invention. 
     The present invention is applicable to recovering nitrogen from a gaseous mixture in which the nitrogen content varies widely and wherein the gaseous mixture contains a significant concentration of C 2  and higher molecular weight hydrocarbon components. It is particularly applicable to treating miscible flood gas produced from enhanced oil recovery. This flood gas recovery results in processing a gas having considerable nitrogen dilution, with a nitrogen concentration often in excess of 70 mole %, and also having a significant concentration of C 2  and higher molecular weight hydrocarbons. 
     It should also be understood that the representative temperatures and pressures set forth herein, with relation to the description of the drawing and the examples, are illustrative only and are not to be considered as limiting. The particular temperatures and pressures utilized in a particular separation will be dependent upon the nature and composition of the feed stream, upon the particular heat exchange surface areas available and upon the initial temperatures and pressures of the feed stream. 
     Referring now to FIG. 1, a feed gas stream containing methane and nitrogen, and having a significant concentration of C 2  and heavier hydrocarbons, at a pressure of at least 450 psia and preferably at about 800 psia or more is fed to the nitrogen rejection system through conduit 3. The feed gas stream could have for its origin, for example, a gas stream produced in a miscible flooding for enhanced oil recovery, in which case it would contain a high and variable nitrogen loading, which could increase to 70 mole % or more during the life of the EOR project, along with a significant concentration of C 2  and heavier hydrocarbons. If necessary other easily condensible contaminants such as CO 2  or H 2  S which may be found in a gas produced in a miscible flooding would be removed by, for example, absorption prior to entering the nitrogen rejection process via stream 3. Generally the nitrogen concentration of the feed gas stream 3 varies from about 40% to about 70% over the life of the EOR project. 
     The feed gas flowing in conduit 3 is divided so that a portion of the feed gas flows in conduit 5, and this portion is cooled by heat exchange with cooled exiting gas streams in chiller 200. Chiller 200 is bypassed by conduit 4, and the relatively warm feed gas flowing in conduit 4 is combined with the cooled gas in conduit 6 to form a combined stream in conduit 7 which is blended to a temperature of about -60° F. The cooled and partially condensed gas flowing in conduit 7 is passed to a phase separator 204. From separator 204 a condensed liquid stream containing heavy hydrocarbons is withdrawn through conduit 8 and an uncondensed vapor stream is withdrawn through conduit 10. The condensed heavy hydrocarbon stream flowing in conduit 8 is elevated in pressure to the product gas pipeline pressure in conduit 9 and combined with the predominantly methane stream exiting the nitrogen rejection system in conduit 38, as will be explained more fully hereinafter. The uncondensed vapor stream in conduit 10, essentially free of heavy hydrocarbons, is divided so that a portion of the vapor flowing in conduit 10 passes through conduit 13 and is cooled by heat exchange with cooled exiting gas streams in chiller 206. 
     The temperature of the cooled and partially condensed gas exiting chiller 206 in conduit 14 is reduced as the nitrogen content of the feed gas increases as will be illustrated in the examples hereinafter. The cooled and partially condensed gas flowing in conduit 14 is passed to a phase separator 208. From separator 208 a condensed liquid stream is withdrawn through conduit 15. The liquid flowing in conduit 15 is expanded in expansion valve 209 and passed to the bottom of the high pressure (HP) fractionator 210 via conduit 16. An uncondensed vapor stream is withdrawn from separator 208 through conduit 18. The uncondensed vapor stream flowing in conduit 18 is cooled sufficiently in chiller 212 by heat exchange with cooled exiting gas streams so as to at least partially condense the vapor entering chiller 212 in conduit 18. The cooled and partially condensed gas stream exiting chiller 212 in conduit 19 is further cooled in passing through an expansion device such as expansion valve 213 and into conduit 20 from where the partially condensed gas is fed to a tray at or near the middle of the HP fractionator 210. 
     Chiller 206 and separator 208 are bypassed by the combination of conduits 11 and 12 and expansion valve 214. The uncondensed vapor flowing in conduit 11 is cooled and partially condensed in passing through valve 214, or other similar expansion device, into conduit 12. The predominantly vapor stream flowing in conduit 12 is combined with the predominantly liquid stream flowing in conduit 16 and the mixture enters the bottom of the HP fractionator via conduit 17. The predominantly vapor stream is provided via conduit 12 to the bottom of HP fractionator 210 so as to provide stripping vapors to increase the amount of nitrogen rejected by the fractionator 210. 
