The present invention relates to spheroid magnetic polymers and more particularly relates to methods of coating a wall of a subterranean reservoir well-bore with a reversible pseudo-gel for improving hydrocarbon recovery and/or drilling performance upon subsequent application of a magnetic field or electric field to the spheroid magnetic polymers.
In the field of producing hydrocarbons, when improving hydrocarbon recovery or drilling performance, there are several aspects to consider, such as reducing the non-productive time, increasing the life of the well, preventing formation damage, etc. Reducing the non-productive time may be accomplished by, but not limited to, increasing the rate of penetration (ROP), reducing frictional pressure, and combinations thereof. Preventing or inhibiting corrosion of the well may reduce failure of downhole tools and/or extend the life of the well. Preventing or inhibiting lost circulation may prevent formation damage, as well as improve hydrocarbon recovery.
One of the primary concerns in upstream deepwater operations is the operational narrow window between pore pressure and fracture gradient that often results in major fluid losses during drilling, running, casing, and cementing processes. Thus, the lost circulation prevention and control are crucial to successful drilling and completion activities. Loss of circulation is one of the biggest contributors to drilling non-productive time, and is the most difficult segment of drilling in which to make economic decisions.
The loss of circulation is the phenomenon in which drilling fluid leaks away via fractures or openings in the wellbore and/or formation. This loss of fluid can be quantified according to its severity, including: seepage losses, partial losses, severe, and total or catastrophic losses. Each situation is specifically handled depending on the operational, personnel and economic risks involved, and the solutions applied. One of the main causes of loss of circulation includes exceeding the fracture gradient with excessive fluid weights or high surge pressures and equivalent circulating densities, which induces fractures in the formations and produces fluid losses while tripping pipe, breaking circulation, or raising fluid weights.
The ROP is the speed at which a drill bit breaks the rock/formation under it to deepen the borehole; increasing the ROP may reduce the non-productive time. Mechanical aspects of the drill bit may be altered to enhance the ROP, or chemicals may be added, e.g. to the drill bit, to alter the chemical composition of the formation. For example, ROP enhancers/enhancements may include, but are not necessarily limited to, surfactants and polymers, in a synthetic base oil carrier, such as a synthetic based olefin or ester.
Highly-permeable formations may include but are not limited to massive sands, pea gravel, shell beds, reef deposits, and combinations thereof, and may be indicated by continuous gradual seepage losses, and partial returns of downhole fluids. Highly-porous formations—sands, gravel beds, or reef deposits. This type of formation may be indicated by partial loss of return of a downhole fluid that may develop slowly and increase with penetration. Cavernous and vugular formations may include limestone, dolomite, chalk, and other formations with secondary porosity, which may be indicated by sudden and severe to complete loss of returns of downhole fluids that may be accompanied by sudden erratic rates of penetration.
The loss of circulation may vary from seepage (about 1 to about 10 bbl/h loss rate) to partial (about 10 to about 50 bbl/h loss rate) to severe (about 50 to about 100 bbl/h loss rate) to total losses (greater than about 500 bbl/h loss rate), and may culminate in extremely costly remedial treatments or catastrophic results. Depending on the severity of this process, the conventional lost circulation materials used to prevent lost circulation are not cost effective, primarily if the usage of huge volumes of them becomes necessary, and additionally if they don't guarantee the durable sealing of the lost zone.
Depending on the cause of loss of circulation, remedial procedures involve reducing the pressure exceeded by the circulating fluid, or filling the openings through which a downhole fluid is escaping. A slurry may be added that can become stiff on standing for filling the fractures or opening of the wellbore to prevent or inhibit lost circulation, or introducing a bridging or plugging solid so that normal filtration can occur.
