This invention relates generally to inhibiting or preventing the formation of mineral scales on surfaces in industrial processes.
Scale formation is a persistent problem encountered in various industrial processes, which results in a significant reduction of the efficiency and lifetime of these processes. The challenges associated with scale formation have a major affect on the capital and operating costs of most conversion processes. For example, the costs associated with heat exchanger fouling for industrialized countries has been estimated to be about 0.25% of the gross national product (GNP) for these countries.
Among well-known mineral scale deposits, CaSO4 is a mineral scale deposit encountered in many industrial processes. Besides having low solubility limits, a major difficulty with CaSO4 is the phase transformation between its hydrates and polymorphs, particularly at elevated temperatures (above 100° C.), which results in a significant reduction of its solubility limits. Furthermore, the solubility of CaSO4 is strongly affected by the presence and concentrations of other ions in the system. Another challenge with CaSO4 scale deposits is that they form even at low pH and can be removed effectively only by mechanical means, which significantly increases the operating cost of the plant.
Current solutions for scale mitigation involve chemical additives that can either shift the scale equilibrium conditions or act as inhibitors by increasing scale formation time. These solutions are typically expensive, environmentally unfriendly, and, in most cases, far from adequate. Hence, to achieve further advances in economics and efficiency of various processes, innovative technologies and groundbreaking ideas for scale mitigation and control must be developed.
There is a need for methods and devices for preventing or inhibiting the formation of scale in numerous industrial processes.
This invention relates generally to articles, devices, and methods for inhibiting or preventing the formation of scale during various industrial processes. In certain embodiments, a vessel is provided for use in an industrial process, the vessel including a surface in contact with a mineral solution, wherein the surface is provided or is modified to have γpolar/γtotal no greater than about 0.2 and/or the surface is provided or is modified to have a surface energy γ no greater than about 32 mJ/m2, thereby providing resistance to mineral scale deposits thereupon.
In one aspect, the invention relates to a vessel for use in an industrial process, the vessel including a surface in contact with a solution, wherein the solution includes at least one mineral and the surface has γ no greater than about 32 mJ/m2, thereby providing resistance to mineral scale deposits thereupon. In certain embodiments, the surface has γ no greater than about 25 mJ/m2. In certain embodiments, the surface has γpolar/γtotal no greater than about 0.125. In certain embodiments, the surface has γpolar/γtotal no greater than about 0.05. In certain embodiments, the surface is a scale-phobic surface that inhibits scale formation thereupon. In certain embodiments, the surface includes a fluoropolymer. In certain embodiments, the fluoropolymer is a silsesquioxane. In certain embodiments, the fluoropolymer is fluorodecyl polyhedral oligomeric silsesquioxane. In certain embodiments, the fluoropolymer is a member selected from the group consisting of tetrafluoroethylene (ETFE), fluorinated ethylene-propylene copolymer (FEP), polyvinylidene fluoride (PVDF), perfluoroalkoxy-tetrafluoroethylene copolymer (PFA), polytetrafluoroethylene (PTFE), tetrafluoroethylene perfluoromethylvinylether copolymer (MFA), ethylene-chlorotrifluoroethylene copolymer (ECTFE), ethylene-tetrafluoroethylene copolymer (ETFE), perfluoropolyether, and Tecnoflon.
In certain embodiments, the surface is a coating. In certain embodiments, the surface includes a silane coating. In certain embodiments, the silane coating is a member selected from the group consisting of methylsilane, phenylsilane, isobutylsilane, dimethylsilane, tetramethyldisilane, hexylsilane, octadecylsilane, and fluorosilane.
In certain embodiments, the surface is located on an interior wall of a heat exchanger.
In certain embodiments, the mineral scale deposits include at least one of calcium sulfate, calcium carbonate, barium sulfate, silica, and/or iron.
In certain embodiments, the surface includes discrete nucleation sites thereupon, thereby promoting preferred mineral scale nucleation at the discrete nucleation sites, a resulting defective interface at the surface, and reduced mineral scale adhesion upon the surface.
