TH74669B - Hydrocarbon gas processing - Google Patents

Abstract

------ 03/01/2019 ------ (OCR) page 1 of number 1 page Invention summary. Processes and equipment for compact operation components used in assembling components. The c2 (or C3 component) and the heavier hydrocarbon components returned from the hydrocarbon gas stream are disclosed, with the gas stream being cooled and divided into the first and second currents. The first stream was further cooled to condense all of that first stream significantly, being expanded to that low pressure. And is supplied as top feeder to the adsorption path, the second current is expanded to lower pressure and fed to the bottom of the adsorption path. The vapor stream of the distillation from the adsorption path is heated by cooling the gas stream and the first stream. The liquid stream of the distillation from the adsorption path is fed to the heat and mass transfer path to heat the fluid stream and expel the volatile components of the fluid stream while the gas stream is applied. However, the absorption path and the heat and mass transfer path are in the assembly components. Action ------------ Process and equipment for compact recovery processing components. ingredient C2 (or C3 component) and heavier hydrocarbon components from the hydrocarbon gas stream were disclosed, with the gas stream being cooled and divided into the first, second, with the first being cooled to condense that first. The whole is actually expanded to the lower pressure and supplied as an upper shield to the adsorption device, and the second current is amplified to the lower pressure and supplied to the bottom of the suction device. As mentioned above, the vapor stream of the distillation from the adsorption device is heated by cooling the gas stream and the first stream.The liquid stream of the distillation from the adsorption device is fed to the heat and mass transfer device for the flow. The liquid heats and expels the volatile components of the fluid stream while cooling the gas stream. Adsorption devices and heat and mass transfer devices are in the processing assembly.

Claims (8)

Disclaimer (all) which will not appear on the advertisement page. : ------ 03/01/2019 ------ (OCR) Page 1 of the amount 15 pages Disclaimer 1. The process for separating methane streams, C2 components, C3 components and heavier hydrocarbon components into volatile residue gases and relatively less volatile residues with the main component C2, C3 constituents and heavier hydrocarbon components thereof. (1) The gas stream is divided into the first and the second (2). The first is cooled (3). The second is cooled. (4) The first such cooled stream is combined with the aforementioned second section cooled to form a stream of cooled gas (5). Such cooled gas stream is divided into the first and The second (6) current is cooled to significantly condense all of the first current and then is expanded to a lower pressure, where the first is further cooled. (7) The first cooled stream that was amplified was tilted upwards towards the absorbent path contained in the single-device operation assembly (8). It expands to higher eye pressure and is fed as a bottom feed to the adsorption pathway (9). The vapor stream of the distillation is collected from the upper area of the adsorption pathway and is Is heated in one or more of the heat exchanger pathways to allow cooling at least one part of the step ( 2) and (6) and thereafter release a stream of the aforementioned distillation vapor as the aforementioned volatile slurry gas portion (10) the liquid stream of the distillation is collected from the area below the path. It is absorbed and heated in the heat transfer path and mass contained in the components, such a single device operation to provide cooling at least one part of the procedure (3). While simultaneously evacuating the more volatile components from the liquid stream of the distillation. And thereafter discharges the liquid stream of the heated distillation and expelled the gas, page 2 of the aforementioned 15 pages from the assembly, doing so in the form of a relatively less volatile part, and (11) volume. And the temperature of the current! Such an inclination that is leaned towards the an absorbent path is effective in maintaining the temperature of the above area of the adsorption path. At the temperature, brew It is the point where the main parts or components in the relatively less volatile part are recovered 2. Claim 1 (a) the first such cooled part is combined with the aforementioned second to produce a partially condensed gas stream (b). The partially condensed gas stream is supplied to the junction and is separated in the junction so that at least one vapor and liquid stream (c) is divided into the first and And (d) at least one of the aforementioned liquid currents were expanded to the above impasse and were leaned as a substance! The adsorption method 3. A form of process pursuant to claim 2, (a) that first current is combined with at least one part of the liquid stream to form an aggregated current (b). It was cooled to significantly condense all of the combined currents, and then expanded to the lower pressure, where the combined currents were significantly lowered. (C) Such expanded combined currents are introduced as the top feed to the aforementioned route (d) any remainder. At least one part of the liquid flow is expanded to the above ocular pressure and is fired as the additional bottom filler to the And (e) the vapor stream of the aforementioned distillation is heated in one or more heat exchanger pathways to provide at least one part of cooling of steps (2) and (6). ) Page 3 of the number 15 pages 4. The defining process, according to claim 1, was (a) the first part was cooled and then expanded to higher ocular pressure (6). The expansion was! Leaned as a substance in the bottom to (C) the second part was cooled to significantly condense all of the second part, and then expanded to higher ocular pressure at the point where the fraction The second was further cooled. (D) The second such expanded cold was! (E) The vapor stream of the distillation is collected from the above area of the adsorption path and is heated in one or more heat exchange routes. Therefore, for cooling at least part of the steps (a) and (c) and (f), the liquid stream of the distillation is collected from the area below the path. It is absorbed and heated in the said heat and mass transfer path for cooling at least part of the step (c) 5. The pre-form process according to claim four (a) the first part was cooled enough to condense the first part (6) the first part that was partially condensed was dispensed. To the intersection and be split in The intersection path allows at least one vapor and liquid stream (c) to be expanded to the eye pressure. And was! Leaned as a bottom fumigate toward the aforementioned absorption path, and (d) at least one portion of the liquid stream was expanded to greater eye pressure. The substance is then leaned at the bottom more times to the aforementioned means. 