This application claims priority to European application No. 12161236.0 filed on 26 Mar. 2012, the whole content of this application being incorporated herein by reference for all purposes.
The present invention pertains to a pipe comprising at least one fluoropolymer layer and to use of said pipe in heat exchangers and in downhole operations including drilling operations.
Fluoropolymers derived from tetrafluoroethylene (TFE) and perfluorinated alkyl vinyl ethers (PAVEs) have found wide applications as coatings and linings of process vessels, storage tanks, pipes, valves and fittings due to their high chemical inertness, high melting points, high service temperatures and thermal stability.
In particular, pipes are typically used for conveying oils and gases at temperatures of usually above 100° C., preferably above 200° C., depending on the application. For instance, pipes used in drilling operations need to withstand high temperatures and pressures, depending where the well is drilled and how deep. The drilling operations indeed involve deeper and deeper wells and typically reach temperatures as high as 260° C. or higher than 260° C., especially proximate to the bottom of the well.
Melt-processable fluoropolymers derived from tetrafluoroethylene (TFE) and perfluoroalkylvinylethers (PAVEs), which are commonly known in the art for being suitable for manufacturing shaped articles such as pipes, typically comprise from 1% to 5% by moles of recurring units derived from said PAVEs.
These fluoropolymers have generally a melting point of at least 265° C., so that they are advantageously used in applications where high operating temperatures are required. In particular, melt-processable TFE copolymers with perfluoropropylvinylether (PPVE) are most preferred because of their higher melting point, typically between 302° C. and 310° C.
There is thus the need in the art for pipes which are endowed with improved mechanical properties and improved thermal resistance at high operating temperatures, while retaining chemical resistance to corrosive chemical agents.
It has been now found that the pipe of the present invention successfully enables overcoming the deficiencies of the pipes known in the art.
It is thus an object of the present invention a pipe comprising at least one layer at least comprising, preferably consisting essentially of (or being made of), a tetrafluoroethylene (TFE) copolymer comprising from 0.8% to 2.5% by weight of recurring units derived from at least one per-fluor-inated alkyl vinyl ether having formula (I) here below:
CF2═CF—O—Rf (I)
wherein Rf is a linear or branched C3-C5 perfluorinated alkyl group or a linear or branched C3-C12 perfluorinated oxyalkyl group comprising one or more ether oxygen atoms,
said TFE copolymer having a melt flow index comprised between 0.5 and 6.0 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg [polymer (F)].
The Applicant has surprisingly found that the polymer (F) according to the present invention is successfully endowed with improved mechanical properties with respect to commercially available TFE copolymers with PAVEs, in particular higher yield strength values and lower creep strain values. It is well known in the art that these properties are related to pipes burst resistance and/or pipes decompression under the effect of pressure impacts
The Applicant has thus found that the pipe of the present invention advantageously withstand high pressure and high temperature conditions, while retaining chemical resistance in harsh environments and thermal resistance at high temperatures.
The yield strength of the polymer (F) is a measure of the maximum stress to be applied at which the polymer (F) begins to deform plastically. The stress at which yield occurs is dependent on both the rate of deformation (strain rate) and, more significantly, on the temperature at which the deformation occurs.
The creep strain of the polymer (F) is a measure of its tendency to deform plastically under the influence of an applied stress. It occurs as a result of long term exposure to high levels of stress which are below the yield strength of the material. The rate of this deformation is a function of the material properties, exposure time, exposure temperature and the applied structural load.
For the purpose of the present invention, by the term “plastic deformation” it is hereby intended to denote permanent and non-reversible deformation of the polymer (F).
The yield strength and the creep strain of the polymer (F) are thus a measure of its tendency to deform plastically under the influence of pressure impacts, in particular at high operating temperatures.
By the term “pipe”, it is hereby intended to denote a continuous tubular pipe made of, or at least comprising, the polymer (F) as defined above or a continuous tubular pipe whose inner surface is coated with a tubular layer made of, or at least comprising, the polymer (F) as defined above.
