US3223157A - Oil recovery process - Google Patents

Oil recovery process Download PDF

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US3223157A
US3223157A US271649A US27164963A US3223157A US 3223157 A US3223157 A US 3223157A US 271649 A US271649 A US 271649A US 27164963 A US27164963 A US 27164963A US 3223157 A US3223157 A US 3223157A
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reservoir
oil
fraction
slug
gas
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US271649A
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James W Lacey
Horsfield Roland
Robert V Welch
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ExxonMobil Upstream Research Co
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Exxon Production Research Co
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    • EFIXED CONSTRUCTIONS
    • E21EARTH DRILLING; MINING
    • E21BEARTH DRILLING, e.g. DEEP DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B43/00Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
    • E21B43/34Arrangements for separating materials produced by the well
    • E21B43/40Separation associated with re-injection of separated materials

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  • This invention concerns an improved method of recovering oil from underground reservoirs.
  • the invention more especially, concerns an improved miscible displacementtype oil recovery process wherein a bank or slug of material miscible with the oil in a reservoir is used to displace oil from the reservoir.
  • the invention particularly relates to a slug-type miscible displacement process for recovering oil from an underground reservoir wherein the miscible slug comprises material obtained directly from the reservoir itself.
  • miscible displacement processes wherein a fluid, which is miscible With the oil in a given reservoir under the reservoir conditions of temperature and pressure, is injected into the reservoir so as to displace oil from the reservoir.
  • the displacing fluid is preferably miscible with the oil under such conditions to the extent necessary to form a single iluid phase with the oil.
  • a bank or slug' is formed in the reservoir about one or more input wells and is then driven through the reservoir toward one or more output wells by means of a suitable drive agent.
  • the bank or slug comprises between about one and thirty-live percent, and preferably between ve and fteen percent, of the hydrocarbon pore volume of the portion of the reservoir subjected to the process.
  • the size of the bank used in any given case may vary considerably, depending on the cost and availability of the materials used in the bank, the structure of the reservoir, the degree of increased recovery desired, etc.
  • the drive fluid or agent used to drive the bank r slug is, itself, normally substantially immiscible with the reservoir oil.
  • the operating conditions for the overall process, and the compositions of the drive iiuid and the miscible slug are preferably chosen such that the slug and the drive fluid form a single tluid phase.
  • the slug is not only completely miscible with the reservoir oil but also with the driving uid under the conditions of temperature, pressure, etc., prevailing within the reservoir. In other words, no phase interface is discernible between the reservoir oil and the miscible slug, nor between the slug and the fluid used to drive the slug.
  • LPG liquefied petroleum gas
  • propane is simply a hydrocarbon mixture consisting principally of propane and butane in liquied form.
  • LPG may also contain minor portions of ethane, pentanes, hexanes, and even heptanes.
  • a slug comprising volatile hydrocarbons is preferably driven by a gas (e.g., methane, natural gas, lean natural gas, or the like) which at the reservoir conditions of temperature and pressure form a single fluid phase with one another.
  • a gas e.g., methane, natural gas, lean natural gas, or the like
  • a reservoir must be operated at a pressure of at least about 1325 p.s.i. when the reservoir temperature is about F., if a single uid phase of the propane and the methane is to be achieved.
  • miscible displacement processes need large amounts of the materials required to establish miscibility with oil. This is true even when using small banks of such materials in small reservoirs. Since the materials must, in general, be injected during a relatively narrow interval of time, it has been necessary to transport large quantities of the materials by tank car, truck or the like to a reservoir site. The expense entailed in the purchase and transportation of the materials has naturally detracted very seriously from the economicsV of miscible displacement processes. It has also been necessary, in some instances, to use smaller banks or slugs of oilmiscible materials than it would otherwise have been desirable to use. Again, it has been generally necessary to limit the application of the miscible displacement processes to small portions of a reservoir, thereby making for serious inefficiencies.
  • miscible slug materials more readily available and at reduced cost for use in miscible displacement processes. It is a more particular object of the invention to avoid the need for transporting large quantities of such materials to a reservoir from distant points of supply. It is a further object of the invention to supply large quantities of miscible slug materials at the very time when such materials are needed in a miscible slug process, and to thereby permit the use of larger slug sizes and the treatment of larger portions of reservoirs.
  • the present invention makes attainment of the above objects possible by providing means for obtaining the materials needed to form the miscible slug of a slug-type miscible displacement process directly from the reservoir to be produced by the process. At the same time, iluids are injected into the reservoir in suicient quantity to maintain the reservoir pressure at a level suthcient to assure the desired miscible relationship within the reservoir.
  • the invention achieves the above objectives by first producing oil from a reservoir in quantities greater than actually desired for sale or use away from the reservoir. More particularly, the rate of production is selected, as will become more apparent later in this description, to maintain the desired rate of injection into the reservoir of the materials needed to form a miscible slug.
  • the oil thereby produced is ilashed, fractionated, or otherwise treated so as to recover at least three streams or fractions trorn the oil.
  • the iirst stream is essentially a lean natural gas comprising in the main methane with minor quantities of ethane, propane, nitrogen, and the like. Substantially very little, if any, hydrocarbons such as butanes or pentanes will normally be present in this stream.
  • the second stream comprises an enriched gas consisting primarily of intermediate volatile hydrocarons such as ethane, propane, and butanes. Quantities of other materials such as pentanes, hexanes, heptanes, carbon dioxide, and the like may also be present. These latter materials, however, will normally occur in only very minor quantities.
  • the third stream comprises simply the produced oil itself devoid of the materials removed in the first and second streams, above.
  • the separation of the three streams is carried out such that the second stream comprises a material which is miscible in all proportions with the reservoir oil under the conditions of temperature and pressure existing within the reservoir.
  • This stream is reinjected into the reservoir, at least in part, at one or more points spaced from the points at which oil is being produced from the reservoir.
  • At least a part of the residual or stripped oil streami.e., the third stream- is also reinjected into the reservoir during this period of operation.
  • This stream is injected at one or more points within the reservoir which are remote from the points of oil production and also the points of reinjection of the second stream.
  • the residual oil be reinjected so as not to be re-produced from the reservoir during the initial phase of production when the purpose of such production is to obtain the materials needed to form a miscible slug for use in the reservoir.
  • the reinjected oil come in contact within the reservoir with the reinjected second stream during this phase of the operation.
  • a portion of the residual oil may, of course, be sold or otherwise consumed as desired.
  • this oil Prior to reinjection of the residual oil into the reservoir, this oil is preferably contacted with the lean natural gas fraction so as to substantially saturate the oil with the gas. Any remaining portion of the lean gas may be reinjected into the reservoir, alone or in conjunction with the residual oil. Like the reinjected residual oil fraction, the lean gas fraction should be reinjected at a point rernote from the point or points of oil production as well as the point or points where the enriched gas fraction is reinjected. j
  • each bank thus formed should preferably be sulcient such that it will promote the recovery of oil from the reservoir upon traveling through the reservoir toward one or more output wells. It is particularly contemplated that each such bank be sufciently large to move entirely through the reservoir from its respective input well to its respective output well or wells.
  • each miscible slug or bank has reached the desired size, the recycling or reinjection of the residual oil fraction and the enriched gas fraction is stopped. At this point, the residual oil fraction may be sold or otherwise transported from the reservoir as is usually the practice in producing operations.
  • the enriched gas stream may also be similarly disposed of. At least a portion of the lean gas fraction, however, should be reinjected into the reservoir behind each miscible slug or bank so as to propel the slug or bank through the reservoir. It is essential, as noted earlier, that the reinjected lean gas form a single iiuid phase with the miscible slug.
  • the reservoir pressure must be maintained at a level sufficient to maintain the slug in a completely miscible relationship with both the reservoir oil and the lean gas.
  • some of the enriched gas fraction may be blended with the inert gas fraction so as to promote miscibility in the reservoir between the slug and the latter fraction.
  • the separation between the lean gas fraction and the enriched gas fraction may be altered so as to modify the composition of the lean gas fraction.
  • the volumes of fluids injected into a reservoir be sufficient, when viewed in light of the volumes of lluids produced from the reservoir, as to maintain the desired level of pressure within the reservoir. If, for any reason, the volume of reinjected fluids is insufficient atany time for this purpose, extraneous fluids may be also injected. For example, lean gas from an adjacent reservoir may be injected into the reservoir. Alternatively, water may be injected into the reservoir at a point suiciently remote from the various input and output wells so as not to interfere with the desired mechanisms and miscible relationships referred to above.