     The HP fractionator 210 is operated at conditions sufficient to produce an overhead fraction which is a nitrogen-enriched gas stream withdrawn through conduit 21, and a bottoms fraction which is a methane-enriched liquid stream withdrawn through conduit 50. The nitrogen enriched uncondensed vapor stream flowing in conduit 21 is cooled in chiller 216 by heat exchange with a reboiler stream for the low pressure (LP) fractionator 218. The thus cooled and partially condensed gas is withdrawn from chiller 216 via conduit 22 and passed to chiller 220 for further cooling and condensing by heat exchange with cooled exiting streams in chiller 220. The nitrogen-enriched vapor withdrawn from HP fractionator 210, which is now predominantly liquid after passing through chillers 216 and 220, is withdrawn from chiller 220 via conduit 23 and passed to phase separator 222. A liquid stream is withdrawn from separator 222 through the combination of conduits 24 and 25 and returned to HP fractionator 210 as a upper external liquid reflux via conduit 25. 
     A vapor stream is withdrawn from separator 222 via conduit 26 and passed to chiller 224 where the vapor stream entering the chiller 224 via conduit 26 is cooled and partially condensed before being withdrawn from chiller 224 via conduit 27. The thus cooled and partially condensed vapors are fed via conduit 27 to phase separator 226. A liquid stream is withdrawn from separator 226 via conduit 28 and passed through valve 228 into conduit 29 where the pressure is reduced so as to effect flashing of the liquid which is then fed to a tray at or near the middle of the LP fractionator 218 via conduit 29. An uncondensed vapor stream is withdrawn from separator 226 via conduit 30 and is passed to an expander, or similar expansion means, 230. The thus expanded and partially condensed vapors are withdrawn from expander 230 via conduit 31 and provided as the main feedstream for LP fractionator 218. This main feedstream is supplied to an upper portion of LP fractionator 218. 
     An overhead high purity nitrogen product stream and a bottoms high purity methane product stream are withdrawn from LP fraction-ator 218 at a pressure level of about 30 psia via conduits 42 and 32 respectively. The high purity methane stream flowing in conduit 32 is elevated in pressure and provided to conduit 33. A methane enriched bottoms stream still containing a significant amount of nitrogen is withdrawn from the HP fractionator 210 via conduit 50 at a pressure level of about 450 psia. A portion of the methane enriched stream flowing in conduit 50 is supplied to conduit 53 at a pressure level of about 450 psia and the remaining portion of the stream flowing in conduit 50 is elevated in pressure and supplied to conduit 52 at a pressure level of about 720 psia. 
     In a preferred embodiment of the invention, the cooled exiting streams flowing in conduits 42, 33, 52, and 53 are utilized to provide much of the refrigeration necessary in the separation steps by countercurrent flow heat exchange with incoming or internal streams in the nitrogen rejection system. Additional cooling for the feedstreams in chillers 200, 206, and 212 is provided by depressurizing the portion of the HP fractionator 210 bottoms stream flowing in conduit 53, exchanging heat with the feed streams, and then recompressing the stream to product gas pipeline pressure. 
     The high purity nitrogen stream flowing from LP fractionator 218 in conduit 42 is heated in chiller 224 by countercurrent flow heat exchange with the nitrogen stream from separator 222 which is flowing in conduit 26. The high purity nitrogen stream exits chiller 224 in conduit 43 and is then further heated in chillers 212, 206, and 200. As illustrated in FIG. 1 the high purity nitrogen stream exits chillers 212, 206, and 200 in conduits 44, 46, and 48 respectively. Conduits 45, 47, and 49 which respectively extend conducts 44, 46, and 48 are illustrated in FIG. 1 to correspond to the data presented hereinafter in Tables 1 and 2 giving the conditions of a composition the fluid flowing at these points in the process. 
     The high purity methane stream from LP fractionator 218 flowing in conduit 34 is heated by countercurrent flow heat exchange with an internal stream in chiller 212. After exiting chiller 212 via conduit 35 the high purity methane stream is combined with the portion of the methane enriched stream from HP fractionator 210 which is flowing in conduit 52. The thus combined stream flowing in conduit 36 is further heated and partially vaporized in chiller 206. After exiting chiller 206 in conduit 37 the combined stream is divided. A portion of the stream flowing in conduit 37 is supplied to conduit 38 and combined with the heavy hydrocarbon liquid stream flowing in conduit 9. The thus combined stream enters chiller 200 via conduit 39 where it is further heated and essentially vaporized in chiller 200, before exiting chiller 200 in conduit 40. 