The pipe of the present invention may be a monolayer pipe ora multilayer pipe.
By the term “monolayer pipe”, it is hereby intended to denote a pipe consisting of one tubular layer made of, or at least comprising, a polymer (F).
By the term “multilayer pipe”, it is hereby intended to denote a pipe comprising at least two concentric layers adjacent to each other, wherein at least the inner layer comprises, or preferably consists essentially of, a polymer (F).
Said at least one layer of the pipe of the invention at least comprises, but preferably consists essentially of polymer (F). This means that embodiments wherein said layer comprises polymer (F) in combination with other layer components are encompassed in the scope of the present invention. It is nevertheless understood that embodiments wherein polymer (F) is the sole polymer component are preferred. More particularly, embodiments wherein the layer is made from polymer (F) possibly in admixture with minor amounts of additional ingredients like pigment, additives, lubricants, and the like which do not substantially modify the properties of polymer (F) are preferred.
The polymer (F) of the pipe of the invention is typically manufactured by aqueous emulsion polymerisation or aqueous suspension polymerisation processes.
The polymer (F) of the pipe of the invention is preferably manufactured by aqueous emulsion polymerisation.
The aqueous emulsion polymerisation is typically carried out in an aqueous medium in the presence of an inorganic water-soluble radical initiator, such as peroxide, percarbonate, persulphate or azo compounds. A reducing agent can be added so as to make easier the initiator decomposition. Non-limitative examples of suitable reducing agents include iron salts. The initiator amount used depends on the reaction temperature and on the reaction conditions. The polymerisation process is carried out at temperatures typically comprised between 50° C. and 90° C., preferably between 70° C. and 80° C. A chain transfer agent may also be introduced during the polymerisation reaction. Non-limitative examples of suitable chain transfer agents include ethane, methane, propane, chloroform and the like. The polymerisation may be carried out in the presence of fluorinated surfactants such as for example perfluoroalkylcarboxylic acid salts (for example ammonium perfluorocaprylate, ammonium perfluorooctanoate) or other compounds such as for example perfluoroalkoxybenzensulphonic acid salts, as described for example in EP 184459 A (E.I. DU PONT DE NEMOURS AND COMPANY) 11 Jun. 1986. Some other fluorinated surfactants that can be used in the polymerization process are described in U.S. Pat. No. 3,271,341 (E.I. DU PONT DE NEMOURS AND COMPANY) 6 Sept. 1966, WO 2007/011631 (3M INNOVATIVE PROPERTIES COMPANY) 25 Jan. 2007 and WO 2010/003929 (SOLVAY SOLEXIS S.P.A.) 14 Jan. 2010. It is particularly advantageous to carry out the polymerization in aqueous phase in the presence of perfluoropolyethers, which can be added in the reaction medium under the form of aqueous emulsion in the presence of a suitable dispersing agent, as described in EP 247379 A (AUSIMONT S.P.A.) 2 Feb. 1987 or, preferably, in the form of aqueous microemulsion as described in U.S. Pat. No. 4,864,006 (AUSIMONT S.P.A.) 5 Sept. 1989.
The latex so obtained is then coagulated and the solid recovered is dried and granulated. The granules are extruded by conventional melt-processing techniques.
The polymer (F) of the pipe of the invention is advantageously melt-processable.
By the term “melt-processable”, it is hereby intended to denote a polymer (F) which can be processed by conventional melt-processing techniques.
The melt flow index measures the amount of polymer which can be pushed through a die, according to ASTM D1238 standard test method, at a specified temperature using a specified load weight. Thus, the melt flow index is a measure for the suitability for melt-processing the polymer (F). This typically requires that the melt flow index be more than 0.1 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg.
It is essential that the polymer (F) of the pipe of the invention has a melt flow index comprised between 0.5 and 6.0 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg.
It has been found that, when the melt flow index of the polymer (F) is lower than 0.5 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg, the pipe cannot be easily manufactured by melt-processing the polymer (F) using well known melt-processing techniques.
