RU2003112686A

RU2003112686A - HYDROCARBON GAS TREATMENT

Info

Publication number: RU2003112686A
Application number: RU2003112686/06A
Authority: RU
Inventors: Джон Д. Уилкинсон; Хэнк М. Хадсон; Майкл С. Пирс
Original assignee: Элккорп
Priority date: 2000-10-02
Filing date: 2001-09-28
Publication date: 2004-11-20

Claims

1. An improved method for separating a gas stream containing methane, C ₂ components, C ₃ components and heavier hydrocarbon components into a volatile residual gas fraction containing a major portion of said methane and a relatively less volatile fraction containing a major portion of said C ₂ -components, -components C ₃ and heavier hydrocarbon components wherein (a) said gas stream is treated in one or more heat exchange stages to obtain at least a first feed stream which COOLING pressurized, (b) said cooled first feed stream is expanded to a lower pressure and then fed to a fractionating column at a higher feed point, and (c) said cooled expanded first feed stream is fractionated at said lower pressure, whereby components of said relatively less volatile fraction, where the improvement is as follows: (1) the liquid distillation stream is withdrawn from the specified fractionation column and heated, (2) the specified heated distillation stream to return to a lower point in the specified fractionation column, which is separated from the specified point of removal of at least one theoretical stage, and (3) the amount and temperature of the specified flows of raw materials supplied to the specified fractionation column are effective to maintain the top temperature of the specified fractionation column at a temperature at which the main parts of the components in the indicated relatively less volatile fraction are recovered.

2. An improved method for separating a gas stream containing methane, C ₂ components, C ₃ components and heavier hydrocarbon components into a volatile residual gas fraction containing a major portion of said methane and a relatively less volatile fraction containing a major portion of said C ₂ -components, C ₃ -components and heavier hydrocarbon components, in which (a) the specified gas stream is processed in one or more stages of heat transfer and at least one stage of separation to obtain at least a first feed stream that is cooled under pressure to condense substantially the entire stream, and at least a second feed stream that is cooled under pressure, (b) said substantially condensed first feed stream is expanded to a lower pressure, whereby it is further cooled and then sent to heat exchange with a warmer distillation stream that rises from the fractionation stages of the fractionation column, (c) said distillation stream is cooled by the first enough to partially condensate it, after which the specified partially condensed distillation stream is separated to obtain the indicated volatile residual gas fraction and the irrigation stream, while the specified irrigation stream is then sent to the specified fractionation column to the upper feed point, (d) the specified heated the first stream is fed to said fractionating column at a first midpoint of the column feed, (e) said cooled second feed stream is expanded to said lower pressure and then fed to said fractionating column to a second midpoint of column feed and (f) said irrigation stream, said heated first feed stream and said expanded second feed stream are fractionated at said lower pressure, whereby components of said relatively less volatile fraction are recovered, where the improvement is as follows: (1) the liquid distillation stream is withdrawn from the specified fractionation column and heated, (2) the specified heated distillation stream is returned to more than a thin point in said fractionating column which is separated from said withdrawal point by at least one theoretical stage, and (3) the amount and temperature of said feed streams supplied to said fractionating column are effective to maintain the top temperature of said fractionating column at a temperature at which recover the main parts of the components in the specified relatively less volatile fraction.

3. The improved method according to claim 1 or 2, wherein said liquid distillation stream is pumped out after removal from said fractionating column.

4. The improved method according to claim 3, where (a) said evacuated liquid distillation stream is separated into at least a first part and a second part, (b) said first part is heated and (c) said heated first part is returned to a lower point at the specified fractionation column, which is separated from the specified outlet by at least one theoretical stage.

5. The improved method according to claim 1 or 2, wherein said liquid distillation stream is sent to heat exchange with at least a portion of said gas stream or said feed streams to provide it with cooling and thereby heat said liquid distillation stream.

6. The improved method according to claim 3, wherein said evacuated liquid distillation stream is sent to heat exchange with at least a portion of said gas stream or said feed streams to provide it with cooling and thereby heat said evacuated liquid distillation stream.

7. The improved method according to claim 4, wherein said first part is sent to heat exchange with at least a part of said gas stream or said raw material streams to provide it with cooling and thereby heat said first part.

8. The improved method according to claim 1 or 2, where the amount and temperature of said heated distillation stream and the heating provided for said fractionating column are effective for maintaining the temperature of the bottom of said fractionating column at a temperature at which the amount of carbon dioxide contained in specified relatively less volatile fraction.

9. The improved method according to claim 3, where the amount and temperature of said heated distillation stream and heating provided for said fractionating column are effective for maintaining the temperature of the bottom of said fractionating column at a temperature at which the amount of carbon dioxide contained in said relatively less volatile fraction.

10. The improved method according to claim 4, where the amount and temperature of said heated first part and heating provided for said fractionating column are effective for maintaining the temperature of the lower part of said fractionating column at a temperature at which the amount of carbon dioxide contained in said relatively less volatile fraction.

11. The improved method according to claim 5, wherein the amount and temperature of said heated distillation stream and heating provided for said fractionating column are effective for maintaining the temperature of the bottom of said fractionating column at a temperature at which the amount of carbon dioxide contained in said relatively less volatile fraction.

12. The improved method according to claim 6, where the amount and temperature of said heated distillation stream and heating provided for said fractionating column are effective for maintaining the temperature of the bottom of said fractionating column at a temperature at which the amount of carbon dioxide contained in said relatively less volatile fraction.

13. The improved method according to claim 7, where the amount and temperature of said heated first part and heating provided for said fractionating column are effective for maintaining the temperature of the lower part of said fractionating column at a temperature at which the amount of carbon dioxide contained in said relatively less volatile fraction.