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US20110105370A1 - Breakers for gelled fracturing fluids - Google Patents

Breakers for gelled fracturing fluids Download PDF

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Publication number
US20110105370A1
US20110105370A1 US12/609,893 US60989309A US2011105370A1 US 20110105370 A1 US20110105370 A1 US 20110105370A1 US 60989309 A US60989309 A US 60989309A US 2011105370 A1 US2011105370 A1 US 2011105370A1
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fracturing fluid
water
breaker
fluid
hydrated
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US12/609,893
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Shaun T. Mesher
Gabrielle L.H. Robson
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Gasfrac Energy Services Inc
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Gasfrac Energy Services Inc
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Priority to US12/609,893 priority Critical patent/US20110105370A1/en
Assigned to MESHER, SHAUN T.E. reassignment MESHER, SHAUN T.E. ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: ROBSON, GABRIELLE H.
Assigned to GASFRAC ENERGY SERVICES INC. reassignment GASFRAC ENERGY SERVICES INC. ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: MESHER, SHAUN T.E.
Priority to PCT/CA2010/001701 priority patent/WO2011050465A1/en
Publication of US20110105370A1 publication Critical patent/US20110105370A1/en
Priority to US13/925,739 priority patent/US9096788B2/en
Abandoned legal-status Critical Current

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    • CCHEMISTRY; METALLURGY
    • C09DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
    • C09KMATERIALS FOR MISCELLANEOUS APPLICATIONS, NOT PROVIDED FOR ELSEWHERE
    • C09K8/00Compositions for drilling of boreholes or wells; Compositions for treating boreholes or wells, e.g. for completion or for remedial operations
    • C09K8/60Compositions for stimulating production by acting on the underground formation
    • C09K8/62Compositions for forming crevices or fractures
    • C09K8/66Compositions based on water or polar solvents
    • C09K8/665Compositions based on water or polar solvents containing inorganic compounds
    • CCHEMISTRY; METALLURGY
    • C09DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
    • C09KMATERIALS FOR MISCELLANEOUS APPLICATIONS, NOT PROVIDED FOR ELSEWHERE
    • C09K8/00Compositions for drilling of boreholes or wells; Compositions for treating boreholes or wells, e.g. for completion or for remedial operations
    • C09K8/60Compositions for stimulating production by acting on the underground formation
    • C09K8/62Compositions for forming crevices or fractures
    • C09K8/70Compositions for forming crevices or fractures characterised by their form or by the form of their components, e.g. foams
    • CCHEMISTRY; METALLURGY
    • C09DYES; PAINTS; POLISHES; NATURAL RESINS; ADHESIVES; COMPOSITIONS NOT OTHERWISE PROVIDED FOR; APPLICATIONS OF MATERIALS NOT OTHERWISE PROVIDED FOR
    • C09KMATERIALS FOR MISCELLANEOUS APPLICATIONS, NOT PROVIDED FOR ELSEWHERE
    • C09K2208/00Aspects relating to compositions of drilling or well treatment fluids
    • C09K2208/26Gel breakers other than bacteria or enzymes