6. The pre-form process according to claim 5 (0 the second part was cooled and thereafter combined with at least one part of the liquid stream to create The combined currents p. 4 of the 15 p. (Ii) The combined currents were cooled to significantly condense all of the summed currents, and thereafter expanded to the above pressure. \ 'Sung is the point \' where \ 'the aforementioned \' is further cooled. (Iii) The cooled summed current at such an expanded duct was! Leaned as a substance! (Iv) any residual And (v) the vapor flow of at least one such current is expanded to the above pressure and is introduced as an additional bottom feed to the said absorption path. The distillation is heated in a single heat exchanger. Or so for cooling at least part of steps (a) and (ii) 7. In accordance with claim 2, zong (1) such heat and mass transfer routes are arranged in the upper and lower regions, and (2) at least part of the fluid flow being The expansion was paid to The operation of the components to enter between the above and below areas of the thermal and mass transfer path. 8. The process according to claim 3, points (1) such heat and mass transfer routes are arranged in the upper and lower regions and (2) any remainder. At least one such amplified current is supplied to the component, doing so to enter between the above and below areas of the heat and mass transfer path. Such 9. In accordance with claim 5, (1) the thermal and mass transfer routes are arranged in the upper and lower regions and (2) at least one part of the liquid stream. The amplified current is supplied to the assembly, doing so to enter between the above and below areas of the thermal and mass transfer path, page 5 of the number. 15 pages 1 0. Process according to claim 6, where (1) such heat and mass transfer routes are arranged in the upper and lower regions and (2) any remainder. Of the liquid stream, at least one that is expanding It is supplied to the assembly, doing so to enter between the above and below areas of the thermal and mass transfer path.1 1. Process in accordance with Clause 2, 3, 5, 6, 7, 8, 9 or 10, any of the above-mentioned intersections is in the aforementioned action components 1 2. In accordance with claim 1, (1) the gas collection path is contained in the assembly, (2) the heat transfer path and additional masses are included within the gas collection path. The aforementioned thermal and mass pathways include one or more forward directions for the external cooling medium (3). Such cooled gas flows are supplied to the collection path. Such gas and It is directed to such additional heat and mass transfer paths to be further cooled by the said external cooling medium, and (4) that additional cooled gas stream is divided into the first. And the second such current 1 3. Process in accordance with claim 4 zong (1) gas collection path is contained in the assembly, (2) additional heat and mass transfer path is included within the gas collection path. The heat transfer and mass thereof, including the forward or more, for the external cooling medium (3), the first part to be cooled, is supplied to the collection path. Such gas and was It is directed to such additional heat transfer path and mass to be further cooled by the said external cooling medium and (4) the first such additional cooled part is expanded to pressure. That said, and after that it was introduced as a substance! Leaned on the bottom to the said absorbent path. Page 6 of the number 15 Page 1 4. Process according to any Clause 2, 3, 5, 6, 7, 9 or 10, the brew clause (1) additional heat transfer and mass pathways are included within the intersection. Brew the heat transfer path and the mass thereof, including one or more lines for the C \ '1, external cooling (2). Also the aforementioned thermal and mass transfer paths to be cooled by the said external cooling medium when creating additional condensate and (3) such additional condensate. Will become part of at least one of the aforementioned liquid flows separated within it.1 5. The process according to claim 11, sang (1) additional heat and mass transfer routes are included within the intersection. These heat and mass transfer routes include one or more lines for the external cooling medium (2). Such vapor flows are directed to additional heat and mass transfer routes. Such In order to be cooled by such external cooling medium to generate additional condensate and (3) such condensate becomes part of at least one such flow of liquid being separated inside it. 6. The process of claim 1, which implicates such heat and mass transfer routes, includes One or more lines for the external heating medium to enhance the heating by the aforementioned gas to evacuate the more volatile components from the liquid stream of the distillation. 1 7. The process of claim 11 implicates such heat and mass transfer routes, including one or more lines for the external heating medium to enhance the heating. Given by the said lean gas for the removal of the more volatile components from the liquid stream of the distillation page 7 of the number 15 page 1 8. The process according to claim 14 sets aside such heat and mass transfer routes, as well as the horizontal or more vertical directions for the external heating medium to complement the heating of the brew by such lean gas. For removal of the more volatile components from the liquid stream of the distillation 1 9. Process according to claim 15, in which such heat and mass transfer paths include, or so, for the external heating medium to enhance the heating by gas! As for removing the more volatile components from the liquid stream of the distillation 2 0. Equipment for separating methane streams, C2 components, C3 elements and heavier hydrocarbon components into volatile and relatively less volatile solvents that contain the primary component C2, C3 component and component. Heavier hydrocarbons Or a c3 component and a heavier hydrocarbon component. The song consists of (1) the first dividing path to divide the gas stream into the first and the second (2) the first heat exchanger path connected to the first divide to receive the first. (3) the heat and mass transfer path contained in the a single action component and connected to the aforementioned primary path. Second part (4) the combined pathway connected to the first heat exchanger and the heat and mass transfer path to receive the first part cooled. And the second that is cooled thereof and generates a stream of cooled gas. (5) A second shared path, connected to the said combined path, to receive such cooled gas stream and (6) The second heat exchanger is connected to the second such stream to obtain the first and the second to cool enough. Page 8 of the 15 p. (7) The first expansion path was connected to the aforementioned second heat exchanger path to obtain the first being condensed significantly. Significantly and significantly condensed first current expands to greater stiffness (8) the adsorption pathways present in the components, the said operations and that are welded. Connect with The first expansion path was said to receive the first cooled stream that was expanded as the top conductor to the absorbent path (9). Divide that second stream