In certain embodiments, the surface has heterogeneous surface chemistry. In certain embodiments, the surface is patterned with discrete hydrophobic regions and discrete hydrophilic regions. In certain embodiments, the surface is textured. In certain embodiments, the surface includes micro-scale and/or nano-scale particles deposited thereupon. In certain embodiments, the surface includes sintered silica and/or porous anodized aluminum. In certain embodiments, the surface includes micro-scale and/or nano-scale posts. In certain embodiments, the surface includes silicon posts. In certain embodiments, the posts have hydrophobic surfaces. In certain embodiments, the posts have walls that are hydrophobic and tops that are hydrophilic, thereby promoting preferred mineral scale nucleation at the tops and resulting in air pockets between posts.
In certain embodiments, the surface has γpolar/γtotal no greater than about 0.15. In certain embodiments, the surface has γpolar/γtotal no greater than about 0.10. In certain embodiments, the surface has γ no greater than about 20 mJ/m2. In certain embodiments, the surface has γ no greater than about 15 mJ/m2. In certain embodiments, the surface has γ no greater than about 10 mJ/m2.
In certain embodiments, the vessel is a conduit or receptacle (e.g., pipeline) used in deep sea oil and/or gas recovery. In certain embodiments, the vessel is a conduit or receptacle of a heat exchanger. The description of elements of the embodiments above can be applied to this aspect of the invention as well.
In another aspect, the invention relates to a method of retrofitting a vessel for improved resistance to mineral scale deposits, the method including applying a coating to produce a surface having γpolar/γtotal no greater than about 0.2, thereby providing resistance to mineral scale deposits thereupon. In certain embodiments, the surface has γpolar/γtotal no greater than about 0.125 or 0.05. The description of elements of the embodiments above can be applied to this aspect of the invention as well.
In another aspect, the invention relates to a method of retrofitting a vessel for improved resistance to mineral scale deposits, the method including applying a coating to produce a surface having γ no greater than about 32 mJ/m2, thereby providing resistance to mineral scale deposits thereupon. In certain embodiments, the surface has γ no greater than about 25 mJ/m2, 20 mJ/m2, 15 mJ/m2, or 10 mJ/m2. In certain embodiments, the vessel is a conduit or receptacle (e.g., pipeline) used in deep sea oil and/or gas recovery. In certain embodiments, the vessel is a conduit or receptacle of a heat exchanger. The description of elements of the embodiments above can be applied to this aspect of the invention as well.
In another aspect, the invention relates to a method for preparing a surface to provide improved resistance to formation of mineral scale deposits thereupon, the method including the steps of forming a surface and determining that the surface has γpolar/γtotal no greater than about 0.2 and/or has γtotal no greater than about 32 mJ/m2, thereby providing improved resistance to formation of mineral scale deposits thereupon. In certain embodiments, the surface has γpolar/γtotal no greater than about 0.125 or 0.05. In certain embodiments, the surface has γ no greater than about 25 mJ/m2, 20 mJ/m2, 15 mJ/m2, or 10 mJ/m2. The description of elements of the embodiments above can be applied to this aspect of the invention as well.
In another aspect, the invention relates to a method for preparing a surface to provide improved resistance to formation of mineral scale deposits thereupon, the method including the step of determining γpolar and γtotal of the surface and adjusting the surface such that γpolar/γtotal greater than about 0.2. In certain embodiments, γpolar/γtotal is no greater than about 0.125 or 0.05. In certain embodiments, the method further includes the step of adjusting the surface such that γtotal is no greater than about 32 mJ/m2. In certain embodiments, γ is no greater than about 25 mJ/m2, 20 mJ/m2, 15 mJ/m2, or 10 mJ/m2. In certain embodiments, adjusting the surface comprises recoating or replacing the surface. In certain embodiments, the surface is a surface of a conduit or receptacle (e.g., pipeline) used in deep sea oil and/or gas recovery. In certain embodiments, wherein the surface is a surface of a conduit or receptacle of a heat exchanger. The description of elements of the embodiments above can be applied to this aspect of the invention as well.