     The remaining portion of the stream flowing in conduit 37 is supplied to conduit 71 and is depressurized across a valve or similar expansion device 232 and enters conduit 72 and chiller 200 where it is heated and vaporized by countercurrent flow heat exchange with the feed stream flowing in conduit 5. On exiting chiller 200 as a vapor in conduit 73, this stream is pressurized and cooled in a compressor 260 and is combined with the product gas stream 41 via conduit 69. 
     The portion of the methane enriched bottoms stream withdrawn from HP fractionator 210 in conduit 53 is divided to flow in conduits 54, 55, and 56. Streams 54 and 53 are depressurized across valves 234 and 236 respectively and the stream flowing in conduit 54 is then heated in chiller 220 by counter-current flow heat exchange with an internal stream and is then recombined in conduit 56. The stream flowing in conduit 56 is then heated and vaporized in the series of chillers 212, 206, and 200 via conduits 56, 58, and 60, respectively, and is then elevated in pressure in compressor 260 and combined with the high purity methane stream flowing in conduit 69 to provide a suitable pipeline gas. 
     The following examples are presented in further illustration of the invention and are not to be considered as unduly limiting the scope of this invention. 
     EXAMPLE 1 
     This example illustrates nitrogen rejection from a gaseous stream containing about 40 mole % nitrogen according to the improved process of this invention. The feedstream 3 is a gaseous stream having a com-position which might be found in a gas stream actually produced in a reservoir flood during a relatively early stage of an EOR project. 
     Table I, below, shows the composition, temperature, pressure, vapor fraction and mass flow rate which were calculated from heat and material balance considerations. The numbers in the left hand column of Table II refer to the conduits (or equivalently streams) designated by the corresponding reference numeral in FIG. 1. 
     EXAMPLE 2 
     This example illustrates nitrogen rejection from a gaseous stream containing about 70 mole % nitrogen according to the improved process of this invention. The feed stream is a gaseous stream having a composition which might be found in a gas stream actually produced in a reservoir flood during a relatively late stage of an EOR project. 
     Table II below shows the composition, temperature, pressure, vapor fraction, and mass flow rate which were calculated from heat and material balance considerations. The numbers in the left hand column of Table II refer to the conduits (or equivalently streams) designated by the corresponding reference numeral in FIG. 1. 
     
                                           TABLE I__________________________________________________________________________Conduit/Mole Fraction     °F.                      psia                         lb/day VaporStreamN.sub.2   C.sub.1      C.sub.2         C.sub.3            i-C.sub.4               n-C.sub.4                  Temp                      Press                         Flow   Fraction__________________________________________________________________________ 3   0.391   0.526      0.050         0.020            0.006               0.002                  75  725                         .616 E + 08                                1.0 5   0.391   0.526      0.050         0.020            0.006               0.002                  75  725                         .616 E + 08                                1.0 6   0.391   0.526      0.050         0.020            0.006               0.002                  -60 725                         .616 E + 08                                .961 7   0.391   0.526      0.050         0.020            0.006               0.002                  -61 700                         .616 E + 08                                .961 8   0.048   0.267      0.199         0.245            0.116               0.051                  -61 700                         .400 E + 07                                0 9   0.048   0.267      0.199         0.245            0.116               0.051                  -61 710                         .400 E + 07                                010   0.405   0.537      0.044         0.011            0.002               0.000                  -61 700                         .576 E + 08                                1.011   0.405   0.537      0.044         0.011            0.002               0.000                  -61 700                         .150 E + 07                                1.012   0.405   0.537      0.044         0.011            0.002               0.000                  -79 450                         .150 E + 07                                .99513   0.405   0.537      0.044         0.011            0.002               0.000                  -61 700                         .561 E + 08                                1.014   0.405   0.537      0.044         0.011            0.002               0.000                  -159                      700                         .561 E + 08                                .48015   0.268   0.626      0.080         0.022            0.003               0.001                  -159                      690                         .270 E + 08                                016   0.268   0.626      0.080         0.022            0.003               0.001                  -176                      450                         .270 E + 08                                .22017   0.274   0.621      0.078         0.021            0.003               0.001                  -173                      450                         .286 E + 08                                .27918   0.543   0.448      0.008         0.001            0.000               0.000                  -159                      690                         .290 E + 08                                1.019   0.543   0.448      0.008         0.001            0.000               0.000                  -183                      690                         .290 E + 08                                020   0.543   0.448      0.008         0.001            0.000               0.000                  -201                      450                         .290 E + 08                                .38921   0.900   0.100      0.000         0.000            0.000               0.000                  -224                      450                         .378 E + 08                                1.022   0.900   0.100      0.000         0.000            0.000               0.000                  -227                      445                         .378 E + 08                                .73023   0.900   0.100      0.000         0.000            0.000               0.000                  -230                      445                         .378 E + 08                                .29524   0.873   0.127      0.000         0.000            0.000               0.000                  -230                      440                         .221 