The classification of the lost circulation materials may be, but is not limited to granular materials, flaky materials, fibrous materials, a slurry, and combinations thereof. The granular materials, may be ground nutshells, or vitrified, expanded shale particles, and the like. These materials have strength and rigidity and may seal by jamming these granular materials just inside the openings. The flaky materials may be, but are not limited to shredded cellophane, mica flakes, plastic laminates, wood chips, and the like. These materials are believed to lie flat across the face of the formation and thereby cover the openings. The fibrous materials may be, but are not limited to cotton fibers, bagasse, hog hair, shredded automobile tires, wood fibers, sawdust, paper pulp, and the like. These materials have relatively little rigidity, and tend to be forced into large openings. Slurries may be or include, but are not limited to hydraulic cement, diesel oil-bentonite-muds (DOB) mixes, high-filter-loss muds, and the like. The slurries tend to have a strength that increases over time after placement of the slurry.
A type of lost circulation material may include a polyacrylamide dispersion in water that is emulsified in paraffinic oil where bentonite is added into the external (oil) phase. Near the drill bit, where high shear rates are prevailing, the emulsion may be broken, and the bentonite is wetted by water and crosslinked with polyacrylamide, and resulting in a viscoelastic material in the formation. Cross-linked polymers have been used for severe lost circulation control, since they are not easily reversible.
A crosslinked polymer has a high apparent viscosity and strong cohesive force and may not be easily diluted by downhole fluids. The cross-linked polymer may be pumped normally, becoming viscoelastic in the “weak zone”. The cross-linked polymer has good chemical compatibility with various other components of lost circulation material. Inorganic bridge materials may be combined with cross-linked materials to enhance thermal stability and optimize particle size distribution. Free-chain movement may be prevented by cross-linking between chains of the polymer matrix. This, in turn, results in an increased strength, decreased flexibility, and increased brittleness of the polymer matrix. Physical crosslinking occurs when long chains entangle, effectively forming chemical “knots” between them. Cross-linking may be carried out by applying: heat, mechanical force, exposure to ionizing and nonionizing radiation (such as microwave), exposure to active chemical agents, or any combination of these. As the extent of crosslinking increases, there is a rapid increase in viscosity and the material becomes viscoelastic, at this point the system is “gelled”. Industrially important crosslinked polymers include: phenol and amino resins, alkyl resins, unsaturated polyesters, epoxy resins, concrete, silicon dioxide, carbon, siloxanes, isocyanates, acrylic copolymers, unsaturated and saturated hydrocarbons, halogen-containing hydrocarbons, ionomers, and combinations thereof.
Horizontal sections may be drilled with a drilling fluid containing a polymer, e.g. a viscosifier agent; sized calcium carbonate (CaCO3), such as but not limited to bridging agents, calcium chloride (CaCl2); or sodium chloride (NaCl); and additives (usually starch or another polymer) tailored to control loss of circulation. Field experience has demonstrated that mixtures, heterogeneous in shape, size, and strength, are usually more likely to form a seal than is a single material. The lost circulation material specifications frequently involve laboratory performance tests in addition to certain physical properties, such as screen size distribution and bulk density.
It would be desirable if methods were devised to improve hydrocarbon recovery and/or drilling performance by using materials that are easily synthesized to be readily available.
There is provided, in one form, a method for producing hydrocarbons including improving a property such as, but not limited to drilling performance, hydrocarbon recovery, and combinations thereof by applying a magnetic field or electric field to the wall of a subterranean reservoir wellbore where the wall has been at least partially coated with spheroid magnetic polymers. The magnetic field or electric field forms a reversible pseudo-gel comprising the spheroid magnetic polymers on the wall to improve the property by a process, such as but not limited to preventing or inhibiting lost circulation, improving or increasing the rate of penetration (ROP), reducing frictional pressure during wellbore construction, preventing or inhibiting corrosion, and combinations thereof.
