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Publication numberUS3380913 A
Publication typeGrant
Publication dateApr 30, 1968
Filing dateDec 28, 1964
Priority dateDec 28, 1964
Publication numberUS 3380913 A, US 3380913A, US-A-3380913, US3380913 A, US3380913A
InventorsHenderson Miles L
Original AssigneePhillips Petroleum Co
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Refining of effluent from in situ combustion operation
US 3380913 A
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Description  (OCR text may contain errors)

April 30, 1968 M. 1 HENDERsoN REFINING OF' EFFLUENT FROM IN SITU COMBUS'IION OPERATION Filed Dec. 28, 1964 VA E393@ A TTORNEVS United States Patent O 3,380,913 REFINING OF EFFLUENT FROM IN SI'IU `COMBUSTION OPERATION Miles L. Henderson, Bartlesville, Okla., assignor to Phillips Petroleum Company, a corporation of Delaware Filed Dec. 28, 1964, Ser. No. 421,189 2 Claims. (Cl. 208-187) ABSTRACT OF THE DISCLOSURE A hot, high pressure vapor-liquid mixture from an in situ combustion operation is charged to a sand trap and vapor-liquid separator to remove sand and recover a vapor stream of N2, H2O, and hydrocarbons boiling in the gas oil range and lower at relatively high pressure and temperature and a liquid stream of water and higher boiling hydrocarbons. The latter stream is flashed to separate an overhead vapor stream and a bottoms liquid stream of high boiling hydrocarbons and water in the form of an emulsion. This emulsion is broken into an overhead vapor stream, a bottoms stream of water, and a side stream of hydrocarbons boiling above the gas oil range. The overhead vapor stream from the sand trap and liquidvapor separator is reduced substantially in pressure and cooled and thereafter passed to a low temperature and low pressure zone to recover an overhead vapor stream of H2O, N2, CO, and CO2, a bottoms Water stream, and a side stream of hydrocarbons ranging from gas oil to normally gaseous hydrocarbons. The liquid side stream is fractionated to recover a normally gaseous hydrocarbon stream, a gasoline stream, a distillate stream, and a gas -oil bottoms stream. Apparatus for effecting the process is provided.

This invention relates to a process and apparatus for rening the high temperature and high pressure efliuent from a production well of an in situ combustion operation.

The production of oil from subterranean oil-bearing strata by in situ combustion is an established commercial operation. The produced effluent from such an operation conducted by direct drive of the combustion front is at an elevated temperature and pressure during that phase of the operation when the combustion zone is approaching the production well. During the entire period of a reverse burning operation, the produced eluent is at a relatively high temperature and pressure due to the fact that the fire front is initiated at the production well and, as the front moves radially outwardly therefrom, the hot combustion products and hydrocarbons pass thru only the hot sand or rock intermediate the fire front and the production well.

The hot eiuent from an in situ combustion process contains substantial concentrations of H2O, N2, CO, and CO2 in addition to hydrocarbons ranging from normally gaseous to heavy residual hydrocarbons. To illustrate, when producing in-place oil of about 8 to 10 API gravity by reverse burning, the oil is upgraded underground to about 26-27 API at 60 F.

The hot effluent from the production well in an in situ combustion operation contains such high concentrations of water and nitrogen that refining of the effluent near the wellhead or in the field being produced has numerous advantages over transporting the etliuent thru pipeline or other means to a distant refinery for processing.

This invention is concerned with an arrangement of apparatus and process for the refining of the hot high pressure eiuent from an in situ combustion processV near the wellhead,

Fice

Accordingly, it is an object of the invention to provide an improved process and arrangement of apparatus for refining the high temperature, high pressure effluent from an in situ combustion process effected in a subterranean deposit of oil. Another object is to provide a process and apparatus which removes water, nitrogen, and other nonhydrocarbon materials from an in situ combustion eflluent. A further object is to reduce the cost and time required for recovering hydrocarbons from an in situ combustion operation and to transport the hydrocarbon phase of such an operation to market. Other objects of the invention will become apparent to one skilled in the art upon consideration of the accompanying disclosure.