  • Water may be injected simultaneously with, or in sequence with, the lean gas used to drive a miscible slug through the reservoir.
  • the combined use of water and gas in this fashion has been indicated by workers in the art to improve the conformance of miscible displacement processes.
  • the combination of lean gas and water enables the miscible displacement process to sweep larger portions of a reservoir than would be possible with the lean gas alone.
  • While the present invention has general application to petroleum reservoirs, it is especially suited for reservoirs having characteristics allowing a high degree of gravity drainage.
  • a uid of low viscosity tends to travel faster through a porous medium than does a fluid of greater viscosity, other factors being equal. Therefore, in the case of a miscible displacement process where a slug of relatively low-viscosity material is used to drive a relatively viscous reservoir oil, the slug tends to linger ahead into the oil and lose its slug configuration. As a result, the benecial effect of the slug material is seriously diminished and may be lost altogether.
  • miscible slug to nger is particularly the case in substantially horizontal reservoirs. in tilted reservoirs or reservoirs having substantial vertical permeabilities, on the other hand, the tendency is substantially eliminated, since the miscible slug in addition to being less viscous than the reservoir oil is also lighter.
  • the fingering tendency of the slug is overcome or greatly reduced in view of the gravity effect tendingV to oat the slug above the reservoir oil.
  • the interplay of these two eifects and their magnitude have been discussed in a publication entitled Miscible Fluid Displacement in Porous Media, Lacey et al., Journal of Petroleum Technology, April 1958, page 76.
  • the drawing depicts a tilted reservoir 10 penetrated by output well 11 and input wells 12 and 16 which extend to the surface of the earth 13. Also depicted is a gas/oil separator 14 which may conveniently consist of a series of staged separators designed to release volatile constituents (e.g., casing head gas) from the produced reservoir oil at progressively lower pressures. Also shown is an oil/ gas contacting zone 15 and pumps or compressors, as the case may be, 17, 18, 19, and 2i).
  • a gas/oil separator 14 which may conveniently consist of a series of staged separators designed to release volatile constituents (e.g., casing head gas) from the produced reservoir oil at progressively lower pressures.
  • an oil/ gas contacting zone 15 and pumps or compressors as the case may be, 17, 18, 19, and 2i).
  • operation is started by producing reservoir oil through output well 11 to the surface of the earth.
  • the produced oil is separated in separation zone 14 to form a lean gas fraction, a rich gas fraction, and a residual or stripped oil fraction.
  • the residual oil ows through line 21 to gas/ oil contacting zone 15, where it is saturated with at least a portion of the lean gas fraction at an elevated pressure-preferably about reservoir pressure.
  • the lean gas reaches zone 1S by owing through line 22 and compressor 18 and line 23.
  • the saturated residual oil from zone 15 is returned to reser- fect through input well 16.
  • Input well 16 is located such that the reinjected residual oil is not again produced from the reservoir until late in the recovery process. In this way, it does not interfere with the formation of the miscible slug.
  • the rich gas fraction Upon entering reservoir 10 through well 12, the rich gas fraction collects in the vicinity of the input well to form a bank or slug 24 which forms a single fluid phase with the reservoir oil.
  • the composition of the rich gas it is necessary for the composition of the rich gas to be controlled to achieve this condition. This requires, in turn, that the separation between the lean gas and the rich gas also be controlled. It is preferred, of course, that the rich gas contain as much methane (or other normally lean gas constituents) as possible while still maintaining a completely miscible relationship between the slug 24 and the reservoir oil.
  • the rich gas fraction will comprise mainly hydrocarbons containing from two to four carbon atoms. Minor amounts of methane, pentanes, and hexanes may also be present. Carbon dioxide may also be present in this fraction, since this material frequently occurs in reservoir oils.
  • a portion of the residual oil from zone 14 may be sold, transported, or otherwise disposed of through line 26. Indeed, it is a characteristic of the invention that normal quantities of oil may be produced and marketed from a reservoir during the formation of the miscible slug 24. Generally speaking, it is contemplated that considerably more residual oil will be recycled to a reservoir in practicing this invention than is sold or transported away-so long as a miscible slug is in the process of being formed.
  • the recycle rate should preferably be suicient to be compatible with the rate at which rich gas is reinjected. It will ordinarily not be unusual to reinject five ⁇ or more times as much residual oil as is marketed.
  • Injection of the rich gas fraction into the reservoir through input well 12 is continued until the bank 24 reaches a preselected size.
  • the size may vary considerably from reservoir to reservoir, depending upon economic conditions, the relative magnitudes of the lingering and gravity effects of the slug relative to the reservoir oil, the distance between the input well 12 and the output well, etc.
  • the output well toward which the slug is driven may be well 11, but it may also be some other well or wells.
  • one or more intermediate wells may be used sequentially as output wells for the reservoir oil.
  • miscible slug 24 will normally be from about one to thirty-tive percent of the hydrocarbon volume of the portion of the reservoir 10 to be swept by the bank. It is particularly contemplated, however, that bank sizes between about live and ten percent of the hydrocarbon volume be employed. It is also preferred that the process be carried out in reservoirs where the ngering tendency of the bank through the reservoir oil is minimal-viz., in tilted reservoirs or reservoirs having substantial vertical permeability.
  • the lean gas is now injected through well 12 into the reservoir behind slug 24 so as to propel the slug through the reservoir and away from well 12.
  • slug 24 is shown to be driven by the lean gas toward output well 11.
  • the lean gas is injected into the reservoir 10 at a pressure suicient to maintain it in a single uid phase with the miscible slug 24.
  • the composition of the lean gas may be altered, as desired, to help insure this condition. For example, some of the material previously contained in the rich gas fraction may now be introduced into the lean gas fraction by altering the nature of the separation carried out in zone 14.
  • Thermal or catalytic cracking of the produced oil, or a component thereof, could be used to generate additional quantities of both lean gas and rich gas fractions.
  • a conventional arrangement for example, is to use a 200 to 300 p.s.i. separator followed by a 50 p.s.i. separator. In such an arrangement, lean gas would be taken as the overhead fraction from the first separator, and the rich gas fraction as the overhead fraction from the second separator.
  • Equipment of this type is frequently employed in the field to remove casing head gas from produced oil. Conventional gasoline distillation equipment, including fractionators and the like, may also be employed as desired.
  • the contacting zone 15 may consist of one or more conventional packed towers, bubble plate towers, or the like suitable for use in contacting gases and liquids. Anyl lean gas not absorbed by the residual oil upon contact of these two materials'in zone 15 may be recycled to compressor 18. Y
  • Reservoir 10 shown in the drawing does not have a gas cap; and in such a reservoir the enriched gas and lean gas fractions are preferably injected into the uppermost portions ot' the crest of the reservoir.
  • the enriched gas fraction is preferably injected substantially at the interface between the gas cap and the reservoir oil.
  • the miscible slug formed by the injection of such fraction is thereby located at the interface.
  • the lean gas fraction may subsequently be injected behind the slug.
  • the invention may be practiced using any suitable number and arrangement of wells. However, it is generally preferred, as indicated earlier, to select well patterns which tend to minimize fingering tendencies of the miscible slug.
  • the former fraction may, on ccasion, be in either the gaseous phase or the liquid phase at various points in the process of this invention.
  • the compressor 20 in some instances may be replaced by a pump.
  • the invention is especially adapted for use in reservoirs capable of operation at the pressures required for such operation. Operation at lower pressures is possible to the extent ordinarily that the miscible slug and the drive gas can be permitted to exist with a phase interface therebetween. While such a system is elective in improving the recovery of oil from a reservoir, it has the disadvantage of requiring larger quantities of drive gas than in the case where the drive gas and the slug materials form a single phase.
  • the present invention relates primarily to an improved gas-propelled, slug-type, miscible displacement process wherein said slug and said gas have compositions such that they form a single uid phase with one another at said reservoir temperature and under the operating reservoir pressure used to conduct such process.
  • the composition of the slug is also selected such that it forms a single fluid phase upon contact with said reservoir oil at the temperature of the reservoir and the operating pressure.
  • the selection of the operating pressure may depend to some extent on the compositions that are possible for the slug and the propelling gas.
  • crude oil is produced from a reservoir and fractionated at the surface of the earth so as to obtain a fraction comprising a mixture of hydrocarbons which upon contact with reservoir oil at the temperature of the reservoir and the reservoir operating pressure will form a single fluid phase with such oil.