There is further provided another non-limiting embodiment for producing hydrocarbons including preventing or inhibiting lost circulation of a downhole fluid. The downhole fluid may be circulated within a subterranean reservoir wellbore and at least partially coat the wall of the subterranean reservoir wellbore with the spheroid magnetic polymers. The downhole fluid includes spheroid magnetic polymers in an amount effective to prevent or inhibit lost circulation of the downhole fluid after a magnetic field or electric field has been applied to the spheroid magnetic polymers to form a reversible pseudo-gel once the downhole fluid is circulated within the subterranean reservoir wellbore. A magnetic field or electric field may be applied to the spheroid magnetic polymers along the coated wall of the subterranean reservoir wellbore to form the pseudo-gel so that the spheroid magnetic polymers to prevent or inhibit lost circulation of the downhole fluid.
There is provided, in another embodiment, a subterranean reservoir wellbore where the wellbore wall may have spheroid magnetic polymers disposed thereon. The spheroid magnetic polymers may include a magnetic particle, such as but not limited to iron, cobalt, nickel, magnesium, molybdenum, tantalum, alloys thereof, spinels thereof, oxides thereof, and combinations thereof. The magnetic polymers may have an average diameter ranging from about 20 nm to about 1000 nm.
The spheroid magnetic polymers appear to help improve hydrocarbon recovery and/or drilling performance once a magnetic field or electric field is applied to the wellbore by allowing the magnetic polymers to provide a multitude of functionalities within the wellbore.
It has been discovered that at least partially coating a wall of a wellbore with spheroid magnetic polymers may improve hydrocarbon recovery and/or drilling performance by a method, such as but not limited to preventing or inhibiting lost circulation, improving or increasing rate of penetration (ROP), reducing frictional pressure during wellbore construction, preventing or inhibiting corrosion, and combinations thereof.
Spheroid magnetic polymers may respond to externally applied stimuli, such as but not limited to electrical stimuli, stress/strain (including pressure) stimuli, magnetic stimuli, thermal stimuli, light, solvent composition, etc. Spheroid magnetic polymers may react to external stimuli to result in a defined engineering or scientific goal. Much of the strength of the magnetic polymer comes from the contact of the magnetic particle with the polymeric matrix. The polymeric matrix also allows the magnetic polymer to swell and gives the magnetic polymer elasticity.
The mechanism of action for the spheroid magnetic polymers involves the spheroid magnetic polymers responding to a permanent or single-orientation magnetic field or electric field to produce structures like gels, which strengthens the rock matrix to prevent wellbore instability by creating a barrier that prevents lost circulation. In one non-limiting embodiment these structures are called “pseudo-gels”. They are gel-like, but are not gels for instance in the sense of a cross-linked polymer. When the magnetic field or electric field is applied, magnetic molecules in the spheroid magnetic polymers orient according to the magnetic field or electric field lines to form a temporary pseudo-gel, and when the field is turned off or removed, the spheroid magnetic polymers tend to return to random orientation and the pseudo-gel is reversed. By the pseudo-gel being reversible is meant that the spheroid magnetic polymers only temporarily form the pseudo-gel. That is, the behavior of the spheroid magnetic polymers in the fluid is reversible. Stated another way, these structures are temporary or non-permanent. In one sense they are similar to liquid crystals. The pseudo-gels can temporarily be very high strength and impermeable.
The present spheroid magnetic polymers and methods of using them is contrasted with the structures and methods of US Patent Application Publication No. 2009/0314488 A1 to Droger which discloses that the polymeric coating formed by the fibres is not reversible. The fibres, which have a core formed from a material that is electrically and/or magnetically susceptible, are bonded by melting or setting, which is process is irreversible permanent. In Droger, the accumulated fibers are heated with a heating source by inductive or resistive means and then allowed to harden and/or set; that is the polymer melts and produces a closely-cross-linked network or mat. The mechanism of action disclosed by Droger necessarily involves the heating of the cores using heat generated via an electric or magnetic field resulting in the softening or melting of a thermoplastic or thermosetting polymer coating such that the polymer fibers bond to one another forming a permanent “melt” structure.