The objects and features of the invention can be better understood with reference to the drawings described below, and the claims. The drawings are not necessarily to scale, emphasis instead generally being placed upon illustrating the principles of the invention. In the drawings, like numerals are used to indicate like parts throughout the various views.
While the invention is particularly shown and described herein with reference to specific examples and specific embodiments, it should be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention.
a is a graph of measured contact angles for three separate liquids on various solid surfaces, according to illustrative embodiments of the invention.
b is a graph of surface energy for various solid surfaces, calculated from the contact angles of
It is contemplated that compositions, mixtures, systems, devices, methods, and processes of the claimed invention encompass variations and adaptations developed using information from the embodiments described herein. Adaptation and/or modification of the compositions, mixtures, systems, devices, methods, and processes described herein may be performed by those of ordinary skill in the relevant art.
Throughout the description, where articles, devices and systems are described as having, including, or comprising specific components, or where processes and methods are described as having, including, or comprising specific steps, it is contemplated that, additionally, there are articles, devices, and systems of the present invention that consist essentially of, or consist of, the recited components, and that there are processes and methods according to the present invention that consist essentially of, or consist of, the recited processing steps.
Similarly, where articles, devices, mixtures, and compositions are described as having, including, or comprising specific compounds and/or materials, it is contemplated that, additionally, there are articles, devices, mixtures, and compositions of the present invention that consist essentially of, or consist of, the recited compounds and/or materials.
It should be understood that the order of steps or order for performing certain actions is immaterial so long as the invention remains operable. Moreover, two or more steps or actions may be conducted simultaneously.
The mention herein of any publication, for example, in the Background section, is not an admission that the publication serves as prior art with respect to any of the claims presented herein. The Background section is presented for purposes of clarity and is not meant as a description of prior art with respect to any claim.
The use of hydrate-phobic surfaces for reducing hydrate adhesion is described in U.S. patent application Ser. No. 13/218,095, titled “Articles and Methods for Reducing Hydrate Adhesion,” and published as U.S. Patent Application Publication No. 2012/0160362, the text of which is hereby incorporated by reference herein in its entirety.
Described herein are experiments with organosilane-coated substrates with varying surface energies for which a systematic demonstration of the effect of surface energy on scale formation is performed. Scale formation is qualitatively (using SEM) and quantitatively (weight gain) observed at various residence times, in contact with a mineral solution. In one experiment, it is shown that an 85% reduction in weight gain due to scale formation can be achieved by decreasing surface free energy from 51 mJ/m2 (bare glass) to 10 mJ/m2 (fluorosilane-coated glass). Also discovered is the importance of the polar component of surface free energy as a factor controlling scale formation on a substrate. Application of this discovery is described herein, with respect to selection, modification, measurement, and/or monitoring of surfaces of vessels having prescribed levels of total surface free energy and/or ratios of γpolar/γtotal.
It is believed that clusters of salt molecules that are gathered together under random thermal motion must reach a critical size to sustain growth. The free energy barrier (ΔG) of the heterogeneous nucleation of a scale embryo of critical size on a smooth surface, and the corresponding nucleation rate (J) can be expressed as:
where σsubstrate-solution is the substrate surface energy, r* is the critical radius of scale nuclei, k is the Bolzmann constant, and J0 is a kinetic constant. The parameter m is the ratio of the interfacial energies given by m=(σsubs,solution-Γsubs,salt/σsalt,solution where σsubs,salt and σsalt,solution are the substrate-salt and salt-solution interfacial energies, respectively.
Without wishing to be bound by a particular theory, from Eq. (1), the nucleation of scale crystals on a substrate appears to be governed by the surface energy of the substrate. It is experimentally demonstrated herein that decreasing surface free energy decreases scale formation.