  • This mixture in most cases will comprise hydrocarbons containing from 2 to 4 carbon atoms-ie., hydrocarbons which are normally gaseous at atmospheric ternperature and pressure (14.7 p.s.i.a. and 70 F.) but liqueable at atmospheric temperature.
  • This mixture of hydrocarbons upon separation from the produced reservoir oil, is reinjected into the reservoir through an input well spaced sufficiently from the point of production so as to form a bank of the mixture within the reservoir in the vicinity of the input well. Also during the first stage of the process, at least a portion of the remaining produced reservoir oil (includingV any gas) is reinjected into the reservoir through a second input Well which is spaced from the rst input well and also from the point of production so as not to interfere with the bank of hydrocarbons formed at the first input well, and also so as to not be re-produced from the reservoir until some time during the second stage of the process.
  • a second input Well which is spaced from the rst input well and also from the point of production so as not to interfere with the bank of hydrocarbons formed at the first input well, and also so as to not be re-produced from the reservoir until some time during the second stage of the process.
  • pressurizing fluid may be injected into the reservoir-again at a point remote from both the point of production and the rst input well--as may be necessary to maintain the desired operating pressure.
  • the pressurizing fluid may generally be any petroleum fraction, such as may be derivedfrom other parts of the reservoir in question or from an entirely different reservoir. It may also be water, inert gases such las producer gas, gases of cornbustion (as, for example, produced by burning natural gas), natural gas, nitrogen, carbon dioxide, and the like.
  • the first stage of the process is completed when the bank of hydrocarbons formed about the input well has reached the desired size-generally between about 5 and l5 percent of the hydrocarbon pore volume of the reservoir (or the portion of the reservoir to be processed).
  • the second stage of the process then begins by injecting the propelling gas into the reservoir through the input Well so as to drive the bank .toward a spaced output well. Reservoir oil displaced by the bank and the propelling gas is recovered from the reservoir through the output well.
  • the propelling gas is obtained from the recovered reservoir oil by any suitable separation technique, as described earlier.
  • the seperation is conducted such that the gas has a composition enabling it to form a single fluid phase upon contact with a mixture of hydrocarbons contained in the bank at the temperature of the reservoir and the operating pressure.
  • pressurizing fluid once again may be injected as necessary into the reservoir so as to maintain the reservoir at the desired operating pressure.
  • This pressurizing fluid may be injected through the same input well as the propelling gas so long as it does not interfere with the single uid phase relationship desired between the propelling gas and the hydrocarbon bank.
  • slugs of water be injected such that propelling gas-and not water-will normally be in direct Contact with the hydrocarbon bank.
  • a method of recovering oil. from an underground reservoir which comprises the steps of producing oil from the reservoir to the surface of the earth through an output well, separating the produced oil into a light gaseous fraction, a residual oil fraction, and an intermediate fraction, such that said fractions have compositions whereby said intermediate gaseous fraction will form a single tluid phase with said reservoir oil and also with said light gaseous fraction under the temperature and pressure conditions Within said reservoir, injecting said intermediate fraction into said reservoir through an input well spaced from said output well, injecting at least a portion of said residual liquid oil into said reservoir at a point removed from said output well and said input well, also injecting at least a portion of said light gaseous fraction into said reservoir at a point spaced from said output well and said input well, discontinuing the injection of said light gaseous fraction, said intermediate fraction, and said residual oil fraction after enough of said intermediate fraction has been injected to form a bank thereof within said reservoir adjacent said input well, and thereafter injecting said light gaseous fraction into said reservoir through said input well to drive said bank away from
  • a method of recovering oil from a subterranean reservoir which comprises the steps of: producing reservoir oil from said reservoir to the surface of the earth through an output well, fractionating said produced oil into a lean gas fraction, a residual oil fraction, and a rich gas fraction, said rich gas fraction having a composition such that it forms a single uid phase with said reservoir oil under the pressure and temperature conditions prevailing within said reservoir, injecting said rich gas fraction into said reservoir through a first input well spaced from said output well, injecting at least a portion of said residual oil fraction into said reservoir through a second input well spaced from said output well and said first input well, continuing the injection of said residual oil fraction and said rich gas fraction into said reservoir until the rich gas fraction thus injected is suicient to form a bank of said rich gas fraction in said reservoir in the vicinity of said first input well, thereafter ceasing the injection of said residual oil fraction and said rich gas fraction, and injecting a fiuid into said first input well so as to drive said bank of said rich gas fraction toward an output well spaced from said
  • a method of recovering oil from a subterranean oil reservoir which comprises the steps of: producing reservoir oil from said reservoir to the surface of the earth through an output well, separ-ating said reservoir oil into a first fraction comprising hydrocarbons containing between 2 and 4 carbon atoms, a second fraction containing materials boiling below said first fraction, and a third boiling above said first fraction, said first fractionl having a composition such that it exists in a single fiuid phase upon contact with said reservoir oil at the pressure and temperature conditions prevailing within said reservoir, injecting said first fraction into said reservoir through a first input well spaced from said output well, injecting at least a portion of said third fraction into said reservoir through a second input well spaced from said output well and said first input well, continuing the injection of said first and said third fractions into said reservoir until the amount of said first fraction thus injected is sufficient to form a bank of said first fraction within said reservoir adjacent said first input well, thereupon discontinuing the injection of said first and said third fractions, injecting a fiuid into said first input well
  • a method of recovering oil from a subterranean oil reservoir which comprises the steps of producing reservoir oil from said reservoir to the surface of the earth through a production well, separating from said reservoir oil a fraction comprising hydrocarbons boiling between about -85 C. and 0 C.
  • said fraction being adapted to have a composition such that it exists in a single fiuid phase with said reservoir oil under the pressure and temperature maintained within said reservoir, injecting said fraction into said reservoir through a first input well spaced from said production well, injecting at least a portion of the remainder of the produced reservoir oil through a second input well spaced from said production well and said first input well, continuing the injection of said fraction and said remainder of said produced oil into said reservoir until the amount of said fraction thus injected is sufiicient to form a bank of said fraction in the vicinity of said input well, thereafter ceasing the injection of said fraction and said remainder of the produced reservoir oil, and injecting a fluid into said first input well so as to drive said bank of said fraction toward an output well spaced from said first input well, and recovering oil from said output well.
  • a method as defined in claim 10 wherein said fluid comprises natural gas separated from oil recovered from said reservoir through said output well.
  • said fluid comprises a fraction of said produced reservoir oil which an output well, separating a mixture of said hydrocarbons from said produced oil such that said mixture will form a single fiuid phase with said reservoir oil at the temperature and pressure of said reservoir, injecting said mixture into said reservoir through an input well spaced from said output well so as to form a bank of said mixture in said reservoir in the vicinity of said input well, injecting at least a portion of the remainder of said produced oil into said reservoir and also injecting such additional pressurizing fiuid into said reservoir as may be necessary during the injection of said mixture and said produced oil to maintain said reservoir pressure.
  • a method of recovering oil from an underground oil reservoir by means of a gas-propelled slug-type miscible displacement process wherein said slug comprises hydrocarbons which are normally gaseous but liquefiable at about 70 F. the improvement which comprises: in a first stage of'said method forming said slug by producing reservoir oil from said reservoir to the earths surface through a first well, separating a mixture of said hydrocarbons from said produced reservoir oil which has a composition such that said mixture is completely miscible with said reservoir oil at the temperature and pressure maintained within said reservoir, injecting said mixture into said reservoir through an input well spaced from said first well in a quantity sufficient to form a slug of said mixture within said reservoir about said input well, in a second stage of said method injecting a propelling gas into said input well to force said slug toward a spaced output well, and recovering oil displaced by said slug through said spaced output well, said propelling gas being obtained by separating from the recovered oil a gaseous fraction which will form
  • a method of recovering oil from an underground oil reservoir which comprises the steps of producing oil from the reservoir to the surface of the earth through an output well, separating'said produced oil into a light gaseous fraction, an intermediate gaseous fraction, and a residual oil fraction such that said intermediate gaseous fraction has a composition whereby it is completely miscible With said reservoir oil under the temperature and pressure conditions existing Within said reservoir, injecting said intermediate gaseous fraction into said reservoir through an input well spaced from said output well in a quantity sufcient to establish a bank of said intermediate fraction Within said reservoir, injecting at least a portion of said residual oil fraction into said reservoir at a point remote from said output well and said input well, also injecting at least a portion of said light gaseous fraction into said reservoir at a point remote from said output well and said input well, discontinuing the injection of said intermediate gaseous fraction, said residual oil fraction, and said light gaseous fraction upon the formation of said bank, thereafter injecting at least a portion of said light gaseous fraction through said input well into said reservoir so as

Description

lib
Dec. 14, 1965 J, w. LAcEY ETAL 3,223,157
OIL RECOVERY PROCESS Filed April 9, 1965 RICH n /GAs INVENTORS.