In contrast, the present method has an absence of forming a cross-linked network or mat. It is important that the pseudo-gel is reversible. Wellbore stability and minimum loss circulation is achieved when the magnetic field or electric field is applied to the fluid having the spheroid magnetic polymers; this is important from the point the view of drilling performance, in non-limiting instances to minimizing nonproductive time and get a wellbore in gauge. However, in order to improve the hydrocarbon recovery, the wellbore of the production section needs to be cleaned to avoid near wellbore damage. That means the gel structure formed by the spheroid magnetic polymer mixture needs to be removed to prevent formation damage. In the present method, this can be achieved by turning off the magnetic field or electric field that was applied to the spheroid magnetic polymers. After the drilling phase is completed, the magnetic field or electric field is removed to enable the magnetic molecules in the spheroid magnetic polymers to change from the magnetic field or electric field induced quasi-parallel orientation to a random orientation of magnetic molecules in the fluid, which results in a change of the fluid properties from gel-like or pseudo-gel structure to a very liquid-like fluid that can be readily displaced out of the hole.
Each spheroid magnetic polymer may have one or more magnetic particles comprising magnetic molecules embedded within a polymer matrix. The magnetic particles may be or include, but not limited to iron, cobalt, nickel, magnesium, molybdenum, tantalum, alloys thereof, spinels thereof, oxides thereof, and combinations thereof, as well as alloys and spinels. Among these magnetic particles, metal oxides may be more resistant to oxidation. The polymer matrix may be or include polystyrene (PS), polyacrylamide, dextran, poly(vinyl alcohol) (PVA), polymethylmethacrylate (PMMA); copolymers and/or triblock polymers, such as but not limited to polyisopropene-block-poly(2-cinnamoylethyl methacrylate)-block-poly-(tert-butyl acrylate), copolymers of acetoacetoxyethyl methacrylate and N-vinyl-caprolactam, copolymers of N-isopropyl acrylamide (NIPA) and glycidyl methacrylate.
Nanoparticles present single domain structures, which include groups of spins all pointing in the same direction and acting cooperatively. By contrast, microparticles exhibit multidomain structures consisting of many single domains, separated by walls that generate magnetic flux closures rendered to the material's non-magnetic behavior. Generally, nanoparticles are defined herein as having an average particle size of 999 nm or less where macroparticles are larger than 1 μm or larger.
The size of the magnetic particle distinguishes the spheroid magnetic polymers as one of two different types: superparamagnetics and ferromagnetics, and the dispersions formed from them are called ferrofluids (or magnetic fluids), and magnetorheologycal fluids, respectively. Ferrofluids (single domains) may be used to switch off the magnetic state after usage of the magnetic polymer, e.g. when it may be desirable for the magnetic particle to have a minimum disturbance on the process or when the surface-to-volume ratio needs to be large. On the other hand, magnetorheological fluids (multidomain structures) present applicability when yield stress has to be accurately controlled by changing the magnetization, or when it is desirable to have a strong response to the magnetization.
The size of the magnetic particle may determine the coercivity as well as remanence, or saturation remanent magnetization. Coercivity characterizes the reverse field strength needed to reduce the magnetization of a material to zero after achieving the saturation magnetization. Saturation remanent magnetization is the magnetization left behind from a permanent magnet after removing the magnetic stimulus. Thus, depending on the magnetic properties and the size of the magnetic particles, the applications of the magnetic particles embedded within the polymeric matrix may change.
Ferrofluids derived from iron oxides typically have magnetic nanoparticles within the size range from about 5 nm to about 15 nm with a large surface-to-volume ratio. The coercivity of the ferrofluids may be small, such as but not limited to a size near to zero, i.e. the fluid exhibits magnetic properties only in the presence of the magnetic field or electric field. Magnetorheological fluids though may have magnetic particles within a size range of about 20 nm to about 1000 nm with a small surface-to-volume ratio. The fluid may exhibit magnetic properties even in the absence of the magnetic field or electric field.