In accordance with certain embodiments, it is presently discovered that scale formation may be reduced by as much as about 85% by reducing the surface energy of the underlying solid surface. In one experiment, a range of solid surfaces with different surface energies was created by depositing several self-assembling organic silane coatings, with surface energies varying between 10 and 41 mJ/m2, onto the surfaces of glass substrates. Bare glass surfaces, with a surface energy of 51 mJ/m2, were tested along with the coated surfaces, as a control measure. To quantify surface energies, advancing and receding contact angles of three liquids, including one non-polar liquid (di-iodo-methane, DIM) and two polar liquids (water and ethylene glycol, EG), on all substrates, were measured using a ramé-hart goniometer (500-Fl). Surface energies were calculated using the Van Oss-Chaudhury-Good theory.
Weight gain on substrates due to scale formation can be characterized by comparing the substrates' weights before and after the experiment. For example, ˜85% reduction was observed in the weight gain of a substrate coated with fluorosilane (
In addition to thermodynamic aspects of surface energy effects on scale formation, the scale growth is demonstrated on three substrates with surface energies ranging from the lowest (fluorosilane coated) to intermediate (hexylsilane coated) to the highest (bare glass).
An important breakdown of surface interactions in terms of polar and apolar terms has been identified herein that further correlates the effect of surface energy and surface polarity on scale formation. Polar interactions are believed to exist due to the Lewis acid and Lewis base sites at the surface that can chemically bond with scale nuclei. Apolar interactions, however, appear to be roughly in the form of London dispersion forces and depend on the polarizability (a) and ionization energy (I) of the molecules involved; these interactions may be referred to as Lifshitz-van der Waals interactions. The polar and apolar components of surface energy may be quantified using the acid-base theory of contact angles (van Oss-Chaudhury-Good approach):
γl,i(1+cos θi)=2(√{square root over (γsLWγl,iLW)}+√{square root over (γs+γl,i−)}+√{square root over (γs−γl,i+)}) (2)
where θi is the measured contact angle of liquid i on solid s, γLW, γ+, and γ− are the Lifshitz-van der Waals (apolar) and the polar components due to the Lewis acid and Lewis base sites, respectively. For reference probe liquids, the values of γLW, γ+, and γ− have been reported previously in Good, R. J. J. Adhes. Sci. Technol. 6, 1269-1302 (1992), the relevant contents of which are incorporated herein by reference. Hence, Eq. (2) provides three components of the surface free energy for any solid. Therefore, determination of these values may be performed by simultaneous solving of the equation for three different liquids.
For example, the contact angles of three probe liquids (water, ethylene glycol, and diiodomethane) can be measured to determine the values of γsLW, γs+, and γs− for all the substrates. The polar component of the surface free energy (γsAB) can then be calculated using Eq. (3):
γsAB=2√{square root over (γs+)}√{square root over (γs−)} (3)
where the superscript AB refers to acid-base (polar) interactions.
Examples of measured contact angles and calculated surface free energy (γtotal) and its components (γLW and γAB) are reported in Table 1.
In certain embodiments, an apparatus or device (e.g., a vessel, such as a conduit, receptacle, pipeline, or the like) is provided that reduces or prevents the formation of mineral scale. The mineral scale may include, for example, calcium sulfate, calcium carbonate, barium sulfate, silica, iron, and/or other deposits. In certain embodiments, the device reduces or prevents the formation of mineral scale by having a surface with a low surface energy, said surface having exposure to a mineral solution. For example, the surface energy may be no greater than 32 mJ/m2, no greater than 25 mJ/m2, no greater than 20 mJ/m2, no greater than 15 mJ/m2, or no greater than 10 mJ/m2. In certain embodiments, the surface has a contribution of polar attractions γpolar in the total energy γtotal of the surface (i.e., the ratio γpolar/γtotal) of no greater than 0.2, no greater than 0.15, no greater than 0.12, no greater than 0.1, no greater than 0.05, or no greater than 0.01. In certain embodiments, γpolar/γtotal is in a range of 0.2 to 0.01, or 0.15 to 0.1.