to get that second current and make that second flow to the limit. The said second expansion path was further connected to the said absorbent path to supply the said second expansion path. (10) The vapor collection path present in the operating components and which is connected to the said adsorption path to obtain the vapor flow of the distillation. (11) The second heat exchanger path was further connected to the storage path. Collect the said vapor to receive the said vapor stream and heat the said vapor stream for cooling at least part of the step (6) (12) of the first heat exchange path. It is further connected to the second heat exchanger method to receive the heated distillation vapor stream and further heat the heated distillation vapor stream to provide further heating. Cool for at least part of step (2) and then release the additional heated distillation vapor stream, ie the volatile solvent gas portion (13). The operating components and which are connected to the said adsorption pathways to receive the liquid stream of the distillation from the area below the adsorption path (14), the heat transfer path and the said mass. It is further connected to the collection method to receive the liquid stream of the said distillation and heat the liquid stream of the said distill to cool at least one part of the step ( 3) While removing the more volatile components from the liquid stream of the kettle Marin Tang said at the same time. And thereafter, pages 9 of the 15 pages release a fluid stream of the heated distillation and expel the said gas from the components, doing so is a relatively less volatile part and (15) path. A regulator adjusted to control the amount and temperature of the aforementioned air flow to the said absorption path to maintain the temperature of the upper area of the adsorption path at The temperature that is left is the peak at the core of the components. The relatively less volatile parts were recovered 2 1. Equipment according to claim 20, which (a) the combined route is adjusted to receive the said first and the second such cooled and to generate a partially condensed gas stream ( b) The junction is connected to the combined pathway to receive the partial condensed gas stream and separate some of the condensed gas streams into at least some of the vapor and liquid flows. (c) The second path is connected to the junction to receive the vapor and divide it into the first and second currents, and (d) the third expansion path. This junction is connected to at least part of the liquid stream and to at least part of the liquid stream to expand to Push the eyes over such The third expansion path was further connected to the adsorption path to supply at least one portion of the liquid stream. Leaning at the bottom more times into the above expansion path 2 2. Equipment according to claim 21, where (a) an additional combined path is connected to the aforementioned second-division path and that intersection to receive the first and at least part of the liquid current. (B) Such a second heat exchanger path is connected to that additional combined path to receive the combined current and make the combined current. Page 10 of the 15 p. (C) The first expansion path was connected to the aforementioned second heat exchanger path. Significantly condensed summed current and significantly condensed summed current to expand to greater stiffness (d). The first expansion path was said to receive the cooled condensed stream, said substance!, Leaned above it to the said absorption path (e), the third expansion path was welded. Connect with that intersection to receive any rest. Of at least one of the said currents and do the rest Of the liquid flow, at least one such current expands to the eye pressure The third expansion route was further connected to the said absorption path to supply any remainder. Of liquid flow At least some of the said amplified currents were added to the bottom of the expansion path, and (f) the second heat exchange path was further connected to the collection path. The vapor is used to receive the vapor stream of the distillate and heat the vapor stream for at least part of the cooling process of step (b) 2 3. Equipment according to claim 20, title (a) the second such heat exchanger path is connected to that heat and mass transfer path to receive the second part cooled and to perform the part. The second, then cooled, was further cooled sufficiently to significantly condense the second part. (6) The first such expansion path was connected to the second heat exchanger path. Such as to obtain the significantly condensed second part thereof, and to make the second significantly condensed so that it expands to a higher pressure (c) the absorption path is correct. Connected to the aforementioned expansion path to obtain the aforementioned chilled second part as a top feed to the aforementioned absorption path (d). Was connected to the first heat exchanger path It is said to get the first chilled part and make the first chilled to expand to the dread. The aforementioned second expansion path was further connected to the aforementioned sorbent path to supply the chilled first portion that was expanded as a bottom filler to the second expansion path. And page 11 of the 15 pages (e) the second such heat exchanger path was further connected to the said vapor collection path to receive the condensate vapor stream and to make the "Jungla" vapor stream. So cool to dumb cool dumb, at least part of step (a) 2 4. The equipment according to claim 23 zong (a) the first such heat exchanger path was adjusted to receive the first part and made the first one, dumb cold enough to condense the first part (b). The junction was connected to the first heat exchanger path to receive the partially condensed first and to separate the first part of the condensed conduit into one vapor and liquid stream. At least one current (c) the second amplification path is connected to the junction to receive the vapor and the mute vapor expands to the higher eye pressure. The second method of expansion was further coupled to the sorbent pathway to supply such an expanded vapor stream as a bottom charcoal to that second expansion path, and (d). A third expansion path is connected to that intersection to obtain at least the fraction of One or more of these flows, and at least one of these flows, expands to a greater pressure. The third expansion path was additionally connected to the adsorption pathway to supply at least one part of the liquid stream, at least one of the above expansion paths as a second passive. Into the way of expansion 2 5. Equipment according to claim 24, zong (a) the combined route was adjusted to connect to the said heat and mass transfer path and that intersection to receive the second chilled mute. And at least one part of the liquid current is generated as a combined current. (6) Such second heat exchange path is connected to the aforementioned combined pathway to obtain The combined currents and thus the summed currents are mute cold enough to significantly condense the summed currents p. 12 of the 15 p. (C) The first such expansion path was