For purposes of improving hydrocarbon recovery or drilling performance, the magnetic polymers are spheroid, which is defined herein as being generally round and “ball-like” or “sphere-like” without necessarily being perfect spheres. The approximate diameters of the spheroid magnetic polymer may be from about 5 nm independently to about 1000 nm, or alternatively from about 40 nm independently to about 400 nm in another non-limiting embodiment. The magnetic particle within the spheroid magnetic polymer may range in size from about 5 nm independently to about 1000 nm, or from about 20 nm independently to about 300 nm in another non-limiting embodiment. The molecular weight (mw) of the magnetic polymer may range from about 10,000 g/mol independently to about 25,000 g/mol.
In the Droger US 2009/0314488 application, the polymers are described as fibres which are a different kind of shape than the spheroid magnetic polymers described herein. Fibers are slender, thread-like structures. Fiber shape and dimensions are important to the formation of a sufficiently strong cross-linked web, network or mat that Droger teaches. Fibers are understood as having a high aspect ratio or length to diameter (L/D) ratio. It is a generally accepted criteria that the L/D ratio is higher than 20.
The magnetic polymers may be: (i) polymer core-magnetic shell spheroids, (ii) magnetic core-polymer shell spheroids, (iii) magnetic polymer spheroids with homogeneously dispersed magnetic particles therein, and combinations thereof. The spheroid magnetic polymers are not themselves magnets, but have a component that is influenced by a magnetic field or electric field; in a non-limiting embodiment iron atoms in the form of ferrous or ferric groups. In one non-limiting instance, the spheroid magnetic polymers may be synthesized by in-situ formation of the magnetic particles into the polymer matrix, i.e. spheroid magnetic polymers may be prepared by co-precipitation of iron salts directly into a polymer matrix and subsequently controlling the nucleation and growth of the spheroid magnetic polymers. Examples of polymeric matrices that may be used to prepare spheroid magnetic polymers by this method include, but are not limited to: polystyrene (PS), poly(styrenesulfonate) (PSS), poly(maleic acid) (PMA), poly(acrylic acid) (PAA), polyacrylamide (PAM), triblock polymer polyisopropene-block-poly(2-cinnamoyl-ethyl methacrylate)-block-poly(tert-butyl acrylate), dextran, poly(vinyl alcohol) (PVA), copolymers of acetoacetoxyethyl methacrylate and N-vinylcaprolactam, copolymers of N-isopropyl acrylamide (NIPA), glycidyl methacrylate, polymethyl-methacrylate (PMMA), poly(2-acrylamido-2-methylpropanesulfonate) (PAMPS), and combinations thereof. In another non-limiting embodiment, the polymerization may occur in-situ in the presence of magnetic particles. This allows for the preparation of porous spheroid magnetic polymers, and a means for tailoring the chemical and interfacial properties of the spheroid magnetic polymers by incorporation of monomers with desired functional groups. Pickering emulsions, three-dimensional, and emulsion polymerization may be prepared this way.
Alternatively, a pre-formed polymer matrix may be mixed with magnetic particles. One example may include a polymer core-magnetic shell that may be prepared by disposing magnetic particles onto the surface of the spheroid magnetic polymers by adsorption or layer-by-layer (LBL) coating. Magnetic core-polymer shell spheroids may be prepared, in another example, by coating the magnetic particles with a polymer by adsorption or LBL technique. Magnetic particles may be homogenously dispersed in a polymer solution and emulsified as a disperse phase to obtain an emulsion. The spheroid magnetic polymers may also be prepared while under magnetization to obtain magnetic spheroids with tailor-made anisotropy. The spheroid magnetic polymers may also have chemicals encapsulated with the magnetic particles. The chemicals may be or include, but are not necessarily limited to, corrosion inhibitors, drag reducers, fluid loss agents, scale inhibitors, asphaltene inhibitors, paraffin dispersants, and combinations thereof.
In one non-limiting example, nanoparticles of Fe(O) may be dispersed into polymethyl methacrylate (PMMA) by emulsion polymerization techniques in a semicontinuous process to exhibit superparamagnetic behavior based on their small coercivity. A surfactant may be used during the polymerization to avoid aggregation of the magnetic particles. The concentration of surfactant may be maintained below the critical micellar concentration (cmc) in the pre-emulsion.