Polar attractions γpolar are believed to exist due to Lewis acid-Lewis base interactions, which are usually in the form of hydrogen bonds. Non-polar interactions are believed to be in the form of London dispersion forces and depend on the polarizability (α) and ionization energy (I) of the molecules involved; these interactions are referred to as Lifshitz-van der Waals interactions. Referring to
In certain embodiments, a method of retrofitting a device (e.g., a vessel) is provided for improved resistance to scale formation. The method includes depositing a coating (e.g., self-assembling organic silane coating) onto a surface of the device. The coating reduces a surface energy within the device to no greater than 32 mJ/m2. In further embodiments, the coating reduces the surface energy to no greater than 25 mJ/m2, no greater than 20 mJ/m2, no greater than 15 mJ/m2, or no greater than 10 mJ/m2. In certain embodiments, the coating provides a surface having γpolar/γtotal of no greater than 0.2, no greater than 0.15, no greater than 0.12, no greater than 0.1, no greater than 0.05, or no greater than 0.01. In certain embodiments, γpolar/γtotal is in a range of 0.2 to 0.01, or 0.15 to 0.1.
In certain embodiments, a scale-phobic surface is provided for minimizing or preventing the formation of scale. The scale-phobic surface may include, for example, a silane coating, such as methylsilane, phenylsilane, isobutylsilane, dimethylsilane, tetramethyldisilane, hexylsilane, octadecylsilane, and/or fluorosilane. In certain embodiments, the scale-phobic surface includes a fluoropolymer. The fluoropolymer may be, for example, a silsesquioxane, such as fluorodecyl polyhedral oligomeric silsesquioxane. In certain embodiments, the fluoropolymer includes tetrafluoroethylene (ETFE), fluorinated ethylene-propylene copolymer (FEP), polyvinylidene fluoride (PVDF), perfluoroalkoxy-tetrafluoroethylene copolymer (PFA), polytetrafluoroethylene (PTFE), tetrafluoroethylene perfluoromethylvinylether copolymer (MFA), ethylene-chlorotrifluoroethylene copolymer (ECTFE), ethylene-tetrafluoroethylene copolymer (ETFE), perfluoropolyether, and/or Tecnoflon.
In some embodiments, the invention relates to an article for use in industrial operation or research set-ups, the article having a surface with lowered surface energy. In certain embodiments, the article is a pipeline (or a part or coating thereof), and the surface is configured to inhibit scale formation thereupon. In certain embodiments, the article is a heat exchanger part or an oil or gas pipeline (or a part or coating thereof), and the surface is configured to inhibit scale formation thereupon.
To test the affect of surface energy of the modified substrates on scale formation, a saturated solution of CaSO4 in water was prepared by dissolving reagent grade chemicals directly without further purification. Batches of four identical coated substrates were placed in a rectangular dish using a holder tray, and the dish was filled with 200 mL of the saturated solution. All dishes (10 batches in this experiment) were then placed on a 15-position hotplate to keep the temperature similar within the holders. The temperature of the solution in all holders was monitored during the term of the experiment, and the measured values were consistent to within ±3° C.
At each sampling round, both solution and substrate samples were taken. Solution samples were withdrawn using a 2 mL syringe, and filtration was performed using 0.22 μm Nylon syringe filters. Withdrawn samples were then diluted by 2 wt. % HNO3 and stored in sealed plastic test tubes at room temperature. The calcium concentration was determined by Inductively Coupled Plasma (ICP-OES) analysis.
The substrate samples taken from each batch were dried and weight gain due to CaSO4 solid deposits was calculated by comparing the weight of each sample from before and after the experiment.
To further investigate the affect of surface energy on scale nucleation and adhesion, the breakdown of surface interactions in terms of polar and non-polar attractions was investigated. Polar attractions exist due to the Lewis acid-Lewis base interactions, which are usually in the form of hydrogen bonds. Non-polar interactions are basically in the form of London dispersion forces and depend on the polarizability (a) and ionization energy (I) of the molecules involved. These interactions are referred to as Lifshitz-van der Waals interactions.
The results showed that significant reduction in scale deposition may be achieved if the contribution of polar attractions in the total energy of the surface (i.e., γpolar/γtotal) is below 10%. The results of this work provide guidelines to design new surfaces with improved scale formation properties by manipulating the surface chemistry and morphology. Such ability to control and mitigate scale formation not only reduces costs of chemical and thermal treatment for scale inhibition and removal, but it also has implications for efficiency and lifetime enhancement and process reliability improvement in various industrial processes.