Definitions

  • This document relates to breakers for gelled fracturing fluids.
  • fracturing fluid In the conventional fracturing of wells, producing formations, new wells or low producing wells that have been taken out of production, a formation can be fractured to attempt to achieve higher production rates. Proppant and fracturing fluid are mixed and then pumped into a well that penetrates an oil or gas bearing formation. High pressure is applied to the well, the formation fractures and proppant carried by the fracturing fluid flows into the fractures. The proppant in the fractures holds the fractures open after pressure is relaxed and production is resumed.
  • fracturing fluid including various mixtures of hydrocarbons, nitrogen and carbon dioxide.
  • Gelling agents are commonly used in hydraulic fracturing treatments in order to allow a fracturing fluid to carry sufficient amounts of proppant downhole.
  • U.S. Pat. Nos. 3,775,069 and 3,846,310 disclose gelling agents that form water-sensitive gels for hydrocarbon fracturing fluids.
  • Various chemicals known as breakers may be added to these gelled fracturing fluids in order to reduce the viscosity of the gel and return the fluid to a pre-gel consistency. Breakers may also be timed to delay the breaking of the gel until a desire amount of time has elapsed, usually long enough to allow a fracturing fluid to deliver sufficient proppant into the created fractures. By breaking the gel after successful delivery of proppant, the reduced viscosity fracturing fluid may then be recovered leaving the delivered proppant behind in the formation to prop open the created fractures.
  • a fracturing fluid for a downhole environment comprising a water-sensitive gel; and a hydrated breaker.
  • a fracturing fluid for a downhole environment comprising a water-sensitive carrier and a breaker, the breaker comprising one or more hydrates, and wherein water of the one or more hydrates is releasable so as to act with the water-sensitive carrier to reduce the viscosity of the fluid.
  • a fracturing fluid for a downhole environment comprising: a water-sensitive gel; and a hydrated breaker having a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid.
  • a fracturing fluid comprising: liquefied petroleum gas; a water-sensitive gel; and a hydrated breaker having a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid.
  • a method of treating a downhole environment with a fracturing fluid comprising: providing to the downhole environment a fluid comprising a water-sensitive carrier and a breaker, the breaker comprising one or more hydrates; and allowing water from the one or more hydrates to release so as to act with the carrier to reduce the viscosity of the fluid.
  • a method of treating a downhole environment comprising: adding a gelling agent and a hydrated breaker to a fracturing fluid to produce a water-sensitive gel, the hydrated breaker having a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid; and treating an underground formation with the water-sensitive gel.
  • the water-sensitive carrier may be a water-sensitive gel.
  • the hydrate may be a hydrated breaker having a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid.
  • the water may be bound within the crystalline framework by forces that are sufficient to bind the water under a first set of conditions and insufficient to bind the water under a second set of conditions.
  • the first set of conditions may comprise ambient surface temperature.
  • the second set of conditions may correspond to the conditions of a selected downhole environment.
  • the hydrated breaker may be selected to release water bound within the crystalline framework at a delayed rate under a set of conditions.
  • the set of conditions may comprise temperatures at or above 40° Celsius.
  • the set of conditions may comprise temperatures at or above 60° Celsius.
  • the set of conditions may comprise temperatures at or above 100° Celsius.
  • the crystalline framework may be saturated with water bound within the crystalline framework.
  • the water bound within the crystalline framework may be present in an amount of 0.01-0.5% by volume of the fracturing fluid.
  • the hydrated breaker may comprise a hydrated ionic salt breaker.
  • the hydrated ionic salt breaker may comprises one or more of a sulfate and a chloride.
  • the hydrated ionic salt breaker may comprise one or more of magnesium chloride, sodium sulfate, calcium sulfate, barium chloride, calcium chloride, aluminum sulfate, aluminum potassium sulfate, magnesium sulphate, and zinc sulphate.
  • the hydrated ionic salt breaker may comprise aluminum potassium sulfate.
  • the hydrated ionic salt breaker may comprise AlK(SO 4 ) 2 (12H 2 O).
  • the hydrated ionic salt breaker may comprise one or more of magnesium chloride, barium chloride, calcium chloride, magnesium sulphate, zinc sulfate, calcium sulphate, and aluminum sulphate.
  • the hydrated ionic salt breaker may comprise one or more of MgCl 2 (6H 2 O), BaCl 2 (2H 2 O), CaCl 2 (6H 2 O, MgSO 4 (7H 2 O), ZnSO 4 (7H 2 O), CaSO 4 (2H 2 O), Al 2 (SO 4 ) 3 (16H 2 O).
  • the fracturing fluid may comprise hydrocarbon fluid.
  • the hydrocarbon fluid may comprise liquefied petroleum gas.
  • the water-sensitive gel may be made from a gelling agent that comprises a combination of an alkoxide of a group IIIA element and an alkoxide of an alkali metal.
  • the group IIIA element may comprise one or more of boron and aluminum.
  • the organic group of one or more of R 1 , R 2 , and R 3 may each comprise 2-10 carbon atoms.
  • the organic group of one or more of R 1 , R 2 , and R 3 may each comprise an alkyl group.
  • M 1 may be boron, and R 1 , R 2 , and R 3 may comprise 2-10 carbon atoms.
  • the alkali metal may comprise one or more of lithium, sodium, and potassium.
  • the organic group of R 4 may comprise 2-24 carbon atoms.
  • the organic group of R 4 may comprise 12 carbon atoms.
  • M 2 may be lithium and the organic group of R 4 may comprise 2-24 carbon atoms.
  • the water may be bound within the crystalline framework by forces that are variable with temperature and range from forces that, when the hydrated breaker is added to the fracturing fluid at surface the water is not released into the fracturing fluid, and when the fracturing fluid is within the downhole environment to be fractured, the water undergoes a controlled release into the fracturing fluid at a rate that is dependent on the temperature of the fracturing fluid within the downhole environment.
  • the one or more hydrates may be configured to release water over one or both of: a particular period of time; and a particular range of temperature.
  • the water-sensitive carrier may be formed from a fluid and one or more gelling agent.
  • the fracturing fluid may be used to treat the downhole environment.
  • Water from the one or more hydrates may be allowed to release so as to act with the carrier to reduce the viscosity of the fluid.
  • the fluid of reduced viscosity may be removed from the formation.
  • the fluid of reduced viscosity may be processed after removal from the formation.
  • the fluid of reduced viscosity may be re-used after removal.
  • a fluid that comprises flowback from a well, the flowback comprising reduced viscosity fluids previously injected into the well as the fracturing fluids disclosed herein.
  • FIGS. 1-10H are graphs illustrating the results of viscosity testing of gelled pentane with various breakers. Table 1 summarizes the various testing characteristics for each graph. The percentage H 2 O values are the theoretical concentrations of the water molecules in the introduced breaker by volume of the gelled hydrocarbon fracturing fluid. Viscosity testing was carried out a Brookfield viscometer at 110 psi.
  • FIG. 11 is a flow diagram for a method of treating a downhole environment.
  • FIG. 12 is a flow diagram for a method of treating a downhole environment with a fracturing fluid.
  • Hydrates contain water, which may be tied up within a crystalline framework of the hydrate.
  • the water may be tied up as a water of crystallization that occurs in salt crystals but that is not covalently bonded to a host molecule or ion.
  • many compounds Upon crystallization from water or moist solvents, many compounds incorporate water molecules into their crystalline frameworks, forming hydrates.
  • a salt of interest cannot be crystallized in the absence of water, even though no strong bonds to the guestwater molecules may be apparent.
  • Many hydrated ionic salts have multiple stable hydrates with different ratios of water molecules to parent salt. The structure of hydrates can be quite elaborate, because of the existence of hydrogen bonds that define these polymeric structures.
  • hydrated compounds give off various amounts of water molecules under ambient or specific temperatures and conditions.
  • heat can be used to drive off the water molecules.
  • fracturing fluids for a downhole environment comprising a water-sensitive carrier such as a water sensitive-gel, and a breaker.
  • the breaker may comprise one or more hydrates, wherein water of the one or more hydrates is releasable so as to act with the water-sensitive carrier to reduce the viscosity of the fluid.
  • the hydrate for example a hydrated ionic salt breaker, may have a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid.
  • the fracturing fluid may also comprise a hydrocarbon fluid, for example C3-C20 fluids such as liquefied petroleum gas.
  • a fracturing fluid is disclosed having a water-sensitive gel and a hydrated breaker.
  • the hydrate may have the formula of Y.x(H 2 O), in which Y is the formula of the anhydrous form of the breaker, and x is the number of molecules of water bound within the crystalline framework, x being equal to more than zero.
  • the water may be bound within the crystalline framework by forces that are sufficient to bind the water under a first set of conditions, for example ambient surface conditions, and insufficient to bind the water under a second set of conditions, for example the conditions of a selected downhole environment.
  • Ambient surface conditions such as ambient surface temperature
  • ambient surface conditions include atmospheric pressure, although the fracturing fluid may be produced under higher pressures such as pumping pressures, particularly if the fracturing fluid is produced right before being pumped into a formation.
  • the first set of conditions which may include temperatures cooler than surface temperatures if the fracturing fluid is kept in a refrigerated state, allow the fracturing fluid to be stored for a desired length of time in a useful state prior to being used.
  • the second set of conditions may refer to the conditions that the fracturing fluid will experience while being used to treat the particular underground formation that the fracturing fluid is targeted for.
  • the second set of conditions such as the temperature of a particular downhole environment, may be determined from measurements or estimated. Estimations may be made from knowledge of the depth and character of the downhole environment. On-shore wells typically increase in temperature by 3° C. per 100 m of depth. In some embodiments, only a portion of the bound water is releasable in the selected downhole environment.