connected to The second heat exchanger path is given to obtain a significantly condensed condensed current and to make such a significantly condensed current to expand to a greater density (d). The adsorption path was connected to the first amplification path to receive the condensed current. The chilled aggregate that was expanded is an upward tilting substance to the aforementioned absorbent pathway (e) the third such expansion path is connected to that intersection to receive the remainder. Any Of at least one said liquid stream and do the rest Of at least one such flow of liquid to expand to the above density. The third expansion route was further connected to the absorption path to supply any remainder. Of liquid flow At least one such amplified current was added to the expansion path and (f) the second heat exchanger path was further connected to the vapor collection path. It is said to receive the vapor flow of the distillation and to do at least one part of the liquid stream that is heated to at least cooling Part of the step (6) 2 6. Equipment according to claim No. 21, (1) such heat and mass transfer paths are arranged in the upper and lower regions, and (2) the operating components are connected to the trajectory. The third expansion To accept at least one part of such amplified fluid stream, and carry at least one part of that expanded liquid flow between the sides Above and below such heat and mass transfer paths 2 7. Equipment according to claim 22, class (1) such heat and mass transfer paths arranged in the upper and lower regions, and (2) the aforementioned operating components are connected to The aforementioned third expansion way to get any rest. Thus, at least one of the above-mentioned liquid flows was expanded and page 13 of the number 15 preceded any rest. Of at least one such stream being amplified between the above and below areas of the thermal and mass transfer path 2 8. Equipment according to claim 24, where (1) such heat and mass transfer paths are arranged in the upper and lower regions, and (2) such action components are connected to The third expansion path to receive the amplified fluid flows. And directs at least one part of the liquid stream, at least one such amplified current, to between the above and below areas of the heat transfer path and the mass 2 9. In accordance with claim 25, (1) such heat and mass transfer routes are arranged in the upper and lower regions, and (2) the operating components are connected to the trajectory. The third expansion is used to receive the expanded liquid stream. And bring any rest Of one of the least amplified liquid flows between the above and below areas of the heat transfer path and the mass 3 0. Equipment according to Clause 21, 22, 24, 25, 26, 27, 28 or 29, any of the above. The intersection of the aforementioned intersection is contained in the components mentioned above 3 1. The equipment, according to claim 20, is (1) the gas collection path is contained in the assembly, (2) the additional heat and mass transfer path is integrated within the gas collection path. The aforementioned thermal and mass transfer routes include one or more forward directions for the external cooling medium (3). The gas collection path is connected to the combined pathway. Said to receive gas stream And to direct the aforementioned stream of gas to the said additional heat and mass transfer paths to be further cooled by the said external cooling medium, and page 14. Of the 15 pages (4), the second split path was adjusted so that it was connected to the gas collection path to receive the additional cooled gas stream and to divide the cooled gas stream. The addition of the said stream is the first and the second currents 3 2. The equipment according to claim 23 zong (1) the gas collection path is in the component parts, (2) the additional heat and mass transfer path is included within the gas collection path. The heat transfer path and the above additional masses include one or more lines for the external cooling medium (3). The gas collection path is connected to the heat exchanger path. The first part is to obtain the first cooled section and direct the first part of the coolant to the aforementioned additional heat and mass transfer paths to be further cooled by the cooling medium. And (4) the second amplified path was adjusted so that it was connected to the said gas collection path, to receive the additional cooled first part and to do the first that was cooled. Such additional cool To expand to the pressure that The second such expansion route was further connected to the aforementioned adsorption pathway to supply the additional cooled first portion that was expanded as a bottom filler to the aforementioned expansion path. The second said 3 3. Any equipment according to claim 21, 22, 24, 25, 26, 27, 28 or 29, the first (1) additional heat and mass transfer routes are included within the intersections as say These additional heat and mass transfer routes, including diagonals or more for the external cooling medium (2), are directed to additional heat and mass transfer routes. Such condensate is to be cooled by the external cooling medium to generate additional condensate and (3) the condensate becomes part of at least one of the internally separated liquid flows. Then page 15 of the number 15 page 3 4. Equipment according to claim 30 brew (1) additional heat transfer and mass pathways are included within such intersections, which the heat and additional mass transfer paths include, or Moreover, for the external cooling medium (2), the vapor stream is directed to the aforementioned additional heat and mass transfer paths to be cooled by such external cooling medium. To generate additional condensate and (3) that condensate becomes part of the liquid stream at least for the same flow that is separated within it.3 5. Equipment in accordance with Clause 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 31 or 32, the provisions of which such thermal and mass transfer paths include , Or so for the external heating medium to enhance the heating provided by such a second for the evacuation of the more volatile components from the liquid stream of the aforementioned distillation. 3 6 . Equipment according to claim 30, whose thermal and mass transfer paths include Divisions or more for the external heating medium to enhance the heating provided by such a second for the evacuation of the aforementioned more volatile components from the liquid stream of such distillation. 3 7. Equipment according to claim 33, whose thermal and mass transfer paths include one or more diagonals for the external heating medium to complement the heating, which provides The second part is for the removal of the more volatile components from the liquid stream of the distillation. 