In another alternative embodiment, spheroid magnetic polymers may be synthesized having thin polystyrene (PS) cores and thicker Fe3O4 shell. Another crosslinked polymer gel/matrix may include polyvinylpyrrolidone, using peroxide (H2O2) as an oxidizing agent, by a simple two-step process. The magnetic composite synthesis was obtained by carbonizing the polymer gel at 400° C. for 1 hour. The composites were synthesized with different magnetic behavior according to the hydrothermal process conditions, mainly by varying the amount of oxidizing agent. They concluded that several synthesis parameters could significantly affect the spheroid magnetic polymer properties. The synthesis of spheroid magnetic polymers should be followed by precise physico-chemical characterizations.
Spheroid magnetic polymers may swell in solvents, particularly spheroids with gel-like structure, and the formation of pseudo-gel may occur due to the nanoparticle interaction with the polymer chains. The swelling of the spheroid magnetic polymers in a water or solvent medium may improve hydrocarbon recovery and/or drilling performance in terms of lost circulation by filling the cracks in the wellbore and/or the formation. The swelling in turn produces high pressure on the wall of the wellbore. The cross-linking between swollen spheroid magnetic polymers may also increase the ability of the spheroid magnetic polymers to prevent or inhibit lost circulation. The reversible pseudo-gels comprising spheroid magnetic polymers will collapse when the applied magnetic field or electric field is removed.
Different researchers have observed that the magnetic behavior of spheroid magnetic polymers may be significantly altered as a function of both particle characteristics (such as type, size, and concentration) and polymer structure obtained (encapsulating the magnetic particles). From a magnetic viewpoint, the spheroid magnetic polymers are dilute ensembles of non-interacting magnetic moments. In one non-limiting example, a ferrofluid saturation magnetizations (Ms) composed of 15 nm magnetite (Fe3O4) particles (without polymerization) had a higher magnetization than the magnetic polymers comprising the 15 nm magnetite. This reduction in the Ms of magnetic polymers was attributed to two possible factors: oxidation processes during the synthesis, and/or the presence of polymer on the surface of the particles.
Spheroid magnetic polymers may be designed to better control loss of hydrocarbon recovery during drilling operations. The wettability of the spheroid magnetic polymer can be changed as well as their magnetic properties, which allows the spheroid magnetic polymers to be used in water-based drilling muds, oil-based drilling muds, synthetic-based drilling muds, and combinations thereof.
To improve hydrocarbon recovery and/or drilling performance in a subterranean reservoir wellbore, a wall of the wellbore may have spheroid magnetic polymers thereon. In one non-limiting instance, a downhole fluid having spheroid magnetic polymers may be circulated within the wellbore to form at least a partial reversible pseudo-gel that includes spheroid magnetic polymers along the wall of the wellbore. The amount of spheroid magnetic polymers within the downhole fluid may range from about 0.01 wt % independently to about 5.0 wt %, or alternatively from about 0.01 wt % independently to about 1.0 wt %. In another non-limiting embodiment, a magnetic polymer pseudo-gel may be applied to the wellbore wall prior to the insertion of the wellbore into the reservoir.
A magnetic field or electric field may be applied to the wellbore, or more specifically the wall of the wellbore having the spheroid magnetic polymers to form a pseudo-gel. The magnetic field may allow the spheroid magnetic polymers to improve hydrocarbon recovery and/or drilling performance from the wellbore by a method, such as but not limited to preventing or inhibiting lost circulation, improving or increasing rate of penetration (ROP), reducing frictional pressure during well-bore construction, preventing or inhibiting corrosion, and combinations thereof. Lost circulation may be prevented or inhibited where the magnetic field or electric field allows the magnetic polymers to swell within a crack of the wall/formation upon application of the magnetic field or electric field to the wellbore. ROP may be improved or increased by controlling the fluid rheological properties upon application of the magnetic field or electric field. The frictional pressure may be reduced during wellbore construction by adding spheroid magnetic polymers to the drilling fluid and/or the completion fluid with subsequent application of the magnetic field or electric field to the magnetic polymers.