In this Example, a catalogue of smooth substrates comprising functionalized coatings with surface free energies ranging between 10 and 50 mJ/m2, by depositing self-assembled monolayers of organosilanes on glass substrates. Their surface energy by measuring contact angles of three probe fluids (water, ethylene glycol, diiodomethane) and quantifying the polar and apolar components of surface free energy using the van Oss-Good-Chaudhury approach.
To systematically study the effect of surface free energy on scale formation, the modified surfaces were exposed to a saturated solution of calcium sulfate in water for up to three days. The experimental set-up and matrix summarizing test conditions are shown in
The formation of organic silane-based self-assembled monolayers (SAMs) on silicon oxide surface and glass surface provides an opportunity to introduce chemically well-defined thin films at the molecular scale.
SAMs of alkylchlorosilanes (Rn—Si—Cl4-n) and alkylalkoxysilanes (Rn—Si—(OR′)4-n) (see Table 2) are fabricated. These silanes require hydroxylated surfaces as the substrate for their formation. The driving force for this self-assembly is the in situ formation of polysiloxane, which is connected to surface silanol groups (—SiOH) via Si—O—Si bonds. We conformed the complete surface reaction of the —SiCl3 groups using X-ray photoelectron spectroscopy (XPS).
SAMs of alkylchlorosilanes, with Rn—Si—Cl4-n precursor, were fabricated using a solution of 0.1 vol % silane in toluene; 0.6 vol % water was added to the solution to promote the reaction. Glass slides (from vwr, microscope slides, 75×25×1 mm in dimensions) were immersed in the solution and sonicated for 2 min. After the reaction was completed, modified substrates were cleaned by sonication in acetone for 2 min and dried them using N2 gas (Air gas, NI300).
Silane SAMs of alkylalkoxysilanes with by Rn—Si—(OR′)4-n were fabricated in an acidic environment to promote the reaction. Glass slides were immersed in a 0.2 vol % silane in ethanol under sonication for 2 min. Hydrochloric acid (from Mallinckrodt, ACS grade) was added to the solution to decrease the solution pH to 2 (˜0.075 vol %). After sonication, glass slides were left in the slime solution for 24 h. They were then washed with water and dried with N2 gas (Air gas, NI300).
As shown in this Example, a catalogue of organosilane-coated substrates are made with varying surface energies and performed a systematic study of surface energy effect on scale formation. Scale formation on the substrates was characterized qualitatively (using SEM) and quantitatively (weight gain) at various residence times. The results show that 85% reduction in weight gain due scale formation can be achieved by decreasing surface free energy form 51 mJ/m2 (bare glass) to 10 mJ/m2 (fluorosilane-coated glass). It is believed that the reason behind this behavior is attributed to the nucleation theory that substrates with high surface energy have a lower energy barrier for nucleation.
In addition to thermodynamic aspect, the scale growth over time on substrates with different surface energies was studies. It is found that low surface energy substrates have fewer numbers, but larger, salt crystal deposited on them. Without wishing to be bound by a particular theory, it is believed that this is due to the fact that the energy barrier to grow a salt crystal after it is formed is less than that to form a new salt embryo on the surface. The breakdown of surface free energy was also studies and it was found that the polar component is the key factors that control scale formation on a substrate. This work can be used on developing materials that are resistant to scaling for industrial applications. The results of this work provide guidelines to design scalephobic surfaces by manipulating the surface chemistry and make it less prone to attract scale nuclei. Such ability to control and mitigate scale formation would reduce costs of chemical and thermal treatments for scale inhibition and removal. This also provides new pathways to enhance the reliability, lifetime, and efficiency of various industrial processes.
While the invention has been particularly shown and described with reference to specific preferred embodiments, it should be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
This application claims priority to and the benefit of, and incorporates herein by reference in its entirety, U.S. Provisional Patent Application No. 61/560,469, filed Nov. 16, 2011.
Number | Date | Country | |
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61560469 | Nov 2011 | US |