1n accordance with the invention the hot vapor-liquid mixture from a production well in an in situ combustion operation is charged to a sand trap and liquid-vaporseparator to remove sand and other solids from the stream and to recover a separate vapor stream comprising N2, H2O, and hydrocarbons boiling in the gas oil range and lower at relatively high pressure and temperature and a separate liquid stream comprising water and hydrocarbons boiling above the gas oil range. The liquid stream comprising water and high boiling hydrocarbons is ashed in a flashing zone or liash vessel to separate an overhead vapor stream and a bottoms liquid stream comprising principally high boiling hydrocarbons and water. This liquid stream in the form of an emulsion is then passed to an emulsion breaker to effect separation of same into an overhead vapor stream, a bottom water stream, and a side stream of residual hydrocarbons boiling above the gas oil range. The overhead vapor stream from the sand trap and liquid-vapor separator, containing principally H2O, N2, CO2, CO, and hydrocarbons ranging from gas oil to normally gaseous hydrocarbons, is substantially reduced in pressure and cooled before passing into a low temperature and low pressure separator to separate same into an overhead vapor stream comprising principally H2O, N2, CO, and CO2, a bottom water stream, and a side stream comprising principally hydrocarbons ranging from gas oil to normally gaseous hydrocarbons. This liquid side stream is fractionated in a conventional distillation column or fractionator to recover an overhead normally gaseous hydrocarbon stream, a stream of gasoline, a distillate side stream, and a bottoms gas oil stream.

In instances where the residual oil from the emulsion breaker is of high enough quality, a portion of this stream -is admixed with the liquid hydrocarbon stream passing into the fractionator to recover valuable lighter constituents therefrom, the heavier portions of this residual oil being recovered in the gas oil.

A more complete understanding of the invention may be had by reference to the drawing which is a process ow illustrating a preferred arrangement of apparatus in accordance with the invention.

Referring to the drawing, a production line 10 connects with the wellhead of a production well 12 of an in situ combustion eld operation. Line 10 leads into sand trap Vand liquid-vapor separator 14. Pressure in line 10 can be controlled within limits by means of vent line 16 containing a motor valve 18 under the control of a pressure controller 20 which is sensitive to pressure in line 10 Idownstre-am of line 16. Vessel 14 is an upright elongated vessel having overhead vapor line 22, a bottom outlet line 24 for sand, and line 26 for withdrawing a liquid side stream comprising principally water and hydrocarbons. Line 26 leads in dash vessel 2S and is provided with a motor valve 30 which is operated by liquid level controller 32 to maintain a suitable liquid level in vessel 14.

Vessel 28 has an overhead vapor line 34 and a bottom liquid line 36 which leads into an emulsion breaker 38 comprising 'an upright elongated vessel which is provided With a pair of liquid level .controllers 40 :and 42 for maintaining suitable levels of residual hydrocarbon and Water, respectively. An overhead vapor line 44 connects with line 34 and Vents thru line 46 under pressure controller 48 which operates motor valve 50. Level controller 42, which is sensitive to the interface level of the water and oil, operates motor valve l52 in eiuent water line 4 t-o maintain a suitable water level in the lower section of vessel 38. Level controller 40 manipulates a motor valve 56 in euent residual oil line 58 -to maintain a suitable selected hydrocarbon level .in vessel 38. Line 58 conducts recovered residual oil to storage or further refining, as desired.

Overhead vapor line 22 leads into line 60 which contains a pressure controller V62 operatively connected with a motor valve 64 for reducing pressure in said line to a predetermined level. Line 60 also contains a condenser or heat exchanger 66. Separator 68 is positioned at the downstream end of line 60 =to receive overhead feed from vessel 14, which contains a wide distribution of hydrocarbons in accordance with their boiling range from gas oil to normally gaseous hydrocarbons. Vessel 68 is provided with an overhead vapor line 70 in which is positioned a motor valve 72 which is operated by a pressure controller 74 to maintain `suitable backpressure on vessel 68. Water line 76 leads from the bottom of vessel I68 and liquid hydrocarbon line 78 conducts a side stream of liquid hydrocarbon into fractionator v80 as feed thereto. A suitable liquid level of Water is maintained in the lower section of vessel 68 by means of interface level controller 82 which is in control of m0- tor valve 84 in line '76. In la similar manner Ia suitablehydrocarbon level is maintained lin vessel 68 by means of level controller 86 which is in operative control of motor v-alve 88 in line 78.