  • the water is bound within the crystalline framework by forces that are variable with temperature and range from forces that, when the hydrated breaker is added to the fracturing fluid at surface the water is not released into the fracturing fluid, and when the fracturing fluid is within the downhole environment to be fractured, the water undergoes a controlled release into the fracturing fluid at a rate that is dependent on the temperature of the fracturing fluid within the downhole environment.
  • the breaker may be selected to release water bound within the crystalline framework at a delayed rate under a set of conditions, for example the second set of conditions discussed above. As water is released in a controlled fashion, the water may act to degrade the gel and reduce the viscosity of the fracturing fluid down to normal.
  • the breaker such as an ionic metal salt breaker, may be substantially insoluble in the fracturing fluid, and thus during blending the breaker will disperse evenly throughout the fluid and thus be able to act to degrade the entire gel in a uniform fashion. In some embodiments the breaker is substantially insoluble in water.
  • the set of conditions may be for example temperatures at or above 40° C., 60° C., 100° C., or higher temperatures.
  • the crystalline framework of the hydrated breaker may be saturated with water bound within the crystalline framework. This way, short of introducing water directly into the fracturing fluid, the hydrate will carry the maximum amount of water possible in its crystal structure for delivery to the fracturing fluid. In some embodiments the water bound within the crystalline framework is present in an amount of 0.01-0.5% by volume of the fracturing fluid.
  • the hydrated ionic salt breaker may comprise one or more of a sulfate and a chloride, for further example if the hydrated ionic salt breaker comprises one or more of magnesium chloride, sodium sulfate, calcium sulfate, barium chloride, calcium chloride, aluminum sulfate, aluminum potassium sulfate, magnesium sulphate, and zinc sulphate.
  • hydrated ionic salt breakers are expected to be suitable as they are substantially insoluble in, and thus generally inert with regards to, the fracturing fluid itself, and yet they able to release water in a predictable fashion into the fracturing fluid to break the gel. Because of the similar hydrophobic nature of hydrocarbon fluid and liquefied petroleum gas, hydrated ionic salt breakers are expected to function in a similar fashion in liquefied petroleum gas as in higher weight hydrocarbon fluids such as the pentane tested.
  • the ionic salt is the product of a strong acid and a strong base. The ionic salt may form a weak acid or base in water.
  • Examples of suitable delayed hydrated ionic salt breakers include magnesium chloride, barium chloride, calcium sulphate, and aluminum sulphate magnesium chloride. Results from testing illustrate that gel break delays may be achieved using aluminum sulphate (for example Al 2 (SO 4 ) 3 (16H 2 O), see FIGS. 2A-2D and 2 E), barium chloride (for example BaCl 2 (2H 2 O), see FIGS. 4A-I ), calcium chloride (for example CaCl 2 (6H 2 O), see FIGS. 5A-5C ), calcium sulphate (for example CaSO 4 (2H 2 O), see FIGS. 6A-B ), magnesium chloride (for example MgCl 2 (6H 2 O), see FIGS.
  • aluminum sulphate for example Al 2 (SO 4 ) 3 (16H 2 O), see FIGS. 2A-2D and 2 E
  • barium chloride for example BaCl 2 (2H 2 O), see FIGS. 4A-I
  • calcium chloride for example CaCl 2 (6H 2 O),
  • magnesium sulphate for example MgSO 4 (7H 2 O), see FIGS. 8A-I
  • zinc sulfate for example ZnSO 4 (7H 2 O), see FIGS. 9A-H
  • aluminum potassium sulfate for example AlK(SO 4 )— 2 (12H 2 O) is another example of a delayed breaker.
  • the particle size of the breaker may be selected to modify the delay times of the breaker. For example, referring to FIGS. 4C and 4D , a larger particle size such as 60 mesh ( FIG. 4C ) has a more delayed effect than the same breaker at 100 mesh ( FIG. 4D ).
  • breaker was passed through a mesh size coarser than the desired mesh size, and the breaker left on top of the mesh was then used.
  • the breaker was passed through a 40 mesh sieve, and the breaker left on top of the 40 mesh sieve was then used as 60 mesh breaker.
  • Breakers used herein may comprise breakers that are ground or unground.
  • Breakers may also be passed through a certain mesh size, such as passed through a 40-250 mesh screen for example. Breakers may also be 40-250 mesh as an example. Breakers may be added directly as a solid or dispersed in a separate fluid.
  • Sodium sulphate, used as a hydrated ionic salt breaker, is illustrated in FIGS. 10A-K (for example Na 2 SO 4 (10H 2 O).
  • Exemplary gelling agents that may be used are disclosed by Whitney in U.S. Pat. Nos. 3,775,069 and 3,846,310, the specifications of which are incorporated by reference.
  • An example of a suitable gelling agent used to make the water-sensitive gel comprises a combination of an alkoxide of a group IIIA element and an alkoxide of an alkali metal. When combined, the alkoxide of the group IIIA element and the alkoxide of the alkali metal react to form a polymer gel.
  • the group IIIA element may comprise one or more of boron and aluminum for example.
  • M 1 the group IIIA element
  • R 1 , R 2 , and R 3 are organic groups.
  • Each of the organic groups of R 1 , R 2 , and R 3 may have 2-10 carbon atoms, and may comprise an alkyl group.
  • M 1 boron
  • R 1 , R 2 , and R 3 comprise 2-10 carbon atoms.
  • the alkali metal may comprise one or more of lithium, sodium, and potassium for example.
  • the organic group of R 4 may comprise 2-24 carbon atoms, for further example 12 carbon atoms, and may comprise an alkyl group.
  • M 2 lithium and the organic group of R 4 comprises 2-24 carbon atoms.
  • R 4 may further comprise: (AQ) n (R 5 ) x (R 6 ) y .
  • A is an organic group, Q is O or N, n is 1-10, R 5 and R 6 are organic groups, x is either 1 or 2 depending on the valence of Q, and y is 0 or 1 depending on the valence of Q.
  • the alkoxide of an alkali metal formed would have the formula: M 2 O(AQ) n (R 5 ) x (R 6 ) y .
  • A may have 2-4 carbon atoms.
  • Organic groups as disclosed herein may refer to groups with at least one carbon atom, as long the resulting gelling agent is suitable for its purpose.
  • examples of organic groups include phenyl, aryl, alkenyl, alkynyl, cyclo, and ether groups.
  • a suitable amount of gelling agent may be used, for example 0.25-5% by weight of the fracturing fluid.
  • the a suitable ration of the alkoxide of a group IIIA element and the alkoxide of an alkali metal may be used, for example 3:1 to 1:3, with 1:1 being a preferable ratio.
  • Breaker introduced Amount (g) % of H 2 O Al 2 (SO 4 ) 3 (16H 2 O) 1.33 0.15 Al 2 (SO 4 ) 3 (16H 2 O) 0.90 0.10 Al 2 (SO 4 ) 3 (16H 2 O) 0.44 0.05 AlK(SO 4 ) 2 (12H 2 O) 1.34 0.15 AlK(SO 4 ) 2 (12H 2 O) 0.90 0.10 AlK(SO 4 ) 2 (12H 2 O) 0.44 0.05 BaCl 2 (2H 2 O) 4.41 0.15 BaCl 2 (2H 2 O) 2.78 0.10 BaCl 2 (2H 2 O) 1.36 0.05 CaCl 2 (6H 2 O) 1.24 0.15 CaCl 2 (6H 2 O) 0.83 0.10 CaCl 2 (6H 2 O) 0.41 0.05 CaSO 4 (2H 2 O) 2.91 0.15 CaSO 4 (2H 2 O) 1.96 0.10 CaSO 4 (2H 2 O) 0.96 0.05 MgCl 2 (6H 2 O)
  • the following exemplary procedure was used to form the gelled hydrocarbon fracturing fluid as a control without a breaker chemical.
  • Butyl lithium (1.76 mL of a 1.7 M solution in pentane, 3 mmol) was added dropwise to a stifling solution of alcohol (C4, C5, C6, C8, C10, C12, C14, C16, and C18 primary alcohols were tested successfully, but only the test results using dodecanol (C12) are displayed here, 3 mmol) in pentane (1 ⁇ 2 pre-weighed mass for 1% by weight).
  • This mixture was then stirred for a further 1 h at room temperature. The remaining pentane was then added and stirring continued for 10 min.
  • the C12 lithium alkoxide was chosen as the best candidate to perform the testing reported here with the tributyl borate to form the charged borate gelling chemical.
  • a method of treating a downhole environment is illustrated.
  • a gelling agent and a hydrated breaker such as the gelling agents and hydrated breakers discussed above, are added to a fracturing fluid to produce a water-sensitive gel.
  • a fracturing fluid may be pressurized in the formation, for example in order to fracture the formation. Fracturing procedures are well known and need not be elaborated upon herein.
  • the hydrated breaker may be selected to release water at a delayed rate while treating the underground formation.
  • fluid in the formation may have a temperature of 80° C.
  • a hydrated ionic salt breaker may be selected to release water at a desired rate at that temperature.
  • the desired rate may be selected based on the desired break time, for example 4 hours.
  • the hydrate may act as a hydrating agent for degrading or destroying the gel.
  • a method of treating a downhole environment with a fracturing fluid is disclosed.
  • the downhole environment has provided to it a fluid comprising a water-sensitive carrier, such as a hydrophobic medium, and a breaker, the breaker comprising one or more hydrates.
  • the one or more hydrates may be configured to release water over one or both of a particular period of time and a particular range of temperature.
  • the water-sensitive carrier may be formed from a fluid and one or more gelling agent.
  • water from the one or more hydrates is allowed to release so as to act with the carrier to reduce the viscosity of the fluid.
  • the fluid of reduced viscosity is removed from the downhole environment. The fluid may then undergo processing, recycling, disposal, burn-off, or re-use.
  • the hydrate is added to the fracturing fluid while the fracturing fluid is downhole.
  • the hydrate used may be a mixture of one or more hydrates.
  • fracturing fluid with a sufficient viscosity to carry proppant into the fractures, minimize formation damage and be safe to use.
  • a fracturing fluid that remains in the formation after fracturing may not be desirable since it may block pores and reduce well production. Liquefied petroleum gas makes an excellent fracturing fluid that achieves all of the above-indicated desired functions.
  • LPG gelled liquefied petroleum gas
  • propane and butane have also been successfully tested.
  • LPG may include a variety of petroleum and natural gases existing in a liquid state at ambient temperatures and moderate pressures. In some cases, LPG refers to a mixture of such fluids. These mixes are generally more affordable and easier to obtain than any one individual LPG, since they are hard to separate and purify individually.
  • common LPGs are tightly fractionated products resulting in a high degree of purity and very predictable performance.
  • Exemplary LPGs used in this document include, propane, butane, and various mixes thereof.
  • LPGs used herein may include amounts of pentane, hexane, i-pentane, n-pentane, and other higher weight hydrocarbons.
  • the LPG mixture may be controlled to gain the desired hydraulic fracturing and clean-up performance.
  • LPGs tend to produce excellent fracturing fluids.
  • LPG is readily available, cost effective and is easily and safely handled on surface as a liquid under moderate pressure.
  • LPG is completely compatible with formations and formation fluids, is highly soluble in formation hydrocarbons and eliminates phase trapping—resulting in increased well production.
  • LPG may be readily and predictably viscosified to generate a fluid capable of efficient fracture creation and excellent proppant transport. After fracturing, LPG may be recovered very rapidly, allowing savings on clean up costs.
  • LPG may be predominantly propane, butane, or a mixture of propane and butane. Predominantly may mean for example over 80%, for example over 90 or 95%.