3 8. Equipment according to claim 34, whose thermal and mass transfer paths include, or so, for the external heating medium to complement the heating provided by the said second part. For removing the more volatile components from the current Liquid of such distillation ------------ ------ 06/06/2018 ------ (OCR) page 1 of the number 15 disclaimers 1. A process for separating methane streams, C2 components, C3 components and heavier hydrocarbon components into volatile residual gases. And relatively less volatile components containing the main component C2, C3 component and the heavier hydrocarbon component. Or C3 component and component The heavier hydrocarbons, in which (1) the gas stream is divided into the first and the second (2), the first is cooled (3), the second is cooled (4) the first. The aforementioned chilled was combined with the aforementioned second part that was so cooled. (5) The cooled gas stream is divided into first and second currents (6). The first currents are cooled to condense all of the first currents as Indeed, and then expands to a lower pressure, where the first currents are further cooled (7). The first cooled current to be expanded is fed above to the adsorption device. In a single piece of equipment processing assembly (8), such a second current was expanded to such a lower pressure and was searched. (9) Distillation vapors are collected from the top of the adsorption device. They are heated in one or more heat exchangers to provide At least one part of the steps (2) and (6) is cooled, and after that the vapor stream of the (10) The distillation fluid stream is collected from the bottom of the adsorption device. It is then heated in the heat transfer device and the mass present in the metamorphic component. Such a single device design to provide at least one part of the cooling process (3) while removing more volatile components from the liquid stream of such distillation on page 2 of the 15 p. The same, and after which the liquid stream of the heated distillation is heated and expelled thereof. And (11) the amount and temperature of the feed current fed to the adsorption device. It is effective in keeping the temperature of the above area of the sorbent at the temperature at which point the main part of the components. The relatively less volatile parts were recovered 2. A process based on claim 1, in which (a) the first cooled part is combined with such cooled second part to (B) This partially condensed gas stream is supplied to the separation equipment and separated in Such an isolation device to provide at least one vapor stream and at least one liquid stream (c) that vapor flow is divided into one such first and second currents and (d) at least one such liquid stream. One section was expanded to The pressure is lower than that and is fed a second time to the adsorption device. 3. A process pursuant to claim 2, in which (a) the first current is combined with at least one such fluid flow. (B) The combined currents are cooled to condense all of the combined currents. And then expanded to a lower pressure, at which the current is further cooled (c) the cooled combined current that is expanded is fed above it to (D) any residual Of at least one such stream The portion is expanded to a lower pressure and is fed a second time to the device. And (e) the vapor stream of the distillation is heated in a heat exchanger. Or more pieces for cooling at least one part of steps (2) and (b) and thereafter release such heated distillation vapors as the aforementioned volatile residual gas portions. Page 3 of the number 15 pages 4. A process according to claim 1, in which (a) the first part was cooled and then expanded to a lower pressure (b) the first cooled part that was expanded as (C) the second part is cooled to condense all of the second part as Indeed, and after that it was expanded to the aforementioned lower pressure, where the second part was done. The expanded second chilled (d) section was fed the top rod to the device. (E) The vapor stream of the distillation is collected from the upper rod area of the The adsorption device and is heated in one or more heat exchangers. Such distillation is required for cooling at least one portion of steps (a) and (c) and (f), the liquid stream of the distillation is collected from the lower shaft of Such adsorption devices and are heated in such heat and mass transfer devices to make Cool at least one part of step (c) 5. A process according to claim 4, in which (a) the first part was cooled enough to condense the first part of it, (b) the partially condensed first part was supplied to the separation equipment. And was split in The separation device is used to provide at least one vapor stream and at least one liquid stream (c). The vapor flow is expanded to a lower pressure. And was fed at the bottom of the first time And (d) at least one of the fluid flows is expanded to the The lower the pressure is and is fed at the bottom a second time to the adsorption device. 6. A process in accordance with claim 5, in which (i) the second is cooled and subsequently combined with a liquid stream. At least one of these currents to form a combined current page 4 of the 15 pages (ii) the combined currents are cooled to condense all of the combined currents. And after being inflated to a lower pressure at that point where the current (Iii) The aforementioned cooled aggregate was fed above it to (Iv) any residual Of at least one flow of liquid at least one part It is expanded to a lower pressure and is fed at the second end to the device. And (v) the vapor stream of the distillation is heated in a heat exchanger. Or more pieces to provide at least one of the cooling parts of steps (a) and (a) 7. Process according to claim 2, in which (1) such heat and mass transfer devices are arranged in the upper and lower regions and (2) at least one such flow of liquid is amplified. body It is supplied to the said processing component to enter between the upper and lower areas. The aforementioned bottom of the aforementioned thermal and mass transfer devices 8. Process according to claim 3, where (1) such heat and mass transfer devices are arranged in the upper and lower regions and (2) any remainder. That is amplified by at least one liquid stream It is supplied to the said processing assembly to enter between the top and The aforementioned bottom of the aforementioned thermal and mass transfer devices 9. Process according to claim 5, in which (1) such heat and mass transfer devices are arranged in the upper and lower regions and (2) at least one such flow of liquid is amplified. body It is supplied to the said processing component to enter between the upper and lower areas. The aforementioned bottom of the aforementioned thermal and mass transfer devices Page 5 of the number 15 Page 1 0. Process according to claim 6, in which (1) such heat and mass transfer devices are arranged in the upper and lower regions and (2) any remainder. That is amplified by at least one liquid stream It is supplied to the said processing assembly to enter between the top and The aforementioned bottom of the aforementioned thermal and mass transfer devices 1 1. Process according to claim 2, 3, 5, 6, 7, 8, 9 or 10, in which a separate device is included in the said processing component 1 2. Process according to claim 1, in which (1) the gas collection device is in the said processing component (2) additional heat and mass transfer equipment is included within the said gas collection