On the other hand, it has been found that, when the melt flow index of the polymer (F) is higher than 6.0 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg, the pipe obtained therefrom does not comply with the required performances under high temperature and high temperature conditions.
The polymer (F) of the pipe of the invention preferably has a melt flow index comprised between 0.6 and 5.5 g/10 min, more preferably between 0.7 and 4.5 g/10 min, even more preferably between 1.2 and 3.5 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg.
The perfluorinated alkyl vinyl ether of formula (I) of the polymer (F) of the pipe of the invention preferably complies with formula (II) here below:
CF2═CF—O—R′f (II)
wherein R′f is a linear or branched C3-C5 perfluorinated alkyl group.
Non-limitative examples of suitable perfluorinated alkyl vinyl ethers of formula (II) include, notably, those wherein R′f is a —C3F5, —C4F7 or —C5F9 group.
The perfluorinated alkyl vinyl ether of formula (I) of the polymer (F) of the pipe of the invention more preferably is perfluoropropyl vinyl ether (PPVE).
It is essential that the polymer (F) of the pipe of the invention comprises from 0.8% to 2.5% by weight of recurring units derived from at least one perfluorinated alkyl vinyl ether having formula (I) as defined above.
It has been found that, when the amount of recurring units derived from at least one perfluorinated alkyl vinyl ether having formula (I) is lower than 0.8% by weight, the pipes obtained therefrom do not comply with the required performances under high temperature and high pressure conditions.
On the other hand, it has been found that, when the amount of recurring units derived from at least one perfluorinated alkyl vinyl ether having formula (I) is higher than 2.5% by weight, the pipes obtained therefrom suffer from plastic deformation under the influence of internal pressure impacts, in particular at high operating temperatures.
The polymer (F) of the pipe of the invention preferably comprises from 1.2% to 2.5% by weight, more preferably from 1.4% to 2.2% by weight of recurring units derived from at least one perfluorinated alkyl vinyl ether having formula (I) as defined above.
The polymer (F) of the pipe of the invention preferably comprises from 1.2% to 2.5% by weight, more preferably from 1.4% to 2.2% by weight of recurring units derived from at least one perfluorinated alkyl vinyl ether having formula (I) as defined above, and preferably has a melt flow index comprised between 0.6 and 5.5 g/10 min, more preferably between 0.7 and 4.5 g/10 min, even more preferably between 1.2 and 3.5 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg.
The polymer (F) of the pipe of the invention preferably comprises from 1.2% to 2.5% by weight, more preferably from 1.4% to 2.2% by weight of recurring units derived from at least one perfluorinated alkyl vinyl ether having formula (II) as defined above, and preferably has a melt flow index comprised between 0.6 and 5.5 g/10 min, more preferably between 0.7 and 4.5 g/10 min, even more preferably between 1.2 and 3.5 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg.
Good results have been obtained using a polymer (F) comprising from 1.2% to 2.5% by weight, preferably from 1.4% to 2.2% by weight of recurring units derived from perfluoropropylvinylether (PPVE), and having a melt flow index comprised between 0.6 and 5.5 g/10 min, more preferably between 0.7 and 4.5 g/10 min, even more preferably between 1.2 and 3.5 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg.
The polymer (F) of the pipe of the invention may further comprise recurring units derived from one or more fluorinated comonomers (F) different from the perfluorinated alkyl vinyl ether having formula (I) as defined above.
By the term “fluorinated comonomer (F)”, it is hereby intended to denote an ethylenically unsaturated comonomer comprising at least one fluorine atoms.
