Oil and Gas

ARE COMPOSITES A VIABLE ALTERNATIVE TO STEEL IN OIL AND GASThe oil and gas industry has traditionally used steel throughout the hydrocarbon value-chain, from the construction of wells and rig systems to onshore pipelines, storage tanks and refineries. However, composites are gaining traction thanks to the numerous advantages they offer over conventional building materials like steel and aluminum. Using composites leads to a reduction in the overall weight of the structure, offers better corrosion resistance properties, reduces the overall operational cost and offers greater design flexibility.The Current ScenarioComposites are currently used in the oil and gas industry to manufacture risers, drill pipes and tubing, pressure vessels, tanks and pipe systems for fluid transport. They are also used in secondary applications such as in the grids and gratings, handrails, cable trays, ladders, decking and flooring of offshore platforms. Composites are in demand for operations at greater depths as a replacement for metal in subsea piping, such as the growing adoption of thermoplastic composites (TCP) in deep-sea oil and gas applications. In 2009, Airborne Oil and Gas, a manufacturer of TCP, became the first company to develop and deploy an offshore TCP downline. One major factor that aided the adoption of TCP was that it is cheaper and easier to transport, prepare and install than steel.Composites are being adopted widely across the oil and gas industry. Airborne Oil and Gas’ carbon fiber reinforced PVDF has shown to generate 30% greater savings on as-installed cost compared to steel, while Saudi Aramco has deployed composite materials across significant portions of its oil and natural gas flowline network. In addition, Technip FMC and Magma Global have entered a partnership to develop a new carbon fiber composite hybrid flexible pipe (HFP) for use in offshore applications while Solvay’s partnership with Baker Hughes aims to implement TCP in offshore flexible pipes and risers.Addressing ChallengesDespite all the benefits that composites offer, the oil and gas industry has shown reluctance in adopting composite solutions. This is often attributed to widespread conservatism among the old guard in the industry, who believe that steel is “good enough” to meet their needs. Another major challenge that composites face is the absence of a global design and qualification standard. Current qualifications for a new composite pipeline product stipulate a minimum required testing time of more than a year and a half. To enable the future widespread adoption of composites, Saudi Aramco signed a charter with TWI Ltd. and the National Structural Integrity Research Center to create the Non-Metallic Innovation Center (NIC) in September 2019. The center will develop field application technologies that are non-metallic and ready to deploy. The aim is to increase the adoption of composites by improving existing qualifications and developing new service standards, inspection and monitoring technologies.ConclusionThere is an enormous opportunity for the adoption of composites in pipe systems, risers, umbilical and frac plugs, and balls used during hydraulic fracturing. Composites would also be quite useful in repairing offshore defects and are a helpful alternative to traditional maintenance practices because they can often be performed without having to shut down the operations.Compared to industries such as aerospace, automotive and construction, where composites have been widely used for decades, the adoption rate of composites in the oil and gas sector has been slow. There is a lack of relevant performance information to contend with, particularly in hostile offshore environments, which are a major hinderance to the growth of composites. However, the benefits offered by composite materials outweigh the perceived risks inherent in using new material technologies. 

Pipe Coating, Lining and Cladding What is the difference between external pipe coating and internal pipe-lining and cladding? External pipe coatings are used to protect the metal from corrosive environments (3LPE coated pipes are the most common choice). Internal lining (example PTFE) protects the pipe from corrosive fluids. Clad pipes (CRA) have the inner surface covered by higher grade materials to achieve stronger resistance while decreasing the overall pipe cost. COATED PIPESPipes may be coated externally to be protected from corrosion, erosion and possible mechanical stress. Pipe coating consists of the application of metallic, or non-metallic, materials on the external surface of the pipe (either seamless or welded). The most common materials to coat pipes externally are:1. Non-metallic pipe coating: Paints, varnishes, lacquers, bituminous coatings, resins, plasticizers, Greases, waxes, oils, Plastics (polyurethane, polyethylene, Rilsan, PTFE, PVC), Elastomers (various types), Vitreous enamel, Cement mortar2. Organometallic pipe coating: Paints pigmented with metals in powder form (aluminum, zinc, lead, stainless steel), Paints containing zinc ethyl-silicate3. Chemical modification: Phosphating, Chromatin, phosphating, Black finishing, and browning4. Cementation (physiochemical modification) 3LPE COATED PIPES3LPE coated pipes feature a three-layer polyethylene coating consisting of:1. a high-performance fusion bonded epoxy (FBE),2. a copolymer adhesive3. an outer layer of polyethylene which provides tough, durable protection against corrosion and erosion.3LPE pipe suit medium to high operating temperatures. LINED PIPESLined pipes are fitted with an internal protective material which is mechanically inserted into the tubular section. The lining material is fitted into the pipe at the end of the manufacturing process. It is clear that internal lining materials, which have an own thickness, reduce the bore size of the pipe.The most pipe lining materials are:Teflon (PTFE)Cement mortarLiquid epoxyGlassFusion bonded epoxy (FBE)PolyethyleneBituminous asphaltZinc CLAD PIPES (CRA)A clad pipe combines the strength and toughness of a carbon steel pipe with the corrosion resistance of a stainless or duplex pipe (or even higher grades, as nickel high-alloyed materials like Inconel, Incoloy, etc). Clad pipes are also called CRA (which stands for “corrosion resistant alloy”). The cladding process consists of the application, in the inner part of the pipe, of a layer of higher grade material onto a lower-grade base material of the pipe. Clad pipes are used for fluids that would quickly corrode carbon-manganese steels. The bonding between the two materials is metallurgical and can be achieved by welding the two together or with explosion techniques (whereas lined pipes feature a mechanical bonding of different materials).Pipe cladding is used to enhance the durability and the resistance to corrosion of a pipe while keeping its final costs at acceptable levels. Of course, clad pipes are more expensive than lined pipes, as the overlay materials used are, generally, noble metals.