device, where the heat transfer device And that mass includes one or more strands. For external cooling medium (3), such cooled gas stream is supplied to the said gas collection device and Were brought to the heat transfer device and the said additional mass to be further cooled by Such external cooling medium and (4) such additional cooled gas flows are divided into first and current The second such 1 3. Process according to claim 4, in which (1) the gas collection device is in the said processing component, (2) additional heat and mass transfer devices are included within the said gas collection device, where the heat transfer device is included. Hot, and such mass includes one or more strands For the external cooling medium (3), the first cooled part is supplied to the said gas collection device and Were brought to the heat transfer device and the said additional mass to be further cooled by The external cooling medium and (4) the first further cooled part is expanded to the aforementioned lower pressure and After that, it is fed at the aforementioned bottom to the adsorption device page 6 of the number 15 page 1 4. Process in accordance with any one of Clause 2, 3, 5, 6, 7, 9 or 10 in which (1) additional heat and mass transfer devices are incorporated within the said separation device. Where such heat and mass transfer devices include one or more lines for the medium External cooling (2) the vapor stream is directed to the additional heat and mass transfer device. In order to be cooled by such external cooling medium to create additional condensation fluid and (3) the condensed effect liquid become at least part of the liquid stream. One such stream that is internally isolated 1 5. Process according to claim 11, in which (1) additional heat and mass transfer devices are incorporated into such separation equipment. Where such heat and mass transfer devices include one or more lines for the medium External cooling (2) such vapor flows are directed to the additional heat and mass transfer equipment. In order to be cooled by such external cooling medium to create additional condensation fluid and (3) the condensed effect liquid become at least part of the liquid stream. One such current that is separated within it 1 6. The process according to claim 1, in which the thermal and mass transfer devices are Including one or more lines for the external heating medium to enhance the heating Heat, which is supplied by the feed gas for the removal of the more volatile components The liquid stream of such distillation 1 7. The process according to claim 11, in which such heat and mass transfer devices Including one or more lines for the external heating medium to enhance the heating Heat, which is supplied by the said feed gas for the removal of the more volatile components from the The liquid stream of such distillation 1 8. The process according to claim 14, in which the thermal and mass transfer devices are Including one or more lines for the external heating medium to complement the page 7 of the 15 hots provided by the said feed gas for the evacuation of the aforementioned more volatile components from The liquid stream of such distillation 1 9. The process according to claim 15, in which heat and mass transfer devices are Including one or more lines for the external heating medium to enhance the heating Heat, which is supplied by the feed gas for the removal of the more volatile components The liquid stream of such distillation 2 0. A type of device for separating methane, C2, C3 and heavier hydrocarbon components into volatile residual gases. And relatively less volatile components containing the main component C2, C3 component and the heavier hydrocarbon component. Or C3 component and component Heavier hydrocarbons It includes (1) the first divider to divide the gas stream into the first and the second (2) the first heat exchanger to be connected to the first shunt. To obtain the first part and cool the first part (3) the heat transfer device and the mass present in the molded processing component. One such device and that is connected to the first splitter to receive the second. (4) the combined equipment connected to the said first heat exchanger, and Such heat and mass transfer devices to get the first such cooled and the second (5) A second splitting device is connected to the combined device to receive the cooled gas stream. (6) The second heat exchanger is connected to the second shunt device. To receive the first current and cool it enough to condense it. The first is truly such (7) the first shin expansion device is connected to the second shin heat exchanger. To receive the first truly condensed current and to make the first truly condensed Indeed, it expands to a pressure lower than page 8 of a total of 15 pages (8). Adsorption devices contained in such processing components and which are connected to The first such expansion device to receive the first cooled current that was amplified as a feeding. (9) Second shunt device connected to the second shunt device to receive The second current and the second current expands to a lower pressure where the second expansion device is being further connected to the sorbent device to supply the second current. (10) The vapor-collecting device contained in the processing component and which was Connected to the siphon to receive a vapor flow of distillation from the top of the device. (11) Such a second heat exchanger that is being further connected to the device. The vapor is collected to receive the vapor stream of the distillate and produce the vapor stream. The heat exchanger is being heated to at least one part of the cooling process (6) (12) of the first such heat exchanger being added to the device. The aforementioned second heat exchanger to receive the steam stream of such heated distillation and perform The steam stream of such heated distillation is further heated to provide at least one part of the cooling process (2) and then release the further heated distillation vapor stream as shown in the figure. (13) the liquid collection device contained in the said processing component and That is connected to the adsorption device to receive the liquid stream of the distillation from the bottom of the (14) Such heat and mass transfer devices that are being further connected to the equipment. Collects the liquid to receive the liquid stream of the distillation and make the flow. At the same time, at least one part of the distillation is heated to cool at least one part of the step (3) while evaporating the more volatile components from the liquid stream of the distillation at the same time and then releasing a stream of liquid. Of the distillation that is heated and evicted from the Such processing components in the form of a relatively less volatile part and page 9 of the number 15 (15) a regulator adjusted to control the amount and temperature of the feed currents. Is fed to the sorbent device to maintain the temperature of the upper part of the device. It is absorbed at the temperature at which point most of the components are In the relatively volatile part Less than the above, was returned 