ATTORN "/ff/ "f/ "//V "ff/ "l 7 James W. Lacey, Roland Horsfiela Robert V. Welch v f f r f d 5" LEAN GAS United States Patent 3,223,157 OIL RECOVERY PROCESS .lames W. Lacey, Edmonton, Alberta, and Roland Horsiield and Robert V. Welch, Calgary, Alberta, Canada, assignors, by mesne assignments, to Esso Products Research Company, a corporation ot Delaware Filed Apr. 9, 1963, Ser. No. 271,649
20 Claims. (Cl. 166-7) This invention concerns an improved method of recovering oil from underground reservoirs. The invention, more especially, concerns an improved miscible displacementtype oil recovery process wherein a bank or slug of material miscible with the oil in a reservoir is used to displace oil from the reservoir. The invention particularly relates to a slug-type miscible displacement process for recovering oil from an underground reservoir wherein the miscible slug comprises material obtained directly from the reservoir itself.
In recent years, the oil industry has been working with new and improved methods for recovering petroleum from underground reservoirs. A particularly attractive class of such methods consists of the so-called miscible displacement processes wherein a fluid, which is miscible With the oil in a given reservoir under the reservoir conditions of temperature and pressure, is injected into the reservoir so as to displace oil from the reservoir. The displacing fluid is preferably miscible with the oil under such conditions to the extent necessary to form a single iluid phase with the oil.
For various reasons, including those of economics, it has been the general practice in conducting a miscible displacement process to limit the amount of the oil-displacing agent used to a relatively small bank or slug. A bank or slug'is formed in the reservoir about one or more input wells and is then driven through the reservoir toward one or more output wells by means of a suitable drive agent. Normally speaking, the bank or slug comprises between about one and thirty-live percent, and preferably between ve and fteen percent, of the hydrocarbon pore volume of the portion of the reservoir subjected to the process. The size of the bank used in any given case may vary considerably, depending on the cost and availability of the materials used in the bank, the structure of the reservoir, the degree of increased recovery desired, etc.
The drive fluid or agent used to drive the bank r slug is, itself, normally substantially immiscible with the reservoir oil. However, the operating conditions for the overall process, and the compositions of the drive iiuid and the miscible slug, are preferably chosen such that the slug and the drive fluid form a single tluid phase. Thus, the slug is not only completely miscible with the reservoir oil but also with the driving uid under the conditions of temperature, pressure, etc., prevailing within the reservoir. In other words, no phase interface is discernible between the reservoir oil and the miscible slug, nor between the slug and the fluid used to drive the slug.
Materials that appear especially attractive for use in the miscible slug of a slug-type miscible displacement process include ethane, propane, and the butanes, pentanes, and mixtures of volatile hydrocarbons such as LPG. LPG (liquefied petroleum gas) is simply a hydrocarbon mixture consisting principally of propane and butane in liquied form. LPG may also contain minor portions of ethane, pentanes, hexanes, and even heptanes.
As noted above, the miscible slug in a miscible slug process is preferably completely miscible with the fluid which is used to propel the slug. Thus, a slug comprising volatile hydrocarbons (e.g., (l2-C4 hydrocarbons) is preferably driven by a gas (e.g., methane, natural gas, lean natural gas, or the like) which at the reservoir conditions of temperature and pressure form a single fluid phase with one another. Typically, in the case of a miscible slug consisting of propane and a drive gas consisting of methane, a reservoir must be operated at a pressure of at least about 1325 p.s.i. when the reservoir temperature is about F., if a single uid phase of the propane and the methane is to be achieved.
A number of speciiic forms of miscible displacement processes have been reported in the literature-see, for example, United States Patents 2,724,437; 2,724,438; and 2,880,801. These publications, in addition to describing specific forms of processes, also describe experimental procedures for determining how to insure completely miscible systems. Other publications of interest include Miscible Fluid Displacement-Prediction of Miscibility, A. L. Benham et al.; Petroleum Transactions, AIME (1960), volume 219, page 229', and British latent No. 696,524.
One of the great deterrents to the application or" miscible displacement processes has been the fact that such processes need large amounts of the materials required to establish miscibility with oil. This is true even when using small banks of such materials in small reservoirs. Since the materials must, in general, be injected during a relatively narrow interval of time, it has been necessary to transport large quantities of the materials by tank car, truck or the like to a reservoir site. The expense entailed in the purchase and transportation of the materials has naturally detracted very seriously from the economicsV of miscible displacement processes. It has also been necessary, in some instances, to use smaller banks or slugs of oilmiscible materials than it would otherwise have been desirable to use. Again, it has been generally necessary to limit the application of the miscible displacement processes to small portions of a reservoir, thereby making for serious inefficiencies.
It is, accordingly, a major object of the present invention to provide a more satisfactory means for making miscible slug materials more readily available and at reduced cost for use in miscible displacement processes. It is a more particular object of the invention to avoid the need for transporting large quantities of such materials to a reservoir from distant points of supply. It is a further object of the invention to supply large quantities of miscible slug materials at the very time when such materials are needed in a miscible slug process, and to thereby permit the use of larger slug sizes and the treatment of larger portions of reservoirs.
The present invention makes attainment of the above objects possible by providing means for obtaining the materials needed to form the miscible slug of a slug-type miscible displacement process directly from the reservoir to be produced by the process. At the same time, iluids are injected into the reservoir in suicient quantity to maintain the reservoir pressure at a level suthcient to assure the desired miscible relationship within the reservoir.
More specically, the invention achieves the above objectives by first producing oil from a reservoir in quantities greater than actually desired for sale or use away from the reservoir. More particularly, the rate of production is selected, as will become more apparent later in this description, to maintain the desired rate of injection into the reservoir of the materials needed to form a miscible slug. The oil thereby produced is ilashed, fractionated, or otherwise treated so as to recover at least three streams or fractions trorn the oil. The iirst stream is essentially a lean natural gas comprising in the main methane with minor quantities of ethane, propane, nitrogen, and the like. Substantially very little, if any, hydrocarbons such as butanes or pentanes will normally be present in this stream.
The second stream comprises an enriched gas consisting primarily of intermediate volatile hydrocarons such as ethane, propane, and butanes. Quantities of other materials such as pentanes, hexanes, heptanes, carbon dioxide, and the like may also be present. These latter materials, however, will normally occur in only very minor quantities.
The third stream comprises simply the produced oil itself devoid of the materials removed in the first and second streams, above.
The separation of the three streams is carried out such that the second stream comprises a material which is miscible in all proportions with the reservoir oil under the conditions of temperature and pressure existing within the reservoir. This stream is reinjected into the reservoir, at least in part, at one or more points spaced from the points at which oil is being produced from the reservoir.
At least a part of the residual or stripped oil streami.e., the third stream-is also reinjected into the reservoir during this period of operation. This stream, however, is injected at one or more points within the reservoir which are remote from the points of oil production and also the points of reinjection of the second stream. it is specifically intended that the residual oil be reinjected so as not to be re-produced from the reservoir during the initial phase of production when the purpose of such production is to obtain the materials needed to form a miscible slug for use in the reservoir. Nor should the reinjected oil come in contact within the reservoir with the reinjected second stream during this phase of the operation. A portion of the residual oil may, of course, be sold or otherwise consumed as desired.
Prior to reinjection of the residual oil into the reservoir, this oil is preferably contacted with the lean natural gas fraction so as to substantially saturate the oil with the gas. Any remaining portion of the lean gas may be reinjected into the reservoir, alone or in conjunction with the residual oil. Like the reinjected residual oil fraction, the lean gas fraction should be reinjected at a point rernote from the point or points of oil production as well as the point or points where the enriched gas fraction is reinjected. j
Reinjection of the lean gas, the residual oil, and the enriched gas fractions should be continued until a bank of the enriched gas is formed within the reservoir about the input Wells that are used to inject this material. The magnitude of each bank thus formed should preferably be sulcient such that it will promote the recovery of oil from the reservoir upon traveling through the reservoir toward one or more output wells. It is particularly contemplated that each such bank be sufciently large to move entirely through the reservoir from its respective input well to its respective output well or wells.