E + 08                                025   0.873   0.127      0.000         0.000            0.000               0.000                  -230                      450                         .221 E + 08                                026   0.939   0.061      0.000         0.000            0.000               0.000                  -230                      440                         .157 E + 08                                1.027   0.939   0.061      0.000         0.000            0.000               0.000                  -232                      435                         .157 E + 08                                .72928   0.903   0.097      0.000         0.000            0.000               0.000                  -232                      435                         .418 E + 07                                029   0.903   0.097      0.000         0.000            0.000               0.000                  -305                       30                         .418 E + 07                                .49230   0.953   0.047      0.000         0.000            0.000               0.000                  -232                      435                         .115 E + 08                                1.031   0.953   0.047      0.000         0.000            0.000               0.000                  -306                       30                         .115 E + 08                                .68732   0.000   1.000      0.000         0.000            0.000               0.000                  -242                       30                         .474 E + 06                                033   0.000   1.000      0.000         0.000            0.000               0.000                  -241                      730                         .474 E + 06                                034   0.000   1.000      0.000         0.000            0.000               0.000                  -191                      730                         .474 E + 06                                035   0.000   1.000      0.000         0.000            0.000               0.000                  -191                      720                         .474 E + 06                                036   0.250   0.678      0.055         0.014            0.002               0.001                  -184                      720                         .266 E + 08                                037   0.250   0.678      0.055         0.014            0.002               0.001                  -74 720                         .266 E + 08                                .97838   0.250   0.678      0.055         0.014            0.002               0.001                  -74 720                         .266 E + 08                                .97839   0.235   0.647      0.066         0.031            0.011               0.004                  -70 710                         .306 E + 08                                .88240   0.235   0.647      0.066         0.031            0.011               0.004                  67  710                         .306 E + 08                                1.041   0.235   0.647      0.066         0.031            0.011               0.004                  67  700                         .306 E + 08                                1.042   0.990   0.010      0.000         0.000            0.000               0.000                  -305                       30                         .152 E + 08                                1.043   0.990   0.010      0.000         0.000            0.000               0.000                  -235                       28                         .152 E + 08                                1.044   0.990   0.010      0.000         0.000            0.000               0.000                  -191                       28                         .152 E + 08                                1.045   0.990   0.010      0.000         0.000            0.000               0.000                  -191                       26                         .152 E + 08                                1.046   0.990   0.010      0.000         0.000            0.000               0.000                  -74  26                         .152 E + 08                                1.047   0.990   0.010      0.000         0.000            0.000               0.000                  -74  24                         .152 E + 08                                1.048   0.990   0.010      0.000         0.000            0.000               0.000                  67   24                         .152 E + 08                                1.049   0.990   0.010      0.000         0.000            0.000               0.000                  67   22                         .152 E + 08                                1.050   0.256   0.670      0.057         0.014            0.002               0.001                  -185                      450                         .419 E + 08                                051   0.256   0.670      0.057         0.014            0.002               0.001                  -185                      450                         .261 E + 08                                052   0.256   0.670      0.057         0.014            0.002               0.001                  -184                      720                         .261 E + 08                                053   0.256   0.670      0.057         0.014            0.002               0.001                  -185                      450                         .158 E + 08                                054   0.256   0.670      0.057         0.014            0.002               0.001                  -253                       38                         .158 E + 08                                .39855   0.256   0.670      0.057         0.014            0.002               0.001                  -244                       38                         .158 E + 08                                .60256   0.256   0.670      0.057         0.014            0.002               0.001                  -246                       36                         .158 E + 08                                .60557   0.256   0.670      0.057         0.014            0.002               0.001                  -191                       36                         .158 E + 08                                .93958   0.256   0.670      0.057         0.014            0.002               0.001                  -192                       34                         .158 E + 08                                .94059   0.256   0.670      0.057         0.014            0.002               0.001                  -74  34                         .158 E + 08                                1.060   0.256   0.670      0.057         0.014            0.002               0.001                  -74  32                         .158 E + 08                                1.061   0.256   0.670      0.057         0.014            0.002               0.001                  67   32                         .158 E + 08                                1.062   0.256   0.670      0.057         0.014            0.002               0.001                  67   30                         .158 E + 08                                1.069   0.256   0.670      0.057         0.014            0.002               0.001                  125 700                         .158 E + 08                                1.070   0.242   0.655      0.063         0.025            0.008               0.003                  86  700                         .464 E + 08                                1.071   0.250   0.678      0.055         0.014            0.002               0.001                  -74 720                         26600  .97872   0.250   0.678      0.055         0.014            0.002               0.001                  -137                      100                         26600  .97373   0.250   0.678      0.055         0.014            0.002               0.001                  67  100                         26600  1.0__________________________________________________________________________ 
    
     