fEractioniator 80, which is a conventional fractional distillation column, is provided with an overhead vapor line 90 containing la condenser 92 and leading into an accumulator 94. Line 96, leading from the bottom of accumulator 94, is provided with a pump 98 which forces gasoline as re'ux back to ythe upper section of -fractionator 80 thru line 100 and also passes gasoline thru line 102 to storage under the control of -level controller 104 which operatively controls valve l106 in line 102. Line r108 vents normally gaseous materials from accumulator 94 under the control of pressure controller [L10 and motor valve 112.

Distillate line 1'14 leads into accumulator 116 which is provided with an overhead vapor line 118 and a liquid outlet line 120 containing pump 122. Reliux line :124 leads from line 120 into column '80 and is provided with `a motor valve 126 which is operated by level controller 128 on accumulator 116. Distillate recovery line 130 leads to storage and is provided with a suitable backpressure valve 1132, when necessary, or pumping into a storage tank provides Athe necessary b-ackpressure.

A reboiler 134 in reboil line 136 provides reboil heat for column 80. Gas oil product line 138 connects with reboil line 136 intermediate reboiler 134 and a pump 140 therein and passes thru a heat exchanger -142 in line 78 to recover heat from the gas oil and preheat the feed in line 78. A by-pass line 144 around heat exchanger 1,42 provides for by-passing all or any desired proportion of the gas oil `around the exchanger.

Line 146 connects oil residue line 58 with line 78 .-to permit passing any desired amount of the residual oil into the hydrocarbon feed in line 78 passing into fractionator I80. Auxiliary line 148 connects line 10 with line 60 to provide for by-passing vapor from line 10 Ito line 60 yaround vessel 14 when desired.

In order to further illustrate the invention .the following example is presented. The data ytherein are not to be construed as unnecessarily limiting the invention.

' EXAMPLE Specific Ranges Well Fluid (line 10):

Quantity, #/hr 33, 874 Vapor, wt. Percent. 31. 8 Liquid, Wt. Percent. 68. 2 Oil, API at 60 F 26 Temperature, F Pressure, p.s.1.a Sand Trap and Liquid-Vapor Separator (14):

Temperature, F Pressure, p.s.i.a

ge, #/hL.

Temperature, F Pressure, p.s.1.a. Charge, #/hr Vapor-Steam Yield, #/hr Residue Oil, Yield, #/hr- API at 60 F Low Temperature-Low Pressure Water Separator (68):

Temperature, F Pressure, p.s.i.a Charge, #Ihr Vapor, wt. Percent..- Liquid, wt. Percent. Water Liquid Yield, #/hr Vapor Yield, #/hr Liquid Yield, #Ihr Fractionator (BO):

Temperature, Top, F

The above .data under the Specilic column illustrate preferred operation when 1relining the production Well euent from a reverse in situ combustion operation in an oil Ideposit in which the oil has an API gravity of about 8 to l0. This type has been upgraded by in situ combustion to 26-27 API gravity. Obviously, the inve -I tion is applicable to the refining of production Well effluent from substantially any in situ combustion operation which upgrades Ithe oil to the range of 20-35 API gravity. Usually the AZPI gravity of the irl-place oil will be in the range of about 8-20.

Certain modilications of the invention will become apparent to those skilled in the art and the illustrative details disclosed are not to be construed as imposing unnecessary limitations on the invention.