Once the size of each miscible slug or bank has reached the desired size, the recycling or reinjection of the residual oil fraction and the enriched gas fraction is stopped. At this point, the residual oil fraction may be sold or otherwise transported from the reservoir as is usually the practice in producing operations. The enriched gas stream may also be similarly disposed of. At least a portion of the lean gas fraction, however, should be reinjected into the reservoir behind each miscible slug or bank so as to propel the slug or bank through the reservoir. It is essential, as noted earlier, that the reinjected lean gas form a single iiuid phase with the miscible slug. To this end, the reservoir pressure must be maintained at a level sufficient to maintain the slug in a completely miscible relationship with both the reservoir oil and the lean gas. It will be apparent, of course, that some of the enriched gas fraction may be blended with the inert gas fraction so as to promote miscibility in the reservoir between the slug and the latter fraction. Alternatively, the separation between the lean gas fraction and the enriched gas fraction may be altered so as to modify the composition of the lean gas fraction.
Throughout the operation of the present invention, it is essential that the volumes of fluids injected into a reservoir be sufficient, when viewed in light of the volumes of lluids produced from the reservoir, as to maintain the desired level of pressure within the reservoir. If, for any reason, the volume of reinjected fluids is insufficient atany time for this purpose, extraneous fluids may be also injected. For example, lean gas from an adjacent reservoir may be injected into the reservoir. Alternatively, water may be injected into the reservoir at a point suiciently remote from the various input and output wells so as not to interfere with the desired mechanisms and miscible relationships referred to above. With respect to water injection, it is particularly contemplated that Water may be injected simultaneously with, or in sequence with, the lean gas used to drive a miscible slug through the reservoir. The combined use of water and gas in this fashion has been indicated by workers in the art to improve the conformance of miscible displacement processes. In other words, the combination of lean gas and water enables the miscible displacement process to sweep larger portions of a reservoir than would be possible with the lean gas alone.
While the present invention has general application to petroleum reservoirs, it is especially suited for reservoirs having characteristics allowing a high degree of gravity drainage. Thus, it is well known in the art that a uid of low viscosity tends to travel faster through a porous medium than does a fluid of greater viscosity, other factors being equal. Therefore, in the case of a miscible displacement process where a slug of relatively low-viscosity material is used to drive a relatively viscous reservoir oil, the slug tends to linger ahead into the oil and lose its slug configuration. As a result, the benecial effect of the slug material is seriously diminished and may be lost altogether.
The tendency of a miscible slug to nger is particularly the case in substantially horizontal reservoirs. in tilted reservoirs or reservoirs having substantial vertical permeabilities, on the other hand, the tendency is substantially eliminated, since the miscible slug in addition to being less viscous than the reservoir oil is also lighter. In other words, if a miscible slug is injected into the upper portion of such a reservoir and driven down through the reservoir, the fingering tendency of the slug is overcome or greatly reduced in view of the gravity effect tendingV to oat the slug above the reservoir oil. The interplay of these two eifects and their magnitude have been discussed in a publication entitled Miscible Fluid Displacement in Porous Media, Lacey et al., Journal of Petroleum Technology, April 1958, page 76.
This invention may be better understood by reference to the drawing which forms part of this application and illustrates the best mode contemplated for practicing the invention. The drawing depicts a tilted reservoir 10 penetrated by output well 11 and input wells 12 and 16 which extend to the surface of the earth 13. Also depicted is a gas/oil separator 14 which may conveniently consist of a series of staged separators designed to release volatile constituents (e.g., casing head gas) from the produced reservoir oil at progressively lower pressures. Also shown is an oil/ gas contacting zone 15 and pumps or compressors, as the case may be, 17, 18, 19, and 2i).
ln applying the process of the present invention to reservoir 10, operation is started by producing reservoir oil through output well 11 to the surface of the earth. Here, the produced oil is separated in separation zone 14 to form a lean gas fraction, a rich gas fraction, and a residual or stripped oil fraction. The residual oil ows through line 21 to gas/ oil contacting zone 15, where it is saturated with at least a portion of the lean gas fraction at an elevated pressure-preferably about reservoir pressure. The lean gas reaches zone 1S by owing through line 22 and compressor 18 and line 23. The saturated residual oil from zone 15 is returned to reser- Voir through input well 16. Input well 16 is located such that the reinjected residual oil is not again produced from the reservoir until late in the recovery process. In this way, it does not interfere with the formation of the miscible slug.
The ric'n gas fraction tlows through line 23, compressor 20, and input well 12 to reservoir 10. In those instances Where this fraction is in the liquid phase, compressor will, of course, ordinarily be a pump.
Upon entering reservoir 10 through well 12, the rich gas fraction collects in the vicinity of the input well to form a bank or slug 24 which forms a single fluid phase with the reservoir oil. As explained earlier, it is necessary for the composition of the rich gas to be controlled to achieve this condition. This requires, in turn, that the separation between the lean gas and the rich gas also be controlled. It is preferred, of course, that the rich gas contain as much methane (or other normally lean gas constituents) as possible while still maintaining a completely miscible relationship between the slug 24 and the reservoir oil. Generally speaking, the rich gas fraction will comprise mainly hydrocarbons containing from two to four carbon atoms. Minor amounts of methane, pentanes, and hexanes may also be present. Carbon dioxide may also be present in this fraction, since this material frequently occurs in reservoir oils.
During this phase of the process, a portion of the residual oil from zone 14 may be sold, transported, or otherwise disposed of through line 26. Indeed, it is a characteristic of the invention that normal quantities of oil may be produced and marketed from a reservoir during the formation of the miscible slug 24. Generally speaking, it is contemplated that considerably more residual oil will be recycled to a reservoir in practicing this invention than is sold or transported away-so long as a miscible slug is in the process of being formed. The recycle rate should preferably be suicient to be compatible with the rate at which rich gas is reinjected. It will ordinarily not be unusual to reinject five `or more times as much residual oil as is marketed.
Injection of the rich gas fraction into the reservoir through input well 12 is continued until the bank 24 reaches a preselected size. The size, of course, may vary considerably from reservoir to reservoir, depending upon economic conditions, the relative magnitudes of the lingering and gravity effects of the slug relative to the reservoir oil, the distance between the input well 12 and the output well, etc. The output well toward which the slug is driven may be well 11, but it may also be some other well or wells. For example, as the solvent slug 24 moves through the reservoir from well 12 toward well 11, one or more intermediate wells may be used sequentially as output wells for the reservoir oil.
The size of miscible slug 24 will normally be from about one to thirty-tive percent of the hydrocarbon volume of the portion of the reservoir 10 to be swept by the bank. It is particularly contemplated, however, that bank sizes between about live and ten percent of the hydrocarbon volume be employed. It is also preferred that the process be carried out in reservoirs where the ngering tendency of the bank through the reservoir oil is minimal-viz., in tilted reservoirs or reservoirs having substantial vertical permeability.
When the bank 24 has reached the desired size, the injection of residual oil through input well 16 and the injection of rich gas through input well 12 are stopped. The production of reservoir oil through output well 11 is reduced, as may be necessary, to provide only the amount of oil required for transmission through line 26. The rich gas is now sold or otherwise disposed of through line 32; or it simply may be reinjected in some other portion of the reservoir.
The lean gas is now injected through well 12 into the reservoir behind slug 24 so as to propel the slug through the reservoir and away from well 12. Referring speciflcally 'to the drawing, for example, slug 24 is shown to be driven by the lean gas toward output well 11. In any event, the lean gas is injected into the reservoir 10 at a pressure suicient to maintain it in a single uid phase with the miscible slug 24. The composition of the lean gas may be altered, as desired, to help insure this condition. For example, some of the material previously contained in the rich gas fraction may now be introduced into the lean gas fraction by altering the nature of the separation carried out in zone 14. It is normally preferred, however, that none of the major components of the rich gas be incorporated within the lean gas. lf additional fluids beyond the lean gas must be injected into reservoir 10 to maintain an adequate pressure therein, additional lean gas may be injected through input well 12 from line 30 from an extraneous source, another portion of the reservoir, or the like. Similarly, water may be injected through line 31 and input well 12 in conjunction with, or in sequence with, the lean gas. Alternatively, a uid such as water may be injected into the reservoir through an additional well, not shown in the figure. Such a well, for example, might be one located down dip from output Well 11.