                                           TABLE II__________________________________________________________________________Conduit/Mole Fraction     °F.                      psia                         lb/day VaporStreamN.sub.2   C.sub.1      C.sub.2         C.sub.3            i-C.sub.4               n-C.sub.4                  Temp                      Press                         Flow   Fraction__________________________________________________________________________ 3   0.681   0.276      0.026         0.011            0.003               0.001                  80  725                         .325 E + 08                                1.0 5   0.681   0.276      0.026         0.011            0.003               0.001                  76  725                         .325 E + 08                                1.0 6   0.681   0.276      0.026         0.011            0.003               0.001                  -60 725                         .325 E + 08                                .992 7   0.681   0.276      0.026         0.011            0.003               0.001                  -61 700                         .325 E + 08                                .992 8   0.064   0.127      0.127         0.242            0.172               0.090                  -61 700                         .468 E + 06                                0 9   0.064   0.127      0.127         0.242            0.172               0.090                  -61 710                         .468 E + 06                                010   0.686   0.277      0.026         0.009            0.002               0.001                  -61 700                         .320 E + 08                                1.011   0.686   0.277      0.026         0.009            0.002               0.001                  -61 700                         .512 E + 07                                1.012   0.686   0.277      0.026         0.009            0.002               0.001                  -75 450                         .511 E + 07                                .99813   0.686   0.277      0.026         0.009            0.002               0.001                  -61 700                         .269 E + 08                                1.014   0.686   0.277      0.026         0.009            0.002               0.001                  -170                      700                         .269 E + 08                                .92615   0.195   0.408      0.245         0.115            0.026               0.008                  -170                      690                         .209 E + 07                                016   0.195   0.408      0.245         0.115            0.026               0.008                  -178                      450                         .209 E + 07                                .11417   0.550   0.313      0.086         0.038            0.009               0.003                  -128                      450                         .721 E + 07                                .84118   0.724   0.267      0.008         0.000            0.000               0.000                  -170                      690                         .248 E + 08                                1.019   0.724   0.267      0.008         0.000            0.000               0.000                  -183                      690                         .248 E + 08                                .99120   0.724   0.267      0.008         0.000            0.000               0.000                  -202                      450                         .248 E + 08                                .87821   0.900   0.100      0.000         0.000            0.000               0.000                  -224                      450                         .476 E + 08                                1.022   0.900   0.100      0.000         0.000            0.000               0.000                  -227                      445                         .476 E + 08                                .70323   0.900   0.100      0.000         0.000            0.000               0.000                  -230                      445                         .476 E + 08                                .34424   0.869   0.131      0.000         0.000            0.000               0.000                  -230                      440                         .259 E + 08                                025   0.869   0.131      0.000         0.000            0.000               0.000                  -230                      450                         .259 E + 08                                026   0.938   0.062      0.000         0.000            0.000               0.000                  -230                      440                         .217 E + 08                                1.027   0.938   0.062      0.000         0.000            0.000               0.000                  -232                      435                         .217 E + 08                                .73128   0.900   0.100      0.000         0.000            0.000               0.000                  -232                      435                         .574 E + 07                                029   0.900   0.100      0.000         0.000            0.000               0.000                  -305                       30                         .574 E + 07                                .49230   0.951   0.049      0.000         0.000            0.000               0.000                  -232                      435                         .160 E + 08                                1.031   0.951   0.049      0.000         0.000            0.000               0.000                  -306                       30                         .160 E + 08                                .68932   0.000   1.000      0.000         0.000            0.000               0.000                  -242                       30                         .677 E + 06                                033   0.000   1.000      0.000         0.000            