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Abstract

A fracturing fluid for a downhole environment is disclosed, comprising a water-sensitive gel; and a hydrated breaker. A fracturing fluid for a downhole environment is also disclosed, the fracturing fluid comprising a water-sensitive carrier and a breaker, the breaker comprising one or more hydrates, and wherein water of the one or more hydrates is releasable so as to act with the water-sensitive carrier to reduce the viscosity of the fluid. A method of treating a downhole environment with a fracturing fluid is also disclosed, the method comprising: providing to the downhole environment a fluid comprising a water-sensitive carrier and a breaker, the breaker comprising one or more hydrates; and allowing water from the one or more hydrates to release so as to act with the carrier to reduce the viscosity of the fluid.

Description

    TECHNICAL FIELD
  • This document relates to breakers for gelled fracturing fluids.
    • BACKGROUND
  • In the conventional fracturing of wells, producing formations, new wells or low producing wells that have been taken out of production, a formation can be fractured to attempt to achieve higher production rates. Proppant and fracturing fluid are mixed and then pumped into a well that penetrates an oil or gas bearing formation. High pressure is applied to the well, the formation fractures and proppant carried by the fracturing fluid flows into the fractures. The proppant in the fractures holds the fractures open after pressure is relaxed and production is resumed. Various fluids have been disclosed for use as the fracturing fluid, including various mixtures of hydrocarbons, nitrogen and carbon dioxide.
  • Gelling agents are commonly used in hydraulic fracturing treatments in order to allow a fracturing fluid to carry sufficient amounts of proppant downhole. U.S. Pat. Nos. 3,775,069 and 3,846,310 disclose gelling agents that form water-sensitive gels for hydrocarbon fracturing fluids. Various chemicals known as breakers may be added to these gelled fracturing fluids in order to reduce the viscosity of the gel and return the fluid to a pre-gel consistency. Breakers may also be timed to delay the breaking of the gel until a desire amount of time has elapsed, usually long enough to allow a fracturing fluid to deliver sufficient proppant into the created fractures. By breaking the gel after successful delivery of proppant, the reduced viscosity fracturing fluid may then be recovered leaving the delivered proppant behind in the formation to prop open the created fractures.
    • SUMMARY
  • A fracturing fluid for a downhole environment is disclosed, comprising a water-sensitive gel; and a hydrated breaker.
  • A fracturing fluid for a downhole environment is also disclosed, the fracturing fluid comprising a water-sensitive carrier and a breaker, the breaker comprising one or more hydrates, and wherein water of the one or more hydrates is releasable so as to act with the water-sensitive carrier to reduce the viscosity of the fluid.
  • A fracturing fluid for a downhole environment is also disclosed, the fracturing fluid comprising: a water-sensitive gel; and a hydrated breaker having a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid.
  • A fracturing fluid is also disclosed, comprising: liquefied petroleum gas; a water-sensitive gel; and a hydrated breaker having a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid.
  • A method of treating a downhole environment with a fracturing fluid is also disclosed, the method comprising: providing to the downhole environment a fluid comprising a water-sensitive carrier and a breaker, the breaker comprising one or more hydrates; and allowing water from the one or more hydrates to release so as to act with the carrier to reduce the viscosity of the fluid.
  • A method of treating a downhole environment is also disclosed, the method comprising: adding a gelling agent and a hydrated breaker to a fracturing fluid to produce a water-sensitive gel, the hydrated breaker having a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid; and treating an underground formation with the water-sensitive gel.
  • In various embodiments, there may be included any one or more of the following features: The water-sensitive carrier may be a water-sensitive gel. The hydrate may be a hydrated breaker having a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid. The water may be bound within the crystalline framework by forces that are sufficient to bind the water under a first set of conditions and insufficient to bind the water under a second set of conditions. The first set of conditions may comprise ambient surface temperature. The second set of conditions may correspond to the conditions of a selected downhole environment. The hydrated breaker may be selected to release water bound within the crystalline framework at a delayed rate under a set of conditions. The set of conditions may comprise temperatures at or above 40° Celsius. The set of conditions may comprise temperatures at or above 60° Celsius. The set of conditions may comprise temperatures at or above 100° Celsius. The crystalline framework may be saturated with water bound within the crystalline framework. The water bound within the crystalline framework may be present in an amount of 0.01-0.5% by volume of the fracturing fluid. The hydrated breaker may comprise a hydrated ionic salt breaker. The hydrated ionic salt breaker may comprises one or more of a sulfate and a chloride. The hydrated ionic salt breaker may comprise one or more of magnesium chloride, sodium sulfate, calcium sulfate, barium chloride, calcium chloride, aluminum sulfate, aluminum potassium sulfate, magnesium sulphate, and zinc sulphate. The hydrated ionic salt breaker may comprise aluminum potassium sulfate. The hydrated ionic salt breaker may comprise AlK(SO4)2(12H2O). The hydrated ionic salt breaker may comprise one or more of magnesium chloride, barium chloride, calcium chloride, magnesium sulphate, zinc sulfate, calcium sulphate, and aluminum sulphate. The hydrated ionic salt breaker may comprise one or more of MgCl2(6H2O), BaCl2(2H2O), CaCl2(6H2O, MgSO4(7H2O), ZnSO4(7H2O), CaSO4(2H2O), Al2(SO4)3(16H2O). The fracturing fluid may comprise hydrocarbon fluid. The hydrocarbon fluid may comprise liquefied petroleum gas. The water-sensitive gel may be made from a gelling agent that comprises a combination of an alkoxide of a group IIIA element and an alkoxide of an alkali metal. The group IIIA element may comprise one or more of boron and aluminum. The alkoxide of a group IIIA element may further comprise: M1(OR1)(OR2)(OR3), in which M1=the group IIIA element, and R1, R2, and R3 are organic groups. The organic group of one or more of R1, R2, and R3 may each comprise 2-10 carbon atoms. The organic group of one or more of R1, R2, and R3 may each comprise an alkyl group. M1 may be boron, and R1, R2, and R3 may comprise 2-10 carbon atoms. The alkali metal may comprise one or more of lithium, sodium, and potassium. The alkoxide of an alkali metal may further comprise: M2(OR4), in which M2=the alkali metal, and R4 comprises an organic group. The organic group of R4 may comprise 2-24 carbon atoms. The organic group of R4 may comprise 12 carbon atoms. M2 may be lithium and the organic group of R4 may comprise 2-24 carbon atoms. The water may be bound within the crystalline framework by forces that are variable with temperature and range from forces that, when the hydrated breaker is added to the fracturing fluid at surface the water is not released into the fracturing fluid, and when the fracturing fluid is within the downhole environment to be fractured, the water undergoes a controlled release into the fracturing fluid at a rate that is dependent on the temperature of the fracturing fluid within the downhole environment. The one or more hydrates may be configured to release water over one or both of: a particular period of time; and a particular range of temperature. The water-sensitive carrier may be formed from a fluid and one or more gelling agent. The fracturing fluid may be used to treat the downhole environment. Water from the one or more hydrates may be allowed to release so as to act with the carrier to reduce the viscosity of the fluid. The fluid of reduced viscosity may be removed from the formation. The fluid of reduced viscosity may be processed after removal from the formation. The fluid of reduced viscosity may be re-used after removal.
  • In some embodiments, a fluid is disclosed that comprises flowback from a well, the flowback comprising reduced viscosity fluids previously injected into the well as the fracturing fluids disclosed herein.
  • These and other aspects of the device and method are set out in the claims, which are incorporated here by reference.
    • BRIEF DESCRIPTION OF THE FIGURES
  • Embodiments will now be described with reference to the figures, in which like reference characters denote like elements, by way of example, and in which:
  • FIGS. 1-10H are graphs illustrating the results of viscosity testing of gelled pentane with various breakers. Table 1 summarizes the various testing characteristics for each graph. The percentage H2O values are the theoretical concentrations of the water molecules in the introduced breaker by volume of the gelled hydrocarbon fracturing fluid. Viscosity testing was carried out a Brookfield viscometer at 110 psi.
  • TABLE 1
    Characteristics of viscosity testing
    % of Temp
    FIG. Breaker Character of breaker H2O (° C.)
    1 None used N/A 0.00 23
    2A Al2(SO4)3(16H2O) 60 mesh 0.15 60
    2B Al2(SO4)3(16H2O) 100 mesh 0.15 60
    2C Al2(SO4)3(16H2O) 200 mesh 0.15 60
    2D Al2(SO4)3(16H2O) 200 mesh 0.10 60
    2E Al2(SO4)3(16H2O) 200 mesh 0.05 60
    2F Al2(SO4)3(16H2O) 100 mesh 0.10 60
    3A AlK(SO4)2(12H2O) 60 mesh 0.15 60
    3B AlK(SO4)2(12H2O) 100 mesh 0.15 60
    3C AlK(SO4)2(12H2O) 200 mesh 0.15 60
    3D AlK(SO4)2(12H2O) 60 mesh 0.10 60
    3E AlK(SO4)2(12H2O) 100 mesh 0.10 60
    3F AlK(SO4)2(12H2O) 200 mesh 0.10 60
    3G AlK(SO4)2(12H2O) 60 mesh 0.05 60
    3H AlK(SO4)2(12H2O) 100 mesh 0.05 60
    3I AlK(SO4)2(12H2O) 200 mesh 0.05 60
    4A BaCl2(2H2O) 60 mesh 0.15 60
    4B BaCl2(2H2O) 100 mesh 0.15 60
    4C BaCl2(2H2O) 60 mesh 0.10 60
    4D BaCl2(2H2O) 100 mesh 0.10 60
    4E BaCl2(2H2O) 200 mesh 0.10 60
    4F BaCl2(2H2O) 60 mesh 0.05 60
    4G BaCl2(2H2O) 100 mesh 0.05 60
    4H BaCl2(2H2O) 200 mesh 0.05 60
    4I BaCl2(2H2O) Ground and passed through 0.15 60