2 1. A type of device pursuant to claim 20, in which (a) the combined equipment is adjusted to accept the said first and second (B) The connected separator is used to receive the condensed gas stream. Some of the above parts and separate some of the condensed gas flows into one vapor stream. (C) A second splitting device connected to the separator to receive the vapor flow. And (d) a third expansion device connected to the isolation device to receive the current. At least one of the aforementioned liquid flows, and conducts at least one liquid stream At least one part of the current expands to the lower pressure. Which expansion device The third is being further connected to the sorbent device to provide a stream of liquid. At least one such current is amplified as a second bottom feed. In the said expansion device 2 2. A type of device pursuant to claim 21 in which (a) a second combination device is connected to the said second shunt device and a separate device. To receive at least one such first current and at least one such current. (B). The second heat exchanger is connected to the second integrating device. Therefore, to receive the combined current and cool the combined current enough to condense. (C) The first such expansion device was connected to the heat exchanger. The second piece is said to receive a truly condensed combined current and to make a truly condensed current. It expands to a pressure lower than page 10 of 15 pages (d). The sorbent device is connected to the first such expansion device to receive current. (E) the third such expansion device is connected to the extraction device to receive the remainder. Any of at least one of the liquid flows and any residual of at least one of the liquid flows expands to a lower pressure. Which expansion device The third part is being further connected to the sorbent device to supply any residual of at least one such amplified liquid stream as a second feed. In the expansion device and (f) the second heat exchanger being additionally connected to the The vapor collection device is used to receive the vapor flow of the distillate and produce the distillate vapor stream. It is hot so that at least one heating of the yen is part of step (6) 2 3. A type of device according to claim 20 in which (a) such a second heat exchanger is connected to a transfer device. Heat and such a mass to get the second said cooled and do the second cooled. (B) The first expansion device is connected to the heat exchanger. Such a second shin to get the aforementioned truly condensed second part and make the second part that was truly condensed. The actual condensation is expanded to a lower pressure (c). The sorbent device is connected to the first expansion device to obtain The second expanded chilled part as above, as above feeding, to the aforementioned adsorption device (d). Such second expansion device was connected to the heat exchanger. The first one was to get the cold first part and make the first that was cooled. Expanding to a lower pressure The second expansion device is being added. With the aforementioned sorbent device to supply the aforementioned cooled first portion as a bottom feed. And (e) the second heat exchanger being additionally connected to the The vapor collection device is used to receive the vapor flow of the distillate and produce the vapor stream. Heat so that at least one part of the cooling process (a) page 11 of the number 15 page 2 4. A type of device according to claim 23 in which (a) the first such heat exchanger is connected to receive the first one. (B) A separate device is connected to the first part of the heat exchanger to obtain The first partially condensed and to separate the partially condensed first. (C) The second expansion device is connected to the decoupling device to receive the current. The vapor and the vapor flow to expand to a lower pressure. Which expansion device The second one is being further connected to the sorbent device to supply the expanded vapor flow. As shown in the figure, the butt feed to the second expansion device and (d) the third expansion device is connected to the shunt to receive current. At least one of the aforementioned liquid flows, and conducts at least one liquid stream At least one part of the current expands to the lower pressure, where the third expansion device is being further connected to the sorbent device to supply fluid. At least one such current was amplified as a second feed. In the said expansion device 2 5. A type of device according to claim 24, in which (a) the combined equipment is adjusted for connection to heat and mass transfer equipment. Thereof and the separation device to receive the second chilled part and the liquid flow At least one such current is generated and generates a combined current (b). A second such heat exchanger is connected to the combined device. To receive the combined current and cool the combined current enough to condense the current (C) The first expansion device was connected to the heat exchanger. The second one is to get the truly condensed currents and to make the combined currents. (D) The adsorption device is connected to the first such expansion device to receive current. (E) The third such expansion device was connected to the extraction device. To obtain any residual of at least one of the liquid flows and to do any remainder of at least one of the liquid flows to expand to a lower pressure. Which expansion device The third is being further connected to the sorbent device to supply any residual of at least one such amplified liquid stream as a second infeed into the And (f) a second such heat exchanger that is being further connected to the The vapor collection device is used to receive the vapor flow of the distillation and to conduct a reliable liquid flow. At least one such stream is heated to provide an integral cooling. At least one part of the step (6) 2 6. Equipment according to claim 21, in which (1) such heat and mass transfer devices are arranged in the upper and lower regions, and (2) such processing components are connected to the shin expansion device. three In order to receive at least one part of the amplified fluid stream, and Conduct at least one such stream of liquid being amplified to Between the above and below areas of the heat transfer device and the mass 2 7. Equipment according to claim 22, in which (1) such heat and mass transfer devices are arranged in the upper and lower regions, and (2) the said processing components are connected to the shin expansion device. three As mentioned to receive any rest That is amplified of at least one such fluid stream and leads any rest Of at least one such stream to between Above and below such mass and heat transfer devices 2 8. Equipment according to claim 24, in which (1) such heat and mass transfer devices are arranged in the upper and lower regions and page 13 of the number 15 (2) such processing components are connected. With the third expansion device In order to receive such an expanded liquid stream. And conduct at least one liquid stream There is at least one such expanded section between the above and below areas. Of