0.000               0.000                  -241                      730                         .677 E + 06                                034   0.000   1.000      0.000         0.000            0.000               0.000                  -211                      730                         .677 E + 06                                035   0.000   1.000      0.000         0.000            0.000               0.000                  -211                      720                         .677 E + 06                                036   0.189   0.742      0.047         0.016            0.003               0.001                  -195                      720                         .274 E + 07                                037   0.189   0.742      0.047         0.016            0.003               0.001                  -97 720                         .274 E + 07                                .90638   0.189   0.742      0.047         0.016            0.003               0.001                  -97 720                         .274 E + 07                                .90639   0.181   0.701      0.052         0.031            0.015               0.007                  -89 710                         .321 E + 07                                .80640   0.181   0.701      0.052         0.031            0.015               0.007                  54  710                         .321 E + 07                                .99241   0.181   0.701      0.052         0.031            0.015               0.007                  53  700                         .321 E + 07                                .99242   0.990   0.010      0.000         0.000            0.000               0.000                  -305                       30                         .210 E + 08                                1.043   0.990   0.010      0.000         0.000            0.000               0.000                  -235                       28                         .210 E + 08                                1.044   0.990   0.010      0.000         0.000            0.000               0.000                  -210                       28                         .210 E + 08                                1.045   0.990   0.010      0.000         0.000            0.000               0.000                  -211                       26                         .210 E + 08                                1.046   0.990   0.010      0.000         0.000            0.000               0.000                  -96  26                         .210 E + 08                                1.047   0.990   0.010      0.000         0.000            0.000               0.000                  -97  24                         .210 E + 08                                1.048   0.990   0.010      0.000         0.000            0.000               0.000                  54   24                         .210 E + 08                                1.049   0.990   0.010      0.000         0.000            0.000               0.000                  53   22                         .210 E + 08                                1.050   0.271   0.631      0.068         0.023            0.005               0.002                  -190                      450                         .103 E + 07                                051   0.271   0.631      0.068         0.023            0.005               0.002                  -190                      450                         .206 E + 07                                052   0.271   0.631      0.068         0.023            0.005               0.002                  -189                      720                         .206 E + 07                                053   0.271   0.631      0.068         0.023            0.005               0.002                  -190                      450                         .822 E + 07                                054   0.271   0.631      0.068         0.023            0.005               0.002                  -255                       38                         .822 E + 07                                .38655   0.271   0.631      0.068         0.023            0.005               0.002                  -232                       38                         .822 E + 07                                .79956   0.271   0.631      0.068         0.023            0.005               0.002                  -234                       36                         .822 E + 07                                .80157   0.271   0.631      0.068         0.023            0.005               0.002                  -211                       36                         .822 E + 07                                .88158   0.271   0.631      0.068         0.023            0.005               0.002                  -212                       34                         .822 E + 07                                .88259   0.271   0.631      0.068         0.023            0.005               0.002                  -96  34                         .822 E + 07                                1.060   0.271   0.631      0.068         0.023            0.005               0.002                  -97  32                         .822 E + 07                                1.061   0.271   0.631      0.068         0.023            0.005               0.002                  54   32                         .822 E + 07                                1.062   0.271   0.631      0.068         0.023            0.005               0.002                  53   30                         .822 E + 07                                1.069   0.271   0.631      0.068         0.023            0.005               0.002                  125 700                         .822 E + 08                                1.070   0.246   0.650      0.063         0.025            0.008               0.003                  102 700                         .114 E + 08                                1.071   0.189   0.742      0.047         0.016            0.003               0.001                  -97 720                         2740.  .90672   0.189   0.742      0.047         0.016            0.003               0.001                  -170                      100                         2740.  .92773   0.189   0.742      0.047         0.016            0.003               0.001                  54  100                         2470.  1.0__________________________________________________________________________ 
    
     The results indicated in Tables I and II show that the process of this invention maintains sufficient separation for feed streams widely varying in nitrogen content by maintaining the indicated process conditions, and that the inventive process will allow the use of nitrogen rejection units for providing sufficiently pure nitrogen for reinjecting in an EOR project. 
     It is to be understood that reasonable variations and modifications for various usages and conditions are possible by those skilled in the art, and such modifications and variations are within the scope of the described invention and the appended claims.