Non-limitative examples of suitable fluorinated comonomers (F) include, notably, the followings:
(a) C2-C8 fluoro- and/or perfluoroolefins such as tetrafluoroethylene (TFE), hexafluoropropylene (HFP), pen tafluoropropylene and hexafluoroisobutylene;
(b) C2-C8 hydrogenated monofluoroolefins, such as vinylidene fluoride (VDF), vinyl fluoride; 1,2-difluoroethylene and trifluoroethylene;
(c) perfluoroalkylethylenes of formula CH2═CH—Rf0, wherein Rf0 is a C1-C6 perfluoroalkyl group;
(d) chloro- and/or bromo- and/or iodo-C2-C6 fluoroolefins such as chlorotrifluoroethylene (CTFE);
(e) (per)fluoroalkylvinylethers of formula CF2═CFORf1, wherein Rf1 is a C1-C2 fluoro- or perfluoroalkyl group, e.g. —CF3, —C2F5;
(f) (per)fluoro-oxyalkylvinylethers of formula CF2═CFOX0, wherein X0 is a C1-C12 oxyalkyl group or a C1-C12 (per)fluorooxyalkyl group having one or more ether groups, e.g. perfluoro-2-propoxy-propyl group;
(g) fluoroalkyl-methoxy-vinylethers of formula CF2═CFOCF2ORf2, wherein Rf2 is a C1-C6 fluoro- or perfluoroalkyl group, e.g. —CF3, —C2F5, —C3F7 or a C1-C6 (per)fluorooxyalkyl group having one or more ether groups, e.g. —C2F5—O—CF3;
(h) fluorodioxoles of formula
wherein each of Rf3, Rf4, Rf5 and Rf6, equal to or different from each other, is independently a fluorine atom, a C1-C6 fluoro- or per(halo)fluoroalkyl group, optionally comprising one or more oxygen atoms, e.g. —CF3, —C2F5, —C3F7, —OCF3, —OCF2CF2OCF3.
Should one or more fluorinated comonomers (F) be present, the polymer (F) of the pipe of the invention comprises typically from 0.8% to 2.5% by weight of recurring units derived from said fluorinated comonomer (F).
Nevertheless, embodiments wherein the polymer (F) is free from said additional comonomers (F) are preferred.
The polymer (F) of the pipe of these preferred embodiments advantageously consists essentially of:
It is understood that chain ends, defects or other impurity-type moieties might be comprised in the polymer (F) without these impairing its properties.
The polymer (F) of the pipe of these preferred embodiments preferably consists essentially of:
and preferably has a melt flow index comprised between 0.6 and 5.5 g/10 min, more preferably between 0.7 and 4.5 g/10 min, even more preferably between 1.2 and 3.5 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg.
The polymer (F) of the pipe of these preferred embodiments more preferably consists essentially of:
and preferably has a melt flow index comprised between 0.6 and 5.5 g/10 min, more preferably between 0.7 and 4.5 g/10 min, even more preferably between 1.2 and 3.5 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg.
Excellent results have been obtained using a polymer (F) consisting essentially of:
and having a melt flow index comprised between 0.6 and 5.5 g/10 min, more preferably between 0.7 and 4.5 g/10 min, even more preferably between 1.2 and 3.5 g/10 min, as measured according to ASTM 01238 at 372° C. under a load of 5 Kg.
The polymer (F) of the pipe of the invention is advantageously thermoplastic,
By the term “thermoplastic”, it is hereby intended to denote a polymer (F) existing, at room temperature (25° C.), below its melting point if it is semi-crystalline or below its Tg if it is amorphous. These polymers have the property of becoming soft when they are heated and of becoming rigid again when hey are cooled, without there being an appreciable chemical change. Such a definition may be found, for example, in the encyclopedia called “Polymer Science Dictionary”, Mark S. M. Alger, London School of Polymer Technology, Polytechnic of North London, UK, published by Elsevier Applied Science, 1989.
The polymer (F) of the pipe of the invention is preferably semi-crystalline.
By the term “semi-crystalline”, it is hereby intended to denote a polymer having a heat of fusion of more than 1 J/g when measured by Differential Scanning calorimetry (DSC) at a heating rate of 10° C./min, according to ASTM D 3418.
The polymer (F) of the pipe of the invention advantageously has a melting point comprised between 311° C. and 321° C., preferably between 311° C. and 318° C.