    a 100 mesh screen
    5A CaCl2(6H2O) 60 mesh 0.15 60
    5B CaCl2(6H2O) 200 mesh 0.10 60
    5C CaCl2(6H2O) 200 mesh 0.05 60
    6A CaSO4(2H2O) 60 mesh 0.15 60
    6B CaSO4(2H2O) 100 mesh 0.15 60
    7A MgCl2(6H2O) Ground and passed through 0.34 60
    a 100 mesh screen
    7B MgCl2(6H2O) Unground 0.32 23
    7C MgCl2(6H2O) Ground 0.32 60
    7D MgCl2(6H2O) Ground and passed through 0.32 60
    a 100 mesh screen
    7E MgCl2(6H2O) Ground and passed through 0.24 60
    a 100 mesh screen
    7F MgCl2(6H2O) Unground 0.16 60
    7G MgCl2(6H2O) 60 mesh 0.15 60
    7H MgCl2(6H2O) 100 mesh 0.15 60
    7I MgCl2(6H2O) Ground and passed through 0.14 60
    a 100 mesh screen
    8A MgSO4(7H2O) 60 mesh 0.15 60
    8B MgSO4(7H2O) 200 mesh 0.15 60
    8C MgSO4(7H2O) 100 mesh 0.15 60
    8D MgSO4(7H2O) 60 mesh 0.10 60
    8E MgSO4(7H2O) 100 mesh 0.10 60
    8F MgSO4(7H2O) 200 mesh 0.10 60
    8G MgSO4(7H2O) 60 mesh 0.05 60
    8H MgSO4(7H2O) 100 mesh 0.05 60
    8I MgSO4(7H2O) 200 mesh 0.05 60
    9A ZnSO4(7H2O) 60 mesh 0.15 60
    9B ZnSO4(7H2O) 100 mesh 0.15 60
    9C ZnSO4(7H2O) 200 mesh 0.15 60
    9D ZnSO4(7H2O) 60 mesh 0.10 60
    9E ZnSO4(7H2O) 100 mesh 0.10 60
    9F ZnSO4(7H2O) 200 mesh 0.10 60
    9G ZnSO4(7H2O) 60 mesh 0.05 60
    9H ZnSO4(7H2O) 100 mesh 0.05 60
    9I ZnSO4(7H2O) 200 mesh 0.05 60
    10A Na2SO4(10H2O) 60 mesh 0.15 60
    10B Na2SO4(10H2O) 100 mesh 0.15 60
    10C Na2SO4(10H2O) 200 mesh 0.15 60
    10D Na2SO4(10H2O) Ground and passed through 0.13 60
    a 100 mesh screen
    10E Na2SO4(10H2O) 60 mesh 0.10 60
    10F Na2SO4(10H2O) 100 mesh 0.10 60
    10G Na2SO4(10H2O) 200 mesh 0.10 60
    10H Na2SO4(10H2O) 60 mesh 0.05 60
    10I Na2SO4(10H2O) Ground and pass through 0.10 60
    a 100 mesh screen
    10J Na2SO4(10H2O) 100 mesh 0.05 60
    10K Na2SO4(10H2O) 200 mesh 0.05 60
  • FIG. 11 is a flow diagram for a method of treating a downhole environment.
  • FIG. 12 is a flow diagram for a method of treating a downhole environment with a fracturing fluid.
    •  DETAILED DESCRIPTION
  • Immaterial modifications may be made to the embodiments described here without departing from what is covered by the claims.
  • Hydrates contain water, which may be tied up within a crystalline framework of the hydrate. The water may be tied up as a water of crystallization that occurs in salt crystals but that is not covalently bonded to a host molecule or ion. Upon crystallization from water or moist solvents, many compounds incorporate water molecules into their crystalline frameworks, forming hydrates. Often, a salt of interest cannot be crystallized in the absence of water, even though no strong bonds to the guestwater molecules may be apparent. Many hydrated ionic salts have multiple stable hydrates with different ratios of water molecules to parent salt. The structure of hydrates can be quite elaborate, because of the existence of hydrogen bonds that define these polymeric structures.
  • Many hydrated compounds give off various amounts of water molecules under ambient or specific temperatures and conditions. For all hydrated ionic salts, heat can be used to drive off the water molecules. For example, a variety of hydrates are known with the formula MgCl2(xH2O), and each is known to lose water with increasing temperature: x=12 (−16.4° C.), 8 (−3.4° C.), 6 (116.7° C.), 4 (181° C.), 2 (ca. 300° C.).
  • Disclosed herein are fracturing fluids for a downhole environment, the fluids comprising a water-sensitive carrier such as a water sensitive-gel, and a breaker. The breaker may comprise one or more hydrates, wherein water of the one or more hydrates is releasable so as to act with the water-sensitive carrier to reduce the viscosity of the fluid.
  • The hydrate, for example a hydrated ionic salt breaker, may have a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid. The fracturing fluid may also comprise a hydrocarbon fluid, for example C3-C20 fluids such as liquefied petroleum gas. In some embodiments, a fracturing fluid is disclosed having a water-sensitive gel and a hydrated breaker. The hydrate may have the formula of Y.x(H2O), in which Y is the formula of the anhydrous form of the breaker, and x is the number of molecules of water bound within the crystalline framework, x being equal to more than zero.
  • The water may be bound within the crystalline framework by forces that are sufficient to bind the water under a first set of conditions, for example ambient surface conditions, and insufficient to bind the water under a second set of conditions, for example the conditions of a selected downhole environment. Ambient surface conditions, such as ambient surface temperature, may refer to the conditions that the fracturing fluid is stored or produced at above ground. In some cases, ambient surface conditions include atmospheric pressure, although the fracturing fluid may be produced under higher pressures such as pumping pressures, particularly if the fracturing fluid is produced right before being pumped into a formation. The first set of conditions, which may include temperatures cooler than surface temperatures if the fracturing fluid is kept in a refrigerated state, allow the fracturing fluid to be stored for a desired length of time in a useful state prior to being used. The second set of conditions may refer to the conditions that the fracturing fluid will experience while being used to treat the particular underground formation that the fracturing fluid is targeted for. The second set of conditions, such as the temperature of a particular downhole environment, may be determined from measurements or estimated. Estimations may be made from knowledge of the depth and character of the downhole environment. On-shore wells typically increase in temperature by 3° C. per 100 m of depth. In some embodiments, only a portion of the bound water is releasable in the selected downhole environment.
  • In some embodiments, the water is bound within the crystalline framework by forces that are variable with temperature and range from forces that, when the hydrated breaker is added to the fracturing fluid at surface the water is not released into the fracturing fluid, and when the fracturing fluid is within the downhole environment to be fractured, the water undergoes a controlled release into the fracturing fluid at a rate that is dependent on the temperature of the fracturing fluid within the downhole environment.
  • The breaker may be selected to release water bound within the crystalline framework at a delayed rate under a set of conditions, for example the second set of conditions discussed above. As water is released in a controlled fashion, the water may act to degrade the gel and reduce the viscosity of the fracturing fluid down to normal. The breaker, such as an ionic metal salt breaker, may be substantially insoluble in the fracturing fluid, and thus during blending the breaker will disperse evenly throughout the fluid and thus be able to act to degrade the entire gel in a uniform fashion. In some embodiments the breaker is substantially insoluble in water. The set of conditions may be for example temperatures at or above 40° C., 60° C., 100° C., or higher temperatures.
  • The crystalline framework of the hydrated breaker may be saturated with water bound within the crystalline framework. This way, short of introducing water directly into the fracturing fluid, the hydrate will carry the maximum amount of water possible in its crystal structure for delivery to the fracturing fluid. In some embodiments the water bound within the crystalline framework is present in an amount of 0.01-0.5% by volume of the fracturing fluid.
  • Various hydrated ionic salt breakers, such as ionic metal salts, may be used. For example, the hydrated ionic salt breaker may comprise one or more of a sulfate and a chloride, for further example if the hydrated ionic salt breaker comprises one or more of magnesium chloride, sodium sulfate, calcium sulfate, barium chloride, calcium chloride, aluminum sulfate, aluminum potassium sulfate, magnesium sulphate, and zinc sulphate. Various other hydrated ionic salt breakers are expected to be suitable as they are substantially insoluble in, and thus generally inert with regards to, the fracturing fluid itself, and yet they able to release water in a predictable fashion into the fracturing fluid to break the gel. Because of the similar hydrophobic nature of hydrocarbon fluid and liquefied petroleum gas, hydrated ionic salt breakers are expected to function in a similar fashion in liquefied petroleum gas as in higher weight hydrocarbon fluids such as the pentane tested. In some embodiments the ionic salt is the product of a strong acid and a strong base. The ionic salt may form a weak acid or base in water.
  • Examples of suitable delayed hydrated ionic salt breakers include magnesium chloride, barium chloride, calcium sulphate, and aluminum sulphate magnesium chloride. Results from testing illustrate that gel break delays may be achieved using aluminum sulphate (for example Al2(SO4)3(16H2O), see FIGS. 2A-2D and 2E), barium chloride (for example BaCl2(2H2O), see FIGS. 4A-I), calcium chloride (for example CaCl2(6H2O), see FIGS. 5A-5C), calcium sulphate (for example CaSO4(2H2O), see FIGS. 6A-B), magnesium chloride (for example MgCl2(6H2O), see FIGS. 7A-E and 7G-I), magnesium sulphate (for example MgSO4(7H2O), see FIGS. 8A-I), and zinc sulfate (for example ZnSO4(7H2O), see FIGS. 9A-H). Referring to FIGS. 3A-3I, aluminum potassium sulfate, for example AlK(SO4)—2(12H2O) is another example of a delayed breaker.
  • As illustrated in the exemplary data provided herein, the particle size of the breaker may be selected to modify the delay times of the breaker. For example, referring to FIGS. 4C and 4D, a larger particle size such as 60 mesh (FIG. 4C) has a more delayed effect than the same breaker at 100 mesh (FIG. 4D). To achieve the desired mesh size, breaker was passed through a mesh size coarser than the desired mesh size, and the breaker left on top of the mesh was then used. For example, to achieve the indicated mesh size of 60 mesh, the breaker was passed through a 40 mesh sieve, and the breaker left on top of the 40 mesh sieve was then used as 60 mesh breaker. Breakers used herein may comprise breakers that are ground or unground. Breakers may also be passed through a certain mesh size, such as passed through a 40-250 mesh screen for example. Breakers may also be 40-250 mesh as an example. Breakers may be added directly as a solid or dispersed in a separate fluid. Sodium sulphate, used as a hydrated ionic salt breaker, is illustrated in FIGS. 10A-K (for example Na2SO4(10H2O).