While the embodiment of the invention described above and illustrated in the drawing constitutes the best mode contemplated for carrying out the invention, it will be apparent that various modifications may be practiced without departing from the spirit of the invention. Thus, some of the produced oil may be burned or cracked, on occasion, to generate suflicient lean or rich gas fractions for the practice of the invention. For example, some or all of the lean gas fraction may be burned with air to produce additional quantities of gas for injection into reservoir 10 through well 12. Such a gas would not, of course, ordinarily be as miscible with the s-olvent slug 24 as would the lean gas itself. However, such a gas could be injected into the reservoir after a substantial volume of lean gas itself had been injected. While such a gas might not be entirely miscible with the slug 24, it would be completely miscible with the lean gas.
Thermal or catalytic cracking of the produced oil, or a component thereof, could be used to generate additional quantities of both lean gas and rich gas fractions.
While the separation zone 14, as previously noted, is
-shown to be a single unit, various forms and combinations of apparatus may be employed for this purpose. A conventional arrangement, for example, is to use a 200 to 300 p.s.i. separator followed by a 50 p.s.i. separator. In such an arrangement, lean gas would be taken as the overhead fraction from the first separator, and the rich gas fraction as the overhead fraction from the second separator. Equipment of this type is frequently employed in the field to remove casing head gas from produced oil. Conventional gasoline distillation equipment, including fractionators and the like, may also be employed as desired.
The contacting zone 15 may consist of one or more conventional packed towers, bubble plate towers, or the like suitable for use in contacting gases and liquids. Anyl lean gas not absorbed by the residual oil upon contact of these two materials'in zone 15 may be recycled to compressor 18. Y
Reservoir 10 shown in the drawing does not have a gas cap; and in such a reservoir the enriched gas and lean gas fractions are preferably injected into the uppermost portions ot' the crest of the reservoir.
In those instances where a reservoir has a gas cap, the enriched gas fraction is preferably injected substantially at the interface between the gas cap and the reservoir oil. The miscible slug formed by the injection of such fraction is thereby located at the interface. The lean gas fraction may subsequently be injected behind the slug.
The invention may be practiced using any suitable number and arrangement of wells. However, it is generally preferred, as indicated earlier, to select well patterns which tend to minimize fingering tendencies of the miscible slug.
Depending on the composition of the enriched gas fraction and the manner in which it is separated from the residual oil fraction, the former fraction may, on ccasion, be in either the gaseous phase or the liquid phase at various points in the process of this invention. Thus, the compressor 20 in some instances may be replaced by a pump.
As pointed out earlier in this description, it is desired in the practice of the present invention to maintain the miscible slug employed therein in a single fluid phase with both the reservoir oil and the gas used to drive the slug. Accordingly, the invention is especially adapted for use in reservoirs capable of operation at the pressures required for such operation. Operation at lower pressures is possible to the extent ordinarily that the miscible slug and the drive gas can be permitted to exist with a phase interface therebetween. While such a system is elective in improving the recovery of oil from a reservoir, it has the disadvantage of requiring larger quantities of drive gas than in the case where the drive gas and the slug materials form a single phase.
To recapitulate briefly, the present invention relates primarily to an improved gas-propelled, slug-type, miscible displacement process wherein said slug and said gas have compositions such that they form a single uid phase with one another at said reservoir temperature and under the operating reservoir pressure used to conduct such process. The composition of the slug is also selected such that it forms a single fluid phase upon contact with said reservoir oil at the temperature of the reservoir and the operating pressure. Conversely, of course, the selection of the operating pressure may depend to some extent on the compositions that are possible for the slug and the propelling gas.
In a rst stage of the process, crude oil is produced from a reservoir and fractionated at the surface of the earth so as to obtain a fraction comprising a mixture of hydrocarbons which upon contact with reservoir oil at the temperature of the reservoir and the reservoir operating pressure will form a single fluid phase with such oil. This mixture in most cases will comprise hydrocarbons containing from 2 to 4 carbon atoms-ie., hydrocarbons which are normally gaseous at atmospheric ternperature and pressure (14.7 p.s.i.a. and 70 F.) but liqueable at atmospheric temperature. This mixture of hydrocarbons, upon separation from the produced reservoir oil, is reinjected into the reservoir through an input well spaced sufficiently from the point of production so as to form a bank of the mixture within the reservoir in the vicinity of the input well Also during the first stage of the process, at least a portion of the remaining produced reservoir oil (includingV any gas) is reinjected into the reservoir through a second input Well which is spaced from the rst input well and also from the point of production so as not to interfere with the bank of hydrocarbons formed at the first input well, and also so as to not be re-produced from the reservoir until some time during the second stage of the process.
During the first stage of the process, additional pressurizing fluid may be injected into the reservoir-again at a point remote from both the point of production and the rst input well--as may be necessary to maintain the desired operating pressure. The pressurizing fluid may generally be any petroleum fraction, such as may be derivedfrom other parts of the reservoir in question or from an entirely different reservoir. It may also be water, inert gases such las producer gas, gases of cornbustion (as, for example, produced by burning natural gas), natural gas, nitrogen, carbon dioxide, and the like.
The first stage of the process is completed when the bank of hydrocarbons formed about the input well has reached the desired size-generally between about 5 and l5 percent of the hydrocarbon pore volume of the reservoir (or the portion of the reservoir to be processed). The second stage of the process then begins by injecting the propelling gas into the reservoir through the input Well so as to drive the bank .toward a spaced output well. Reservoir oil displaced by the bank and the propelling gas is recovered from the reservoir through the output well. The propelling gas is obtained from the recovered reservoir oil by any suitable separation technique, as described earlier. The seperation is conducted such that the gas has a composition enabling it to form a single fluid phase upon contact with a mixture of hydrocarbons contained in the bank at the temperature of the reservoir and the operating pressure.
During the second stage of the process, pressurizing fluid once again may be injected as necessary into the reservoir so as to maintain the reservoir at the desired operating pressure. This pressurizing fluid may be injected through the same input well as the propelling gas so long as it does not interfere with the single uid phase relationship desired between the propelling gas and the hydrocarbon bank. Thus, if water is injected through the input well, it is preferred that slugs of water be injected such that propelling gas-and not water-will normally be in direct Contact with the hydrocarbon bank.
What is claimed is:
1. A method of recovering oil. from an underground reservoir which comprises the steps of producing oil from the reservoir to the surface of the earth through an output well, separating the produced oil into a light gaseous fraction, a residual oil fraction, and an intermediate fraction, such that said fractions have compositions whereby said intermediate gaseous fraction will form a single tluid phase with said reservoir oil and also with said light gaseous fraction under the temperature and pressure conditions Within said reservoir, injecting said intermediate fraction into said reservoir through an input well spaced from said output well, injecting at least a portion of said residual liquid oil into said reservoir at a point removed from said output well and said input well, also injecting at least a portion of said light gaseous fraction into said reservoir at a point spaced from said output well and said input well, discontinuing the injection of said light gaseous fraction, said intermediate fraction, and said residual oil fraction after enough of said intermediate fraction has been injected to form a bank thereof within said reservoir adjacent said input well, and thereafter injecting said light gaseous fraction into said reservoir through said input well to drive said bank away from said input well, and recovering oil displaced from said reservoir by said bank at a point displaced from said input well.
2. A method as defined in claim 1 wherein said portion of said residual oil fraction is contacted with said light gaseous fraction prior to injection into said reservoir.
3. A method as defined in claim 1 wherein additional fluid other than said light gaseous fraction, said intermediate fraction and said residual oil fractions is injected into said reservoir during said method as may be necessary to maintain said reservoir pressure.
4. A method of recovering oil from a subterranean reservoir which comprises the steps of: producing reservoir oil from said reservoir to the surface of the earth through an output well, fractionating said produced oil into a lean gas fraction, a residual oil fraction, and a rich gas fraction, said rich gas fraction having a composition such that it forms a single uid phase with said reservoir oil under the pressure and temperature conditions prevailing within said reservoir, injecting said rich gas fraction into said reservoir through a first input well spaced from said output well, injecting at least a portion of said residual oil fraction into said reservoir through a second input well spaced from said output well and said first input well, continuing the injection of said residual oil fraction and said rich gas fraction into said reservoir until the rich gas fraction thus injected is suicient to form a bank of said rich gas fraction in said reservoir in the vicinity of said first input well, thereafter ceasing the injection of said residual oil fraction and said rich gas fraction, and injecting a fiuid into said first input well so as to drive said bank of said rich gas fraction toward an output well spaced from said first input Well.