Very good results have been obtained using a polymer (F) having a melting point comprised between 312° C. and 317° C.
Most preferred polymers (F) of the pipe of the invention comprises from 1.2% to 2.5% by weight of recurring units derived from at least one perfluo-rinated alkyl vinyl ether having formula (II) and have:
Even more preferred polymers (F) of the pipe of the invention are those consisting essentially of:
The pipe of the present invention is typically manufactured by well known melt-processing techniques such as melt extrusion.
The Applicant has surprisingly found that, due to the advantageous inherent mechanical properties of the polymer (F), the pipe of the present invention successfully withstands temperatures up to 280° C., preferably up to 300° C.
The Application has also found that the pipe of the invention has advantageously a smooth inner surface.
According to a first embodiment of the invention, the multilayer pipe is a flexible riser.
By the term “flexible riser”, it is hereby intended to denote a flexible tubular pipe wherein the constituent layers comprise polymeric sheaths for providing a sealing function and reinforcing layers intended to take up the mechanical forces and which are formed by windings of metal wires or strips or various tapes or sections made of composites.
The flexible riser of the invention may be an unbonded flexible riser or a bonded flexible riser.
By the term “bonded flexible riser”, it is hereby intended to denote a flexible riser wherein two or more concentric layers are adhered to each other.
By the term “unbonded flexible riser”, it is hereby intended to denote a flexible riser comprising two or more superposed concentric layers, wherein these layers have a certain freedom to move relative to one another.
Should the pipe of the invention be a flexible riser, it is preferably a bonded flexible riser.
According to a first variant of this first embodiment of the invention, the flexible riser is a rough-bore flexible riser.
By the term “rough-bore flexible riser”, it is intended to denote a flexible riser wherein the innermost element is an internal carcass which forms a rough bore owing to gaps between the turns of the carcass that allow it to flex.
The rough-bore flexible riser of this first variant of this embodiment of the invention typically comprises, from the interior towards the exterior:
The internal polymeric sheath is typically coated over the internal carcass of the rough-bore flexible riser so that a continuous tubular layer at least comprising, preferably consisting essentially of (or being made of), a polymer (F) as defined above is obtained.
The internal polymeric sheath is preferably extruded over the internal carcass of the rough-bore flexible riser by conventional melt-processing techniques.
According to a second variant of this first embodiment of the invention, the flexible riser is a smooth-bore flexible riser.
By the term “smooth-bore flexible riser”, it is hereby intended to denote a flexible riser which is free from an internal carcass, wherein the innermost element is a smooth-walled impermeable polymeric tube.
According to a second embodiment of the invention, the pipe of the invention is a pipe liner suitable for use in a process for lining a metal pipeline.
The present invention thus also pertains to a process for lining a metal pipeline, said process comprising the following steps:
The metal pipeline is usually an iron or steel pipeline, preferably a steel pipeline, more preferably a carbon, alloy or stainless steel pipeline.
According to a variant of this second embodiment of the invention, the metal pipeline may be an existing damaged metal pipeline. Should the metal pipeline be an existing damaged metal pipeline, the lining process of the invention is a lining rehabilitation process.
The Applicant has found that the pipe of the present invention is advantageously endowed with outstanding resistance to plastic deformation to be suitably used as pipe liner in a process for the lining of a metal pipeline wherein the expansion of the deformed pipe liner may be successfully obtained by recovery of its elastic deformation.
The process for lining a metal pipeline preferably comprises the following steps:
wherein said pipe comprises at least one layer made of a tetrafluoroethylene (TFE) copolymer [polymer (F)] consisting essentially of:
CF2═CF—O—Rf (I)
wherein Rf is a linear or branched C3-C5 perfluorinated alkyl group or a linear or branched C3-C12 perfluorinated oxyalkyl group comprising one or more ether oxygen atoms, and
said TFE copolymer having a melt flow index comprised between 0.5 and 6.0 g/10 min, as measured according to ASTM D1238 at 372° C. under a load of 5 Kg.
The pipe of the process for lining a metal pipeline is defined as above.