heat transfer devices and their respective masses 2 9. Equipment according to claim 25, in which (1) the thermal and mass transfer devices are arranged in the upper and lower regions, and (2) the said processing components are connected to the expansion device that three Said to receive the expanded liquid stream. And bring any rest Of liquid flow Which is amplified at least one such stream to between the above and below areas of Thermal and mass transfer devices 3 0. Equipment according to Clause 21, 22, 24, 25, 26, 27, 28 or 29, either. Where the said separation device is in the said processing component 3 1. Equipment according to claim 20, in which (1) a gas-collecting device is included in the aforementioned processing assembly, (2) an additional heat and mass transfer device, is integrated within the collection device. Gases in which the aforementioned additional heat and mass transfer devices include one or more lines. For the external cooling medium (3), such a gas collection device is connected to the combined apparatus to receive current. The cooled gas is then directed to the heat transfer device. And the additional mass to be further cooled by the said external cooling medium; and (4) the second splitting device is adjusted so that it is connected to the gas collection device. Such as to receive that additional cooled gas stream and to divide the additional cooled gas stream. As mentioned as the first and the second currents 3 2. Equipment according to claim 23, in which (1) gas-collecting device is included in the said processing assembly, page 14 of the amount of 15 pages (2), additional heat and mass transfer devices are included within the collection device. Such gases in which the aforementioned additional thermal and mass transfer devices include one or more lines. For the external cooling medium (3), the gas collection device is connected to the heat exchanger. The first to receive the first chilled part and bring the first chilled to the Such additional heat and mass transfer devices to be further cooled by the conducting medium. And (4) the second expansion device was adjusted so that it was connected to the collection device. The gas to obtain the said additional cooled first section and to make the cooled first. Expanding to lower pressure Which the second expansion device is being further connected to Such adsorption device to supply the expanded first cooled portion thereof as a feeder. At the bottom to the second such expansion device 3 3. Any equipment according to Clause 21, 22, 24, 25, 26, 27, 28 or 29 in which (1) additional heat and mass transfer devices are included within the said isolation device. Which such additional heat and mass transfer devices include one or more lines for External cooling medium (2) the vapor stream is directed to the additional heat and mass transfer device. In order to be cooled by such external cooling medium to create additional condensation fluid and (3) the condensed effect liquid become at least part of the liquid stream. One current separated within it 4. Equipment according to claim 30, in which (1) additional heat and mass transfer devices are incorporated within the said separation device. Which such additional heat and mass transfer devices include one or more lines for External cooling medium (2) the vapor stream is directed to the additional heat and mass transfer device. In order to be cooled by such external cooling medium to create an additional condensation fluid and page 15 of the number 15 (3) the condensed liquid becomes at least part of the liquid stream. One such stream that is split within 3 5. Equipment according to Clause 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 31 or 32, any of the aforementioned thermal and mass transfer equipment includes a line. Genre or more for External heating medium to complement the heating provided by the aforementioned second part for Remove the more volatile components from the liquid stream of the distillation. 3. 6. Equipment according to claim 30, in which the equipment transfers heat and mass. Including one or more lines for the external heating medium to enhance the heating Heat, which is given by the aforementioned second for the removal of the more volatile components from the The liquid stream of such distillation 3 7. Equipment according to claim 33, in which such heat and mass transfer devices Including one or more lines for the external heating medium to enhance the heating Heat, which is given by the aforementioned second for the removal of the more volatile components from the The liquid stream of such distillation 3 8. Equipment according to claim 34, in which such heat and mass transfer devices Including one or more lines for the external heating medium to enhance the heating Heat, which is given by the aforementioned second for the removal of the more volatile components from the The liquid stream of the distillation ------------ 1. A process for separating gas streams containing methane. C2, C3 component and heavier hydrocarbon constituents form volatile residual gases and relatively less volatile components that contain the principal component of the C2 component, the C3 component and the heavier hydrocarbon component mentioned, or C3 component and the hydrocarbon component that Heavier than the foregoing, where (1) the aforementioned gas stream is divided into the first and the second (2) the first part is cooled (3) the second part is cooled (4). The aforementioned chilled first part is combined with the second chilled to form a chilled gas stream (5) .The aforementioned cooled gas stream is divided into first and second ( 6) The first of the above currents is cooled to condense all of them literally and then is expanded to a lower pressure, where the current is further cooled (7). The aforementioned expanded current is fed above to an adsorption device in the processing component (8). The second current is expanded to a lower pressure and is fed to the bottom to the device. (9) The vapor stream of the distillation is collected from the upper area of the The aforementioned adsorption device is heated in one or more heat exchanger to provide cooling at least one part of steps (2) and (6) and thereafter release the vapor stream of the distillation at (10) The distillation fluid stream is collected from the bottom of the aforementioned adsorption devices and heated in the heat transfer equipment and The mass contained in the aforementioned processing components for cooling at least one part of step (3) while simultaneously removing more volatile components from the liquid stream of the aforementioned distillation. And thereafter releasing a liquid stream of the heated distillation and expelled the aforementioned gases from the aforementioned processing components in relatively less volatile form than the foregoing and (11) volume and temperature. The infeed current fed to the aforementioned sorbent device is effective in maintaining the temperature of the aforementioned sorbent area at the temperature at which point the main part of the components. The relatively less volatile parts of the above were recovered