  • Exemplary gelling agents that may be used are disclosed by Whitney in U.S. Pat. Nos. 3,775,069 and 3,846,310, the specifications of which are incorporated by reference. An example of a suitable gelling agent used to make the water-sensitive gel comprises a combination of an alkoxide of a group IIIA element and an alkoxide of an alkali metal. When combined, the alkoxide of the group IIIA element and the alkoxide of the alkali metal react to form a polymer gel.
  • The group IIIA element may comprise one or more of boron and aluminum for example. In some embodiments, the alkoxide of a group IIIA element comprises M1(OR1)(OR2)(OR3), in which M1=the group IIIA element, and R1, R2, and R3 are organic groups. Each of the organic groups of R1, R2, and R3 may have 2-10 carbon atoms, and may comprise an alkyl group. In one embodiment, M1=boron, and R1, R2, and R3 comprise 2-10 carbon atoms.
  • The alkali metal may comprise one or more of lithium, sodium, and potassium for example. In some embodiments, the alkoxide of an alkali metal further comprises M2(OR4), in which M2=the alkali metal, and R4 comprises an organic group. The organic group of R4 may comprise 2-24 carbon atoms, for further example 12 carbon atoms, and may comprise an alkyl group. In one embodiment, M2=lithium and the organic group of R4 comprises 2-24 carbon atoms.
  • In some embodiments, R4 may further comprise: (AQ)n(R5)x(R6)y. in which A is an organic group, Q is O or N, n is 1-10, R5 and R6 are organic groups, x is either 1 or 2 depending on the valence of Q, and y is 0 or 1 depending on the valence of Q. Thus, the alkoxide of an alkali metal formed would have the formula: M2O(AQ)n(R5)x(R6)y. A may have 2-4 carbon atoms. The organic groups of R5 and R6 may each have 1-16 carbons. Where y=1, R6 is bonded to the Q atom. Organic groups as disclosed herein may refer to groups with at least one carbon atom, as long the resulting gelling agent is suitable for its purpose. Examples of organic groups include phenyl, aryl, alkenyl, alkynyl, cyclo, and ether groups. A suitable amount of gelling agent may be used, for example 0.25-5% by weight of the fracturing fluid. In addition, the a suitable ration of the alkoxide of a group IIIA element and the alkoxide of an alkali metal may be used, for example 3:1 to 1:3, with 1:1 being a preferable ratio.
  • Referring to FIGS. 6A-6B, the following exemplary procedure was used to form the fracturing fluids tested. Similar procedures were used to form the other fracturing fluids tested and reported here. Butyl lithium (3.53 mL of a 1.7 M solution in pentane, 6 mmol) was added dropwise to a stifling solution of dodecanol (1.12 g, 6 mmol) in pentane (125.00 g, 1% by wt gelling agents in pentane). This mixture was then stirred for a further 1 h at room temperature. A separate solution of tributyl borate (1.62 mL, 6 mmol) in pentane (125.00 g) was prepared in a blender at 17% variance with a rheostat for 5 min. To this solution was added the lithium alkoxide solution and a hydrated breaker (see Table 1 for the breakers tested). In this case, the hydrated breaker was CaSO4(2H2O) (2.91 g, 0.15% by vol. H2O, 60 mesh) Blending was continued for 1 min at 30% variance. Over this time cloudy white gels formed. These were tested on a Brookfield viscometer—60° C., 4 h, 110 psi. Table 2 below illustrates the various amounts of the different types of breakers tested.
  • TABLE 2
    Various amounts of breaker added to achieve desired concentrations
    Breaker introduced Amount (g) % of H2O
    Al2(SO4)3(16H2O) 1.33 0.15
    Al2(SO4)3(16H2O) 0.90 0.10
    Al2(SO4)3(16H2O) 0.44 0.05
    AlK(SO4)2(12H2O) 1.34 0.15
    AlK(SO4)2(12H2O) 0.90 0.10
    AlK(SO4)2(12H2O) 0.44 0.05
    BaCl2(2H2O) 4.41 0.15
    BaCl2(2H2O) 2.78 0.10
    BaCl2(2H2O) 1.36 0.05
    CaCl2(6H2O) 1.24 0.15
    CaCl2(6H2O) 0.83 0.10
    CaCl2(6H2O) 0.41 0.05
    CaSO4(2H2O) 2.91 0.15
    CaSO4(2H2O) 1.96 0.10
    CaSO4(2H2O) 0.96 0.05
    MgCl2(6H2O) 1.15 0.15
    MgSO4(7H2O) 1.19 0.15
    MgSO4(7H2O) 0.80 0.10
    MgSO4(7H2O) 0.39 0.05
    ZnSO4(7H2O) 1.39 0.15
    ZnSO4(7H2O) 0.93 0.10
    ZnSO4(7H2O) 0.46 0.05
    Na2SO4(10H2O) 1.09 0.15
    Na2SO4(10H2O) 0.73 0.10
    Na2SO4(10H2O) 0.36 0.05
  • Referring to FIG. 1, the following exemplary procedure was used to form the gelled hydrocarbon fracturing fluid as a control without a breaker chemical. Butyl lithium (1.76 mL of a 1.7 M solution in pentane, 3 mmol) was added dropwise to a stifling solution of alcohol (C4, C5, C6, C8, C10, C12, C14, C16, and C18 primary alcohols were tested successfully, but only the test results using dodecanol (C12) are displayed here, 3 mmol) in pentane (½ pre-weighed mass for 1% by weight). This mixture was then stirred for a further 1 h at room temperature. The remaining pentane was then added and stirring continued for 10 min. A solution of tributyl borate (0.69 g, 3 mmol) in pentane (1% by wt) was prepared as the trialkoxide with stifling for 10 min. The two solutions were then combined with stifling for 10 min over which time a colourless soft gel formed. This was then left to stand for 10 min before being tested on a Brookfield viscometer—23° C., 4 h, 110 psi. The tested gels were shear-thinning. Based on successful testing results with C4, C5, C6, C8, C10, C12, C14, C16, and C18 lithium alkoxides, the C12 lithium alkoxide was chosen as the best candidate to perform the testing reported here with the tributyl borate to form the charged borate gelling chemical.
  • Referring to FIG. 11, a method of treating a downhole environment is illustrated. In stage 10, a gelling agent and a hydrated breaker, such as the gelling agents and hydrated breakers discussed above, are added to a fracturing fluid to produce a water-sensitive gel. In stage 12, an underground formation is treated, for example fractured, with the water-sensitive gel. The fracturing fluid may be pressurized in the formation, for example in order to fracture the formation. Fracturing procedures are well known and need not be elaborated upon herein. The hydrated breaker may be selected to release water at a delayed rate while treating the underground formation. For example, fluid in the formation may have a temperature of 80° C., and a hydrated ionic salt breaker may be selected to release water at a desired rate at that temperature. The desired rate may be selected based on the desired break time, for example 4 hours. Thus, the hydrate may act as a hydrating agent for degrading or destroying the gel.
  • Referring to FIG. 12, a method of treating a downhole environment with a fracturing fluid is disclosed. In a stage 14, the downhole environment has provided to it a fluid comprising a water-sensitive carrier, such as a hydrophobic medium, and a breaker, the breaker comprising one or more hydrates. The one or more hydrates may be configured to release water over one or both of a particular period of time and a particular range of temperature. The water-sensitive carrier may be formed from a fluid and one or more gelling agent. In a stage 16, water from the one or more hydrates is allowed to release so as to act with the carrier to reduce the viscosity of the fluid. In a subsequent stage, the fluid of reduced viscosity is removed from the downhole environment. The fluid may then undergo processing, recycling, disposal, burn-off, or re-use.
  • It should be understood that various embodiments disclosed herein may be used in various other embodiments disclosed herein as desired. In some embodiments, the hydrate is added to the fracturing fluid while the fracturing fluid is downhole. The hydrate used may be a mixture of one or more hydrates.
  • In some embodiments, it may be desired to have a fracturing fluid with a sufficient viscosity to carry proppant into the fractures, minimize formation damage and be safe to use. A fracturing fluid that remains in the formation after fracturing may not be desirable since it may block pores and reduce well production. Liquefied petroleum gas makes an excellent fracturing fluid that achieves all of the above-indicated desired functions.
  • The breakers and gelling agents disclosed herein make suitable gelled liquefied petroleum gas (LPG) fracturing fluids. In addition to the pentane tests disclosed in the Figures, propane and butane have also been successfully tested. LPG may include a variety of petroleum and natural gases existing in a liquid state at ambient temperatures and moderate pressures. In some cases, LPG refers to a mixture of such fluids. These mixes are generally more affordable and easier to obtain than any one individual LPG, since they are hard to separate and purify individually. Unlike conventional hydrocarbon based fracturing fluids, common LPGs are tightly fractionated products resulting in a high degree of purity and very predictable performance. Exemplary LPGs used in this document include, propane, butane, and various mixes thereof. Further examples include HD-5 propane, commercial butane, i-butane, and n-butane. LPGs used herein may include amounts of pentane, hexane, i-pentane, n-pentane, and other higher weight hydrocarbons. The LPG mixture may be controlled to gain the desired hydraulic fracturing and clean-up performance.
  • LPGs tend to produce excellent fracturing fluids. LPG is readily available, cost effective and is easily and safely handled on surface as a liquid under moderate pressure. LPG is completely compatible with formations and formation fluids, is highly soluble in formation hydrocarbons and eliminates phase trapping—resulting in increased well production. LPG may be readily and predictably viscosified to generate a fluid capable of efficient fracture creation and excellent proppant transport. After fracturing, LPG may be recovered very rapidly, allowing savings on clean up costs. In some embodiments, LPG may be predominantly propane, butane, or a mixture of propane and butane. Predominantly may mean for example over 80%, for example over 90 or 95%.
  • In the claims, the word “comprising” is used in its inclusive sense and does not exclude other elements being present. The indefinite article “a” before a claim feature does not exclude more than one of the feature being present. Each one of the individual features described here may be used in one or more embodiments and is not, by virtue only of being described here, to be construed as essential to all embodiments as defined by the claims.