Pipes suitable for use in this process for lining a metal pipeline may be monolayer pipes or multilayer pipes as defined above.
For the purpose of the present invention, an elastic deformation is distinguished from a plastic deformation. By the term “elastic deformation” it is hereby intended to denote temporary and reversible deformation of the polymer (F).
Should the stress applied to the polymer (F) under step (ii) of the process for lining a metal pipeline be lower than the yield strength of said polymer (F), the deformed pipe can be advantageously expanded under step (iii) of said process by recovery of its elastic deformation.
In step (ii) of the process for lining a metal pipeline, the pipe is preferably deformed by reducing its cross-sectional area by means of radial or axial compression.
According to one type of technique, the so-called Roll Down process, the cross-sectional area of the pipe is reduced by means of radial compression typically using sets of compression rollers.
According to another type of technique, the cross-sectional area of the pipe is reduced by means of axial compression typically pulling the pipe liner through a diameter reducing die. The diameter reduction is only achieved so long as the axial tension on the pipe is maintained. The compressive strains involved are typically of about 10% to 15%. Non-limitative examples of this type of process are the techniques known as Swagelining, Die-drawing and Titeliner.
In step (iii) of the process for lining a metal pipeline, the deformed pipe is expanded to fit with the inner diameter of the pipeline typically by elastic recovery. The deformed pipe may be also expanded by heat and/or pressurisation with oils and gases.
It is also an object of the present invention a pipeline system comprising at least two coaxial pipes:
The pipeline system preferably comprises two coaxial pipes, wherein the outer diameter of the inner pipe fits with the inner diameter of the metal pipeline.
The pipe of the pipeline system is defined as above.
The metal pipeline is usually an iron or steel pipe, preferably a steel pipe, more preferably a carbon, alloy or stainless steel pipeline.
Another object of the present invention is use of the pipe of the invention in heat exchangers.
Also, another object of the present invention is use of the pipe of the invention in downhole operations.
Further, another object of the present invention is use of the pipe of the invention in drilling operations.
The rough-bore flexible riser of the present invention is particularly suitable for use in downhole operations such as drilling operations where the internal carcass prevents the pipe from failing under the effect of pressure impacts.
The Applicant has surprisingly found that the pipe of the present invention is successfully endowed with higher yield stress values and lower creep strain values o that it can be advantageously used in a wide variety of applications where the pipe has to withstand high pressure and high temperature conditions, while being chemical resistant in harsh environments.
Should the disclosure of any patents, patent applications, and publications which are incorporated herein by reference conflict with the description of the present application to the extent that it may render a term unclear, the present description shall take precedence.
The invention will be now described with reference to the following examples whose purpose is merely illustrative and not limitative of the present invention.
Measurement of the Melt Flow Index (MFI)
The determination of the MFI was carried out according to the ASTM D1238 standard lest method at 372° C. under a load of 5 Kg.
Measurement of the Second Melting Temperature (T(II) Melting Point)
The second melting temperature was determined according to the ASTM D4591 standard lest method. The melting point observed at the second heating period was recorded and is hereby referred to as the melting point of the polymer.
Measurement of the Percentage by Weight of the Perfluorinated Alkyl Vinyl Ether (I) in the Polymer
The determination of the perfluorinated alkyl vinyl ether monomer (I) was carried out by FT-IR analysis and expressed as per cent by weight.
The perfluorinated alkyl vinyl ether monomer (I) content was determined under the followin-g conditions: the band optical density (OD) at 994 cm−1 was nor-malized with the band optical density (OD) at 2365 cm−1 by means of the following formula:
Monomer (I) [% by weight]=(OD at 994 cm−1)/(OD at 2365 cm−1)×0.99
Measurement of the Tensile Properties
Tensile tests on polymers (F) according to Examples 1 to 3 of the invention and comparative Examples 1 and 2 were performed by an Instron 4203 machine using microtensile specimens as reported in ASTM D3307 standard test method; specimens were cut by hollow punch from compression molded sheets having a thickness of 1.5 mm and were stretched at a speed equal to 50 mm/min after 15 minutes of conditioning time at the required temperature.