5. A method as defined in claim 4 wherein said fiuid comprises said lean gas fraction.
6. A method as defined in claim 5 wherein said rich gas fraction comprises liquefied petroleum gas and said lean gas fraction comprises natural gas, and said reservoir is maintained at a pressure sufficient to cause said rich gas fraction to form a single fiuid phase with said lean gas fraction and said residual oil fraction at the temperature of said reservoir.
7. A method of recovering oil from a subterranean oil reservoir which comprises the steps of: producing reservoir oil from said reservoir to the surface of the earth through an output well, separ-ating said reservoir oil into a first fraction comprising hydrocarbons containing between 2 and 4 carbon atoms, a second fraction containing materials boiling below said first fraction, and a third boiling above said first fraction, said first fractionl having a composition such that it exists in a single fiuid phase upon contact with said reservoir oil at the pressure and temperature conditions prevailing within said reservoir, injecting said first fraction into said reservoir through a first input well spaced from said output well, injecting at least a portion of said third fraction into said reservoir through a second input well spaced from said output well and said first input well, continuing the injection of said first and said third fractions into said reservoir until the amount of said first fraction thus injected is sufficient to form a bank of said first fraction within said reservoir adjacent said first input well, thereupon discontinuing the injection of said first and said third fractions, injecting a fiuid into said first input well so as to drive said bank toward a production well spaced from said first input well, and recovering the reservoir oil from said production well.
8. A method as defined in claim 7 wherein said fluid comprises said second fraction, and wherein said reservoir pressure is maintained sufficiently great to cause said second fraction and said first fraction to exist as a single fiuid phase upon contact at said reservoir temperature.
9. A method as defined in claim 8 wherein said reservoir pressure is maintained Aby the injection into said reservoir of fluids in addition to and other than said first, second and third fractions.
10. A method of recovering oil from a subterranean oil reservoir which comprises the steps of producing reservoir oil from said reservoir to the surface of the earth through a production well, separating from said reservoir oil a fraction comprising hydrocarbons boiling between about -85 C. and 0 C. at atmospheric pressure, said fraction being adapted to have a composition such that it exists in a single fiuid phase with said reservoir oil under the pressure and temperature maintained within said reservoir, injecting said fraction into said reservoir through a first input well spaced from said production well, injecting at least a portion of the remainder of the produced reservoir oil through a second input well spaced from said production well and said first input well, continuing the injection of said fraction and said remainder of said produced oil into said reservoir until the amount of said fraction thus injected is sufiicient to form a bank of said fraction in the vicinity of said input well, thereafter ceasing the injection of said fraction and said remainder of the produced reservoir oil, and injecting a fluid into said first input well so as to drive said bank of said fraction toward an output well spaced from said first input well, and recovering oil from said output well.
11. A method as defined in claim 10 wherein said fluid comprises natural gas separated from oil recovered from said reservoir through said output well.
12. A method as defined inclaim 11 wherein the pressure maintained within said reservoir is sufficient to cause said natural gas and said hydrocarbons to exist in a single fiuid phase upon contact at the temperature of said reservoir.
13. A method as defined in claim 12 wherein water is injected into said first input Awell in addition to natural gas.
14. A method as defined in claim 10 wherein said fraction comprises hydrocarbons containing from 2 to 4 carbon atoms.
15. A method as defined in claim -19 wherein said fluid .comprises a fraction of said produced reservoir oil which an output well, separating a mixture of said hydrocarbons from said produced oil such that said mixture will form a single fiuid phase with said reservoir oil at the temperature and pressure of said reservoir, injecting said mixture into said reservoir through an input well spaced from said output well so as to form a bank of said mixture in said reservoir in the vicinity of said input well, injecting at least a portion of the remainder of said produced oil into said reservoir and also injecting such additional pressurizing fiuid into said reservoir as may be necessary during the injection of said mixture and said produced oil to maintain said reservoir pressure.
17. In a method of recovering oil from an underground oil reservoir by means of a gas-propelled slug-type miscible displacement process wherein said slug comprises hydrocarbons which are normally gaseous but liquefiable at about 70 F., the improvement which comprises: in a first stage of'said method forming said slug by producing reservoir oil from said reservoir to the earths surface through a first well, separating a mixture of said hydrocarbons from said produced reservoir oil which has a composition such that said mixture is completely miscible with said reservoir oil at the temperature and pressure maintained within said reservoir, injecting said mixture into said reservoir through an input well spaced from said first well in a quantity sufficient to form a slug of said mixture within said reservoir about said input well, in a second stage of said method injecting a propelling gas into said input well to force said slug toward a spaced output well, and recovering oil displaced by said slug through said spaced output well, said propelling gas being obtained by separating from the recovered oil a gaseous fraction which will form a single fiuid phase with said mixture of hydrocarbons at the temperature and pressure conditions of said reservoir but which will form separate fluid phases with said reservoir oil at such conditions, injecting sufficient pressurizing fiuid into said reservoir during said first and second stages to maintain said reservoir pressure, said pressurizing fluid during said first stage including at least a portion of said produced reservoir oil remaining after the separation of said mixture of said hydrocarbons, said portion being injected into said reservoir at a point remote from said input well and said first well.
18. In a method of recovering oil from an underground oil reservoir by means of a gas-propelled slug-type miscible displacement process wherein said slug comprises hydrocarbons containing from 2 to 4 carbon atoms, and wherein said method is operated at a reservoir pressure such that the propelling gas forms a single fiuid phase with said hydrocarbons, the improvement which comprises: forming said slug in a first stage of said method. by producing reservoir oil from Said reservoir to the earths surface through a first well, separating a mixture of lsaid hydrocarbons from said produced reservoir oil of a composition such that said mixture forms a single ffuid phase upon contact with said reservoir oil at said reservoir temperature and said operating pressure, injecting said mixture into said reservoir through a rst input well spaced from said rst Well in a quantity sufficient to form a slug of said mixture within said reservoir about said first input Well, injecting at least a portion of the remainder of said produced reservoir oil into said reservoir through a second input well spaced remotely from said rst Well and said rst input Well, injecting such additional pressurizing uid into said reservoir during said rst stage as may be necessary to maintain said operating pressure, discontinuing the injection of said mixture of said hydrocarbons upon the formation of said slug, and thereafter in a second stage of said method recovering reservoir oil from said reservoir through an output Well spaced from said first input well, separating a gaseous fraction from the reservoir oil recovered during said second stage which is of a composition such that it will form a single fluid phase with said mixture of hydrocarbons upon contact with said mixture of hydrocarbons at said reservoir temperature and said operating pressure, injecting said gaseous fraction into said reservoir through said rst input well so as to drive said slug toward said output well, and injecting such additional pressurizing lluid as may be necessary into said reservoir during said second stage as may be necessary to maintain said operating pressure.
19. A method as defined in claim 18 in which said rst well is the same as said output well.
20. A method of recovering oil from an underground oil reservoir which comprises the steps of producing oil from the reservoir to the surface of the earth through an output well, separating'said produced oil into a light gaseous fraction, an intermediate gaseous fraction, and a residual oil fraction such that said intermediate gaseous fraction has a composition whereby it is completely miscible With said reservoir oil under the temperature and pressure conditions existing Within said reservoir, injecting said intermediate gaseous fraction into said reservoir through an input well spaced from said output well in a quantity sufcient to establish a bank of said intermediate fraction Within said reservoir, injecting at least a portion of said residual oil fraction into said reservoir at a point remote from said output well and said input well, also injecting at least a portion of said light gaseous fraction into said reservoir at a point remote from said output well and said input well, discontinuing the injection of said intermediate gaseous fraction, said residual oil fraction, and said light gaseous fraction upon the formation of said bank, thereafter injecting at least a portion of said light gaseous fraction through said input well into said reservoir so as to Vcause said bank to displace oil from said reservoir, and injecting such pressurizing fluid as may be necessary into said reservoir during said rst and second stages to maintain the pressure within said reservoir such that said light gaseous fraction and said intermediate gaseous fraction will form a single fluid phase upon contact with one another at said reservoir temperature and said pressure.