Claims (40)

1. A fracturing fluid for a downhole environment, the fracturing fluid comprising:
a water-sensitive gel; and
a hydrated breaker having a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid.
2. The fracturing fluid of claim 1 in which the water is bound within the crystalline framework by forces that are sufficient to bind the water under a first set of conditions and insufficient to bind the water under a second set of conditions.
3. The fracturing fluid of claim 2 in which the first set of conditions comprise ambient surface temperature.
4. The fracturing fluid of claim 2 in which the second set of conditions correspond to the conditions of a selected downhole environment.
5. The fracturing fluid of claim 1 in which the hydrated breaker is selected to release water bound within the crystalline framework at a delayed rate under a set of conditions.
6. The fracturing fluid of claim 5 in which the set of conditions comprise temperatures at or above 40° Celsius.
7. The fracturing fluid of claim 6 in which the set of conditions comprise temperatures at or above 60° Celsius.
8. The fracturing fluid of claim 7 in which the set of conditions comprise temperatures at or above 100° Celsius.
9. The fracturing fluid of claim 1 in which the crystalline framework is saturated with water bound within the crystalline framework.
10. The fracturing fluid of claim 1 in which the water bound within the crystalline framework is present in an amount of 0.01-0.5% by volume of the fracturing fluid.
11. The fracturing fluid of claim 1 in which the hydrated breaker comprises a hydrated ionic salt breaker.
12. The fracturing fluid of claim 11 in which the hydrated ionic salt breaker comprises one or more of a sulfate and a chloride.
13. The fracturing fluid of claim 12 in which the hydrated ionic salt breaker comprises one or more of magnesium chloride, sodium sulfate, calcium sulfate, barium chloride, calcium chloride, aluminum sulfate, aluminum potassium sulfate, magnesium sulphate, and zinc sulphate.
14. The fracturing fluid of claim 13 in which the hydrated ionic salt breaker comprises aluminum potassium sulfate.
15. The fracturing fluid of claim 14 in which the hydrated ionic salt breaker comprises AlK(SO4)2(12H2O).
16. The fracturing fluid of claim 13 in which the hydrated ionic salt breaker comprises one or more of magnesium chloride, sodium sulfate, barium chloride, calcium chloride, magnesium sulphate, zinc sulfate, calcium sulphate, and aluminum sulphate.
17. The fracturing fluid of claim 16 in which the hydrated ionic salt breaker comprises one or more of MgCl2(6H2O), Na2SO4(10H2O), BaCl2(2H2O), CaCl2(6H2O, MgSO4(7H2O), ZnSO4(7H2O), CaSO4(2H2O), Al2(SO4)3(16H2O).
18. The fracturing fluid of claim 1 further comprising hydrocarbon fluid.
19. The fracturing fluid of claim 18 in which the hydrocarbon fluid comprises liquefied petroleum gas.
20. The fracturing fluid of claim 1 in which the water-sensitive gel is made from a gelling agent that comprises a combination of an alkoxide of a group IIIA element and an alkoxide of an alkali metal.
21. The fracturing fluid of claim 20 in which the group IIIA element comprises one or more of boron and aluminum.
22. The fracturing fluid of claim 20 in which the alkoxide of a group IIIA element further comprises:

M1(OR1)(OR2)(OR3)
in which M1=the group IIIA element, and R1, R2, and R3 are organic groups.
23. The fracturing fluid of claim 22 in which the organic group of one or more of R1, R2, and R3 comprises 2-10 carbon atoms.
24. The fracturing fluid of claim 22 in which the organic group of one or more of R1, R2, and R3 comprises an alkyl group.
25. The fracturing fluid of claim 22 in which M1=boron, and R1, R2, and R3 comprise 2-10 carbon atoms.
26. The fracturing fluid of claim 20 in which the alkali metal comprises one or more of lithium, sodium, and potassium.
27. The fracturing fluid of claim 20 in which the alkoxide of an alkali metal further comprises:

M2(OR4)
in which M2=the alkali metal, and R4 comprises an organic group.
28. The fracturing fluid of claim 27 in which the organic group of R4 comprises 2-24 carbon atoms.
29. The fracturing fluid of claim 28 in which the organic group of R4 comprises 12 carbon atoms.
30. The fracturing fluid of claim 29 in which M2=lithium and the organic group of R4 comprises 2-24 carbon atoms.
31. The fracturing fluid of claim 1 in which the water is bound within the crystalline framework by forces that are variable with temperature and range from forces that, when the hydrated breaker is added to the fracturing fluid at surface the water is not released into the fracturing fluid, and when the fracturing fluid is within the downhole environment to be fractured, the water undergoes a controlled release into the fracturing fluid at a rate that is dependent on the temperature of the fracturing fluid within the downhole environment.
32. A fracturing fluid comprising:
liquefied petroleum gas;
a water-sensitive gel; and
a hydrated breaker having a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid.
33. A method of treating downhole environment, the method comprising:
adding a gelling agent and a hydrated breaker to a fracturing fluid to produce a water-sensitive gel, the hydrated breaker having a crystalline framework containing water that is bound within the crystalline framework and releasable into the fracturing fluid to act on the water-sensitive gel to reduce the viscosity of the fracturing fluid; and
treating a downhole environment with the water-sensitive gel.
34. The method of claim 33 in which the hydrated breaker is selected to release water bound within the crystalline framework at a delayed rate while treating the downhole environment.
35. A fracturing fluid for a downhole environment, the fluid comprising:
a water-sensitive gel; and
a hydrated breaker.
36. Fracturing fluid for a downhole environment, the fluid comprising:
a water-sensitive carrier and a breaker, the breaker comprising one or more hydrates, and wherein water of the one or more hydrates is releasable so as to act with the water-sensitive carrier to reduce the viscosity of the fluid.
37. Fluid according to claim 36 wherein the one or more hydrates are configured to release water over one or both of:
a particular period of time; and
a particular range of temperature.
38. Fluid according to claim 36 wherein the water-sensitive carrier is formed from a fluid and one or more gelling agent.
39. A method of treating a downhole environment with a fracturing fluid, the method comprising:
providing to the downhole environment a fluid comprising a water-sensitive carrier and a breaker, the breaker comprising one or more hydrates; and
allowing water from the one or more hydrates to release so as to act with the carrier to reduce the viscosity of the fluid.
40. The method according to claim 39, comprising removing from the downhole environment the fluid of reduced viscosity.
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Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20140284059A1 (en) * 2013-03-22 2014-09-25 Synoil Fluids Holdings Inc. Amide branched aromatic gelling agents
US9315720B2 (en) 2011-09-23 2016-04-19 Synoil Fluids Holdings Inc. Pyromellitamide gelling agents
US9719340B2 (en) 2013-08-30 2017-08-01 Praxair Technology, Inc. Method of controlling a proppant concentration in a fracturing fluid utilized in stimulation of an underground formation
US10259984B2 (en) 2011-09-23 2019-04-16 Synoil Fluids Holdings Inc. Pyromellitamide gelling agents
US10436001B2 (en) 2014-06-02 2019-10-08 Praxair Technology, Inc. Process for continuously supplying a fracturing fluid
CN113526730A (en) * 2021-07-26 2021-10-22 南京南环水务科技有限公司 Fracturing flow-back fluid treatment method and treatment device
US11898431B2 (en) 2020-09-29 2024-02-13 Universal Chemical Solutions, Inc. Methods and systems for treating hydraulically fractured formations
US12151644B2 (en) 2014-07-21 2024-11-26 State Farm Mutual Automobile Insurance Company Methods of facilitating emergency assistance

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US9194223B2 (en) * 2009-12-18 2015-11-24 Baker Hughes Incorporated Method of fracturing subterranean formations with crosslinked fluid

Citations (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3163219A (en) * 1961-06-22 1964-12-29 Atlantic Refining Co Borate-gum gel breakers
US3615285A (en) * 1970-01-30 1971-10-26 Exxon Research Engineering Co Hydrocarbons gelled with alkoxy compounds containing two different metals
US3749171A (en) * 1971-02-17 1973-07-31 Phillips Petroleum Co Decreasing the permeability of subterranean formations
US3775069A (en) * 1972-03-03 1973-11-27 Exxon Research Engineering Co Hydrocarbon gels containing metal alkoxy gellants and a dehydrating agent
US3846310A (en) * 1972-03-03 1974-11-05 Exxon Production Research Co Hydraulic fracturing method using gelled hydrocarbons
US4104173A (en) * 1971-12-17 1978-08-01 Borg-Warner Corporation Gelling agents for hydrocarbon compounds
US4407897A (en) * 1979-12-10 1983-10-04 American Can Company Drying agent in multi-layer polymeric structure
US4607696A (en) * 1985-08-30 1986-08-26 New Mexico Tech. Research Foundation Topical viscosity control for light hydrocarbon displacing fluids in petroleum recovery and in fracturing fluids for well stimulation
US5649596A (en) * 1996-02-27 1997-07-22 Nalco/Exxon Energy Chemicals, L.P. Use of breaker chemicals in gelled hydrocarbons
US5846915A (en) * 1995-10-26 1998-12-08 Clearwater, Inc. Delayed breaking of gelled hydrocarbon fracturing fluid
US5948735A (en) * 1997-04-14 1999-09-07 Nalco/Exxon Energy Chemicals, L.P. Use of breaker chemicals in gelled hydrocarbons
US5951970A (en) * 1996-06-19 1999-09-14 Haarmann & Reimer Gmbh Drying composition comprising an odoriferous substance
US6642185B2 (en) * 2000-10-16 2003-11-04 Baker Hughes Incorporated Borate crosslinked fracturing fluid viscosity reduction breaker mechanism and products
US6849581B1 (en) * 1999-03-30 2005-02-01 Bj Services Company Gelled hydrocarbon compositions and methods for use thereof
US7066262B2 (en) * 2004-08-18 2006-06-27 Halliburton Energy Services, Inc. Gelled liquid hydrocarbon treatment fluids having reduced phosphorus volatility and their associated methods of use and preparation

Patent Citations (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3163219A (en) * 1961-06-22 1964-12-29 Atlantic Refining Co Borate-gum gel breakers
US3615285A (en) * 1970-01-30 1971-10-26 Exxon Research Engineering Co Hydrocarbons gelled with alkoxy compounds containing two different metals
US3749171A (en) * 1971-02-17 1973-07-31 Phillips Petroleum Co Decreasing the permeability of subterranean formations
US4104173A (en) * 1971-12-17 1978-08-01 Borg-Warner Corporation Gelling agents for hydrocarbon compounds
US3775069A (en) * 1972-03-03 1973-11-27 Exxon Research Engineering Co Hydrocarbon gels containing metal alkoxy gellants and a dehydrating agent
US3846310A (en) * 1972-03-03 1974-11-05 Exxon Production Research Co Hydraulic fracturing method using gelled hydrocarbons
US4407897A (en) * 1979-12-10 1983-10-04 American Can Company Drying agent in multi-layer polymeric structure
US4607696A (en) * 1985-08-30 1986-08-26 New Mexico Tech. Research Foundation Topical viscosity control for light hydrocarbon displacing fluids in petroleum recovery and in fracturing fluids for well stimulation
US5846915A (en) * 1995-10-26 1998-12-08 Clearwater, Inc. Delayed breaking of gelled hydrocarbon fracturing fluid
US5649596A (en) * 1996-02-27 1997-07-22 Nalco/Exxon Energy Chemicals, L.P. Use of breaker chemicals in gelled hydrocarbons
US5951970A (en) * 1996-06-19 1999-09-14 Haarmann & Reimer Gmbh Drying composition comprising an odoriferous substance
US5948735A (en) * 1997-04-14 1999-09-07 Nalco/Exxon Energy Chemicals, L.P. Use of breaker chemicals in gelled hydrocarbons
US6849581B1 (en) * 1999-03-30 2005-02-01 Bj Services Company Gelled hydrocarbon compositions and methods for use thereof
US6642185B2 (en) * 2000-10-16 2003-11-04 Baker Hughes Incorporated Borate crosslinked fracturing fluid viscosity reduction breaker mechanism and products
US7066262B2 (en) * 2004-08-18 2006-06-27 Halliburton Energy Services, Inc. Gelled liquid hydrocarbon treatment fluids having reduced phosphorus volatility and their associated methods of use and preparation

Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US9315720B2 (en) 2011-09-23 2016-04-19 Synoil Fluids Holdings Inc. Pyromellitamide gelling agents
US9631136B2 (en) 2011-09-23 2017-04-25 Synoil Fluids Holding Inc. Amide branched aromatic gelling agent enhancers and breakers
US10259984B2 (en) 2011-09-23 2019-04-16 Synoil Fluids Holdings Inc. Pyromellitamide gelling agents
US20140284059A1 (en) * 2013-03-22 2014-09-25 Synoil Fluids Holdings Inc. Amide branched aromatic gelling agents
US9217102B2 (en) * 2013-03-22 2015-12-22 Synoil Fluids Holdings Inc. Amide branched aromatic gelling agents
US10138408B2 (en) 2013-03-22 2018-11-27 Synoil Fluids Holdings Inc. Amide branched aromatic celling agents
US9719340B2 (en) 2013-08-30 2017-08-01 Praxair Technology, Inc. Method of controlling a proppant concentration in a fracturing fluid utilized in stimulation of an underground formation
US10436001B2 (en) 2014-06-02 2019-10-08 Praxair Technology, Inc. Process for continuously supplying a fracturing fluid
US12151644B2 (en) 2014-07-21 2024-11-26 State Farm Mutual Automobile Insurance Company Methods of facilitating emergency assistance
US11898431B2 (en) 2020-09-29 2024-02-13 Universal Chemical Solutions, Inc. Methods and systems for treating hydraulically fractured formations
CN113526730A (en) * 2021-07-26 2021-10-22 南京南环水务科技有限公司 Fracturing flow-back fluid treatment method and treatment device

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