Yield stress was evaluated as nominal stress at first zero slope point on the stress-strain curve.
Tensile tests on pipes made of polymers (F) according to Example 4 or 5 of the invention were performed according to ASTM D638 standard procedure using specimens of type IV having a thickness of 7 mm at a grip distance of 65 mm and a gauge length of 12.5 mm. Modulus values have been measured at a cross-head speed of 1 mm/min, whereas strain at break and stress at yield values have been measured at a cross-head speed of 50 mm/min.
Yield stress was evaluated as nominal stress at first zero slope point on the stress-strain curve. Rupture is the point where a sharp load drop occurs and specimens break.
The higher is the yield stress value, the higher is the resistance to plastic deformation of the polymer.
Tensile creep tests on polymers (F) according to Examples 1 to 3 of the invention and comparative Examples 1 and 2 were performed according to ASTM D2990 standard test method but using specimen dimensions described in ISO 527-1A; no extensometers were used, but specimen shape correction was employed in order to get good strain evaluation. Specimens were cut by hollow punch from compression molded sheets having a thickness of 1.5 mm.
Tensile creep tests on polymers (F) according to Example 4 or 5 were performed according to ASTM D2990 standard test method but using specimen dimensions described in ISO 527-1A; no extensometers were used, but specimen shape correction was employed in order to get good strain evaluation. Specimens were cut by hollow punch from pipes having a thickness of 7 mm.
The lower is the creep strain value, the higher is the resistance to plastic deformation of the polymer.
Processing of Pipes
The polymer was extruded in a 45 mm extruder equipped with a head to produce pipes having an external diameter of 12 mm and an internal diameter of 10 mm. The temperature profile on the machine was set between 280° C. and 380° C. The cone at the exit of the head appeared transparent and the surface of the pipe so obtained was smooth without any defect.
Measurement of the Shrinkage
The pipes were cut in a longitudinal direction to a length of 400 mm. After thermal treatment at 300° C. for one hour, their length was re-measured at 23° C. thus obtaining the percent variation.
Measurement of Rapid Gas Decompression
Rapid gas decompression (RGD) tests on specimens cut from pipes made of polymers (F) according to Example 5 of the invention were performed according to ISO 13628-2 standard procedure (API 17J). The samples were preconditioned for 30 days in NORSOK® M710 oil at 185° C. under vapour pressure and this was followed by 20 rapid gas decompression cycles at 185° C. and 1000 bar using a mixture of 15% by moles of carbon dioxide in methane. The decompression rate was 70 bar per minute.
In an AISI 316 steel vertical 22 litres autoclave, equipped with a stirrer working at 400 rpm, after the vacuum was made, were introduced in sequence:
The autoclave was then heated up to reaction temperature of 60° C. and, when this temperature was reached, 0.60 bar of ethane were introduced.
By a compressor a gaseous mixture of TFE/PPVE in nomi-nal molar ratio of 99.210.8 was added until reaching a pressure of 21 bar.
The composition of the gaseous mixture present at the autoclave head (as determined by GC analysis) was formed of the following compounds in the indicated molar percentages: 95.9% TFE, 2.0% PPVE, 2.1% ethane.
Then, by a metering pump, 100 ml of a 0.035 M ammonium persulphate solution were fed.
The polymerization pressure was maintained constant by feeding the above mentioned monomeric mixture; when 8.8 g of the mixture were fed, the monomer feeding was interrupted. The reactor was cooled to room temperature, the latex was dischar-ged and coagulated with HNO3 (65% by weight) and the polymer was washed with H2O and dried at about 220° C.
Determination of the obtained polymer:
Composition (IR analysis): PPVE: 1.8% by weight
MFI: 5.0 g/10 min
Second melting temperature (T(Il) melting point): 314° C.