Chemicals, such as but not limited to corrosion inhibitors, drag reducers, fluid loss agents, scale inhibitors, asphaltene inhibitors, paraffin dispersants, and combinations thereof may be encapsulated by the spheroid magnetic polymers. These chemicals may be delivered upon controlled release of the chemicals from the spheroid magnetic polymers within the desired place of the well. The spheroid magnetic polymers may be guided by a magnetic field or electric field where the magnetic field or electric field causes swelling of the spheroid magnetic polymer and release of the chemical. The corrosion inhibitors may prevent or inhibit corrosion at a desirable location of the wellbore. Prevent or inhibit is defined herein to mean that the lost circulation or corrosion may be suppressed or reduced. That is, it is not necessary for lost circulation or corrosion to be entirely prevented for the methods discussed herein to be considered effective, although complete prevention is a desirable goal.
The downhole fluids, which may include drilling fluids, completion fluids, production fluids, and servicing fluids, except as noted, may also include other typical additives for improving the performance of the downhole fluid. In another non-limiting embodiment, the downhole fluid may include additives to aid in better functionality of the magnetic polymers. Such additives may be or include, but are not limited to surfactants, salts, pH control additives, viscosifier additives, and combinations thereof.
Surfactants may be used to enhance the thermodynamic, physical, and rheological properties of magnetic polymers within the downhole fluids. These spheroid magnetic polymers may be dispersed in the downhole fluid, which may be a drilling fluid, a completion fluid, a production fluid, or a stimulation fluid. The downhole fluid may be a non-aqueous fluid or an aqueous fluid, or the downhole fluid may be a single-phase fluid, or a poly-phase fluid, such as an emulsion of oil-in-water (O/W) or water-in-oil (W/O). The spheroid magnetic polymers may be used in conventional operations and challenging operations that require stable fluids for high temperature and pressure conditions (HTHP).
It may be helpful in designing new fluids containing spheroid magnetic polymers to match the amount of the spheroid magnetic polymers with the proper surfactant/downhole fluid ratio to achieve the desired dispersion for the particular fluid. Surfactants are generally considered optional, but may be used to improve the quality of the dispersion of the spheroid magnetic polymers within the downhole fluid. Such surfactants may be present in the downhole fluids in amounts ranging from about 0.001 wt % independently to about 10 wt %, alternatively from about 0.01 wt % independently to about 5 wt %, where “independently” as used herein means that any lower threshold may be combined with any upper threshold to define an acceptable alternative range.
Expected suitable surfactants may include, but are not necessarily limited to non-ionic, anionic, cationic, amphoteric surfactants and zwitterionic surfactants, janus surfactants, and blends thereof. Suitable nonionic surfactants may include, but are not necessarily limited to, alkyl polyglycosides, sorbitan esters, methyl glucoside esters, amine ethoxylates, diamine ethoxylates, polyglycerol esters, alkyl ethoxylates, alcohols that have been polypropoxylated and/or polyethoxylated or both. Suitable anionic surfactants may include alkali metal alkyl sulfates, alkyl ether sulfonates, alkyl sulfonates, alkyl aryl sulfonates, linear and branched alkyl ether sulfates and sulfonates, alcohol polypropoxylated sulfates, alcohol polyethoxylated sulfates, alcohol polypropoxylated polyethoxylated sulfates, alkyl disulfonates, alkylaryl disulfonates, alkyl disulfates, alkyl sulfosuccinates, alkyl ether sulfates, linear and branched ether sulfates, alkali metal carboxylates, fatty acid carboxylates, and phosphate esters. Suitable cationic surfactants may include, but are not necessarily limited to, arginine methyl esters, alkanolamines and alkylenediamides. Suitable surfactants may also include surfactants containing a non-ionic spacer-arm central extension and an ionic or nonionic polar group. Other suitable surfactants may be dimeric or gemini surfactants, cleavable surfactants, janus surfactants and extended surfactants, also called extended chain surfactants.