I claim:

1. A process for refining an eiflulent stream from a production Well of an in situ combustion operation wherein said stream is at a temperature of at least 300 F. and a pressure of at least 500 p.s.i.a, which comprises the steps of:

(a) passing said stream into a solids-liquid-vapor separating zone and separately recovering therein entrained solids, a vapor stream at a temperature in the range of 300 to 650 F. and a pressure in the range of 500 to 2000 p.s.i.a., and an unvaporized liquid stream at said temperature and pressure;

` (b) ashing the unvaporized liquid stream recovered in step (a) in a flashing zone at a temperature in the range of 230 to 350 F. and a pressure in the range of 25 to 150 p.s.i.a. to recover an overhead vapor stream and a liquid bottoms stream in the form of a liquid-vapor emulsion;

(c) separaitng the bottoms stream of step (b) in an emulsion breaking zone at substantially the same temperature and pressure as in step (b) into an overhead vapor stream, a bottom water stream, and a residual hydrocarbon side stream;

(d) passing the vapor stream of step (a) into a lowtemperature separation zone operated at a temperature in the range of to 150 F. and a pressure in the range of 50 to 150 p.s.i.a to separate same into an overhead vapor stream comprising principally steam, and a side stream of hydrocarbons ranging from normally gaseous thru gas oil; and

(e) fractionating the side stream of hydrocarbons of step (c) to recover separate streams of normally gaseous hydrocarbons, gasoline boiling range hydrocarbons, distillate, and gas oil.

2. The process of claim 1 wherein the stream of step (a) is from a reverse burning combustion front in an oil stratum containing a low API gravity oil and the oil in said stream has an API vgravity in the range of 20 to 35.

References Cited UNITED STATES PATENTS Shipley et al 208-187 Marx et al. 196-98 Walker et al 20S-'187 Woertz 260-676 Lenhart 20S-'187 X

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US2368497 *Aug 26, 1943Jan 30, 1945Standard Oil Dev CoHydrocarbon dehydration by distillation
US2933447 *May 13, 1957Apr 19, 1960Nat Tank CoMethods and means for resolving petroleum emulsion streams
US3014082 *Dec 23, 1959Dec 19, 1961Pure Oil CoMethod and apparatus for purifying and dehydrating natural gas streams
US3211643 *Oct 13, 1961Oct 12, 1965Oil Shale CorpProduction of oil from solid carbonaceous materials
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Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3782468 *Sep 20, 1971Jan 1, 1974Rogers Eng Co IncGeothermal hot water recovery process and system
US3809159 *Oct 2, 1972May 7, 1974Continental Oil CoProcess for simultaneously increasing recovery and upgrading oil in a reservoir
US4014575 *Jul 26, 1974Mar 29, 1977Occidental Petroleum CorporationSystem for fuel and products of oil shale retort
US4109718 *Nov 1, 1976Aug 29, 1978Occidental Oil Shale, Inc.Method of breaking shale oil-water emulsion
US4174751 *Jan 23, 1978Nov 20, 1979Occidental Oil Shale, Inc.By heating
US6588503Apr 24, 2001Jul 8, 2003Shell Oil CompanyIn Situ thermal processing of a coal formation to control product composition
US6609570 *Apr 24, 2001Aug 26, 2003Shell Oil CompanyIn situ thermal processing of a coal formation and ammonia production
US6729401 *Apr 24, 2001May 4, 2004Shell Oil CompanySynthesis gas may be produced from the formation. synthesis gas may be used as a feed stream in an ammonia synthesis process. ammonia may be used as a feed stream in a urea synthesis process.
US6923257 *Apr 24, 2002Aug 2, 2005Shell Oil CompanyIn situ thermal processing of an oil shale formation to produce a condensate
US6994168Apr 24, 2001Feb 7, 2006Scott Lee WellingtonIn situ thermal processing of a hydrocarbon containing formation with a selected hydrogen to carbon ratio
US7986869 *Apr 21, 2006Jul 26, 2011Shell Oil CompanyVarying properties along lengths of temperature limited heaters
WO2002085821A2 *Apr 24, 2002Oct 31, 2002Shell Oil CoIn situ recovery from a relatively permeable formation containing heavy hydrocarbons
WO2003040513A2 *Oct 24, 2002May 15, 2003Shell Oil CoIn situ thermal processing of a hydrocarbon containing formation
Classifications
U.S. Classification208/187, 166/267
International ClassificationE21B43/34
Cooperative ClassificationE21B43/34
European ClassificationE21B43/34