The same procedure as detailed under Example 1 was followed but:
The composition of the gaseous mixture present at the autoclave head (as determined by GC analysis) was formed of the following compounds in the indicated molar percentages: 96.90% TEE, 1.55% PPVE, 1.55% ethane.
Determinations on the obtained polymer:
Composition (IR analysis): PPVE: 1.4% by weight
MFI: 3.0 g/10 min
Second melting temperature (T(II) melting point): 317° C.
The same procedure as detained under Example 1 was o owed but:
The composition of the gaseous mixture present at the autoclave head (as determined by GC analysis) was formed of the following compounds in the indicated molar percentages: 96.2% TFE, 1.7% PPVE, 2.1% ethane.
Determinations on the obtained polymer:
Composition (IR analysis): PPVE: 1.5% by weight
MFI: 2.0 g/10 min
Second melting temperature (T(II) melting point): 316° C.
As shown in Table 1 here below, reporting the results of yield strength tests at 280° C., the polymers (F) according to the invention advantageously exhibited improved yield stress values at temperatures up to 280° C. as compared with commercially available products of comparative Examples 1 and 2.
As shown in Table 2 here below, reporting the results of the creep strain tests, the polymers (F) according to the invention advantageously exhibited lower creep strain values as compared with commercially available product of comparative Example 2.
As shown in Table 3 here below, pipes were obtained using the polymer (F) according to the present invention which advantageously were endowed with shrinkage values at 300° C. comparable to those of commercially available product of comparative Example 1.
It has been thus found that the pipe of the present invention comprising at least one layer at least comprising, preferably consisting essentially of (or being made of), the polymer (F) advantageously exhibits enhanced yield strength values, both in short-term and long-term trials, in particular at high operating temperatures, so that it can successfully withstand high internal pressure levels because of its improved mechanical properties.
The same procedure as detained under Example 1 was followed but:
The composition of the gaseous mixture present at the autoclave head (as determined by GC analysis) was formed of the following compounds in the indicated molar percentages: 93.0% TFE, 6.2% PPVE, 0.7% ethane.
Determinations on the obtained polymer:
Composition (IR analysis): PPVE: 2.2% by weight
MFI: 3.3 g/10 min
Second melting temperature (T(II) melting point): 311.4° C.
The same procedure as detained under Example 1 was followed but:
The composition of the gaseous mixture present at the autoclave head (as determined by GC analysis) was formed of the following compounds in the indicated molar percentages: 93.5% TFE, 6.0% PPVE, 0.5% ethane.
Determinations on the obtained polymer:
Composition (IR analysis): PPVE: 2.2% by weight
MFI: 1.7 g/10 min
Second melting temperature (T(II) melting point): 311.6° C.
As shown in Table 4 here below, reporting the results of tensile tests at 23° C., pipes made of the polymers (F) according to the invention as notably represented by Example 4 or 5 of the invention advantageously exhibited a combination of mechanical properties such that said pipes can be suitably used in a process for lining a metal pipeline.
As shown in Table 5 here below, reporting the results of the creep strain tests, pipes made of the polymer (F) according to the invention as notably represented by Example 4 of the invention advantageously exhibited relatively low creep strain values without undergoing yielding failure under relatively high stress of 3.0 MPa and 4.0 MPa to be suitably used in a process for lining a metal pipeline.
As shown in Table 6 here below, reporting the results of the rapid gas decompression (RGD) tests, pipes made of the polymer (F) according to the invention as notably represented by Example 5 advantageously exhibited no visible cracks to be suitably used in a process for lining a metal pipeline in downhole applications without undergoing decompression under the effect of pressure impacts.
The pipe of the present invention is thus particularly suitable for use in operations where high thermal resistance at high operating temperatures is required.
Number | Date | Country | Kind |
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12161236.0 | Mar 2012 | EP | regional |
Number | Date | Country | |
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Parent | 14388229 | Sep 2014 | US |
Child | 16241586 | US |
Number | Date | Country | |
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Parent | 16241586 | Jan 2019 | US |
Child | 16939825 | US |