In the foregoing specification, the invention has been described with reference to specific embodiments thereof, and has been described as effective in providing methods and structures for improving hydrocarbon recovery and/or drilling performance by a method, such as but not limited to preventing or inhibiting lost circulation, improving or increasing the rate of penetration (ROP), reducing frictional pressure during wellbore construction, preventing or inhibiting corrosion, and combinations thereof. However, it will be evident that various modifications and changes can be made thereto without departing from the broader scope of the invention as set forth in the appended claims. Accordingly, the specification is to be regarded in an illustrative rather than a restrictive sense. For example, specific downhole fluids, magnetic particles, polymeric components, pseudo-gels and spheroid magnetic polymers falling within the claimed parameters, but not specifically identified or tried in a particular composition or method, are expected to be within the scope of this invention.
The present invention may suitably comprise, consist or consist essentially of the elements disclosed and may be practiced in the absence of an element not disclosed. For instance, the method for producing hydrocarbons may comprise, consist essentially of or consist of improving a property selected from the group consisting of hydrocarbon recovery, drilling performance, and combinations thereof; where the method comprises, consists of or consists essentially of applying a magnetic field or electric field to the wall of a subterranean reservoir wellbore where the wall has been at least partially coated with spheroid magnetic polymers, and the magnetic field or electric field forms a reversible pseudo-gel that improves hydrocarbon recovery and/or drilling performance by a process, such as but not limited to preventing or inhibiting lost circulation, improving or increasing rate of penetration (ROP), reducing frictional pressure during wellbore construction, preventing or inhibiting corrosion, and combinations thereof.
There is also provided a subterranean reservoir wellbore comprising, consisting essentially of, or consisting of, a wall with spheroid magnetic polymers disposed thereon, wherein each spheroid magnetic polymer comprises, consists essentially of, or consists of, a magnetic particle selected from the group consisting of iron, cobalt, nickel, magnesium, molybdenum, tantalum, alloys thereof, spinels thereof, oxides thereof, and combinations thereof, and wherein the spheroid magnetic polymers have an average diameter ranging from about 5 to about 1000 nm.
The words “comprising” and “comprises” as used throughout the claims, are to be interpreted to mean “including but not limited to” and “includes but not limited to”, respectively.
As used herein, the singular forms “a,” “an,” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise.
As used herein, the term “and/or” includes any and all combinations of one or more of the associated listed items.
As used herein, relational terms, such as “first,” “second,” “top,” “bottom,” “upper,” “lower,” “over,” “under,” etc., are used for clarity and convenience in understanding the disclosure and do not connote or depend on any specific preference, orientation, or order, except where the context clearly indicates otherwise.
As used herein, the term “substantially” in reference to a given parameter, property, or condition means and includes to a degree that one of ordinary skill in the art would understand that the given parameter, property, or condition is met with a degree of variance, such as within acceptable manufacturing tolerances. By way of example, depending on the particular parameter, property, or condition that is substantially met, the parameter, property, or condition may be at least 90.0% met, at least 95.0% met, at least 99.0% met, or even at least 99.9% met.
As used herein, the term “about” in reference to a given parameter is inclusive of the stated value and has the meaning dictated by the context (e.g., it includes the degree of error associated with measurement of the given parameter).
This application is a continuation-in-part application of U.S. patent application Ser. No. 14/610,407 filed Jan. 30, 2015, which in turn claims the benefit of Provisional Patent Application No. 61/944,923 filed Feb. 26, 2014, both of which are incorporated by reference herein in their entireties.
Number | Date | Country | |
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61944923 | Feb 2014 | US |
Number | Date | Country | |
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Parent | 14610407 | Jan 2015 | US |
Child | 15880000 | US |