References Cited by the Examiner UNITED STATES PATENTS 2,623,596 12/1952 Whorton et al. 166-7 2,724,438 ll/l955 Whorton et al. 166-9 X 2,880,801 4/1959 Crump 166-9 2,885,003 5/1959 Lindauer 166-9 2,994,372 8/1961 Stone 166-9 X 2,994,373 8/1961 Stone 166-9 3,035,637 5/1962 Allen 166-9 3,103,972 9/1963 Parker 166-9 OTHER REFERENCES Kehn, D. M.: A Review of the Enriched Gas Drive Process, Producers Monthly, February 1960, pages 2834.
CHARLES E. OCONNELL, Primary Examiner.
BENJAMIN HERSH, Examiner.
UNITED STATES PATENT OFFICE CERTIFICATE LOF CORRECTION Patent No 3 223,157 y December 14, 1965 James- W. Lacey et al It is hereby certified that error appears in the above numbered patent requiring correction and that the said Letters Patent should read as corrected below.
In the grant,- lines 3 and 4, for "assgnors by mesne. assignments, ,to Esso Products Research Company, a corporation of Delaware" read assgnors by mesne ass gnments, to Esso Production Research Company, of Houston, Texas, a corporation of Delaware line 13,- for "Esso Products Research Company, its successors" read Esso Production Research Company, its successorsin the heading to the printed specification, linesS and 6, for "Esso Products Research Company, a corporation of Delaware" read Esso Production Research Company, Houston, Tex. a corporation of Delaware Signed and sealed this `'7th day of March 1967.
(SEAL) Attest:
ERNEST W. SWIDER EDWARD J. BRENNER Attestng Officer Commissioner of Patents

Claims (1)

16. IN A METHOD OF PRODUCING OIL FROM AND UNDERGROUND RESERVOIR BY A GAS-PROPELLED, SLUG-TYPE MISCIBLE DISPLACEMENT PROCESS WHEREIN SAID SLUG COMPRISES HYDROCARBONS WHICH ARE NORMALLY GASEOUS BUT LIQUEFIABLE AT ATMOSPHERIC TEMPERATURE, THE IMPROVEMENT WHICH COMPRISES STARTING SAID PROCESS BY PRODUCING OIL FROM SAID RESERVOIR THROUGH AN OUTPUT WELL, SEPARATING A MIXTURE OF SAID HYDROCARBONS FROM SAID PRODUCED OIL SUCH THAT SAID MIXTURE WILL FORM A SINGLE FLUID PHASE WITH SAID RESERVOIR OIL AT THE TEMPERATURE AND PRESSURE OF SAID RESERVOIR, INJECTILNG SAID MIXTURE INTO SAID RESERVOIR THROUGH AN INPUT WELL SPACED FROM SAID OUTPUT WELL SO AS TO FORM A BANK OF SIA DMIXTURE IN SAID RESERVOIR IN THE VICINITY OF SAID INPUT WELL, INJECTING AT LEAST A PORTION OF THE REMAINDER OF SAID PRODUCED OIL INTO SAID RESERVOIR AND ALSO INJECTING SUCH ADDITIONAL PRESSURIZING FLUID INTO SAID RESERVOIR AS MAY BE NECESSARY DURING THE INJECTION OF SAID MIXTURE AND SAID PRODUCED OIL TO MAINTAIN SAID RESERVOIR PRESSURE.
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Cited By (14)

* Cited by examiner, † Cited by third party
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US3360945A (en) * 1965-02-25 1968-01-02 Lummus Co Repressurized natural gas addition to main gas stream to maintain well head pressure
DE1280176B (en) * 1966-04-07 1968-10-17 Shell Int Research Process for extracting liquid hydrocarbons from a permeable, underground storage facility
US3705625A (en) * 1971-10-22 1972-12-12 Shell Oil Co Steam drive oil recovery process
US3788398A (en) * 1971-12-01 1974-01-29 Mobil Oil Corp Oil recovery process
US3841403A (en) * 1972-06-23 1974-10-15 Texaco Inc Miscible flood process for oil recovery using a lean gas
US4086961A (en) * 1977-01-10 1978-05-02 Texaco Inc. Method of oil recovery employing enriched gas drive with control of evolved gas
US4372381A (en) * 1981-04-10 1983-02-08 Mobil Oil Corporation Method for recovery of oil from tilted reservoirs
FR2514071A1 (en) * 1981-10-06 1983-04-08 Chaudot Gerard PROCESS FOR PRODUCING HYDROCARBON DEPOSITS WITH INJECTION OF EFFLUENTS INTO THE DEPOSIT OR IN THE WELL (S) AND INSTALLATION FOR CARRYING OUT SAID METHOD
US4467868A (en) * 1979-10-05 1984-08-28 Canterra Energy Ltd. Enhanced oil recovery by a miscibility enhancing process
US4548267A (en) * 1983-11-29 1985-10-22 Standard Oil Company Method of displacing fluids within a gas-condensate reservoir
US4635721A (en) * 1983-11-29 1987-01-13 Amoco Corporation Method of displacing fluids within a gas-condensate reservoir
US5019279A (en) * 1989-12-21 1991-05-28 Marathon Oil Company Process for enriching a gas
US5450901A (en) * 1993-12-17 1995-09-19 Marathon Oil Company Apparatus and process for producing and reinjecting gas
WO2017172321A1 (en) * 2016-03-30 2017-10-05 Exxonmobil Upstream Research Company Self-sourced reservoir fluid for enhanced oil recovery

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US2623596A (en) * 1950-05-16 1952-12-30 Atlantic Refining Co Method for producing oil by means of carbon dioxide
US2724438A (en) * 1954-03-01 1955-11-22 Atlantic Refining Co Method of recovering desirable petroleum hydrocarbon fractions from producing oil reservoirs
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Publication number Priority date Publication date Assignee Title
US2623596A (en) * 1950-05-16 1952-12-30 Atlantic Refining Co Method for producing oil by means of carbon dioxide
US2724438A (en) * 1954-03-01 1955-11-22 Atlantic Refining Co Method of recovering desirable petroleum hydrocarbon fractions from producing oil reservoirs
US2880801A (en) * 1956-10-03 1959-04-07 Jersey Prod Res Co Method of increasing recovery of oil
US2885003A (en) * 1957-07-19 1959-05-05 Jersey Prod Res Co Recovery of hydrocarbons from subterranean reservoirs
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Cited By (16)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3360945A (en) * 1965-02-25 1968-01-02 Lummus Co Repressurized natural gas addition to main gas stream to maintain well head pressure
DE1280176B (en) * 1966-04-07 1968-10-17 Shell Int Research Process for extracting liquid hydrocarbons from a permeable, underground storage facility
US3705625A (en) * 1971-10-22 1972-12-12 Shell Oil Co Steam drive oil recovery process
US3788398A (en) * 1971-12-01 1974-01-29 Mobil Oil Corp Oil recovery process
US3841403A (en) * 1972-06-23 1974-10-15 Texaco Inc Miscible flood process for oil recovery using a lean gas
US4086961A (en) * 1977-01-10 1978-05-02 Texaco Inc. Method of oil recovery employing enriched gas drive with control of evolved gas
US4467868A (en) * 1979-10-05 1984-08-28 Canterra Energy Ltd. Enhanced oil recovery by a miscibility enhancing process
US4372381A (en) * 1981-04-10 1983-02-08 Mobil Oil Corporation Method for recovery of oil from tilted reservoirs
WO1983001273A1 (en) * 1981-10-06 1983-04-14 Chaudot, Gérard Extraction from oil fields with reinjection of separated materials
FR2514071A1 (en) * 1981-10-06 1983-04-08 Chaudot Gerard PROCESS FOR PRODUCING HYDROCARBON DEPOSITS WITH INJECTION OF EFFLUENTS INTO THE DEPOSIT OR IN THE WELL (S) AND INSTALLATION FOR CARRYING OUT SAID METHOD
US4548267A (en) * 1983-11-29 1985-10-22 Standard Oil Company Method of displacing fluids within a gas-condensate reservoir
US4635721A (en) * 1983-11-29 1987-01-13 Amoco Corporation Method of displacing fluids within a gas-condensate reservoir
US5019279A (en) * 1989-12-21 1991-05-28 Marathon Oil Company Process for enriching a gas
US5450901A (en) * 1993-12-17 1995-09-19 Marathon Oil Company Apparatus and process for producing and reinjecting gas
WO2017172321A1 (en) * 2016-03-30 2017-10-05 Exxonmobil Upstream Research Company Self-sourced reservoir fluid for enhanced oil recovery
US10323495B2 (en) 2016-03-30 2019-06-18 Exxonmobil Upstream Research Company Self-sourced reservoir fluid for enhanced oil recovery

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