The 7 Flow Meters Used in the Oil and Gas Industry Over the years, people who are involved in the oil and gas industry have been innovating and creating ways to get accurate measurements. From extracting to delivering these raw materials, everyone in the business has been deeply invested in getting the most accurate measurements possible.Thus, scientists and engineers have been working long and hard to discover new ways and technologies to make more efficient metering systems. Because of their hard work, the creation of different flow meters materialized, and because of that, the oil and gas industry is still going strong today.These flow meters are used by industries, particularly gas and oil, to calculate the mass flow rate or volumetric flow rate of fluids. Such an application defines the capacity and type of flow meter. Gases, liquids, and fluids are measured in terms of mass flow rate and volumetric flow rate. Where and How Do Oil and Natural Gas Form?Before we tell you the different flow meters that are commonly used in the oil and gas industry, knowing the process of how industries collect raw materials should come first.Both of these raw materials are present on different geological sources. Mostly, gas and oil fields are present on sedimentary rocks like sandstone and limestone. The main reason is that these materials can easily pass through rocks, making them easier to accumulate. The capacity of the reservoirs found can be determined by its porosity, while the productivity is proportional to their permeability.To start a flow, they drill inside these rocks, which will make the fluids easier to extract. To either start, increase, or for continual flow, water is pumped inside the rocks, which are commonly located underground. High-pressured water is pumped in these rocks, which will increase the flow rates and increased extraction of fluids. A type of flow meter, called ABB’s electromagnetic flow meter, is used to accurately and precisely measure the water being pumped inside the rocks.However, there are certain cases where drilling and pumping water is not enough to acquire these substances. Oil or natural gas found on impermeable rocks is mostly unable to form into conventional means. These materials are called ‘unconventional hydrocarbons’, and they include shale oil, coal-bed methane, and shale gas. Because of the rock’s very low permeability, the accumulation should be stimulated to start a flow and enable the extraction process. To do this, a method called ‘hydraulic fracturing’ is necessary.In hydraulic fracturing, a mixture of sand and water is pumped inside the rocks. Because of the high pressure, small fractures (fissures) are made, which will make the materials free to move inside the foundation. Hydraulic fracturing is done by enabling these fissures to be open for the materials to move, which is what the sand does; opening these fractures, which results in high permeability. To get the precise measurement of the fracturing fluid and the blending of additives in the mix, ABB’s electromagnetic flow meter is used.Now that we have explained the overview of how the oil and gas industry get these raw substances; the next step is getting to know how they measure it with different types of metering systems. Coriolis Flow MetersThe technology used in the Coriolis flowmeters is not precisely the newest in terms of measuring the natural substances in the oil and gas industry. The first industrial patent for the Coriolis flowmeter is dated back in the 1950s. However, the start of the application of the said technology in the field is not until 1970. And up until now, nothing has changed although the refinement of the meters for more accurate measurements.One of the original designs of the flow meter is that it features a single tube with thin walls. It is highly accurate; however, the practicality of the model is the primary concern because of its vibration issues. To address that, the design was changed into a two-tube design instead of one.Although having gone through different designs, the main principle of the Coriolis flowmeter has never changed. By creating inertia through oscillating tubes as the materials flow through them, the tubes twist. The number of twists is directly proportional to the mass flow rate. This is then measured flow meter transmitters and a sensor to make a linear flow signal.Using a Coriolis flowmeter has several advantages. One of these is that it is highly accurate. These flow meters are more commonly used to measure a wide range of petroleum products such as crude oil and natural gas. The main gist of the flow meter is that it measures mainly the mass flow rate instead of its volume. It makes it best for measuring petroleum products since the primary concern in measuring these products is the heat rather than the quantity.Typically, this type of flow meter applies to pipes with a diameter of 1 to 4 inches. But nowadays, larger models have been more available than before. Probably the only downside of Coriolis flowmeters is it is more expensive than other types of metering systems. This can be worth as it is more low maintenance than the other flow meters. Ultrasonic Flow MetersUltrasonic flow meters measure the velocity of the fluid running through a pipe by the use of sound waves. A linear shift in its frequency will be noticeable once the speed of the fluid slowly increases.Ultrasonic flowmeters can be used for both measuring the velocity of the liquid inside and outside the pipe; inline designs mount the flow meter inside the tube while clamp-on modelsmeasure the speed using transducers. However, clamp-ons are lower in accuracy than inline models. Thus, they are only used to spot checks to get the measurement immediately.Unlike the Coriolis flow meter, ultrasonic flow meters and other flow meters that are designed specifically for crude oils can be used inline for pipes that have a 20-inch measurement. Also, the clamp-on design is applicable in a lot of different things and is durable. Not to mention, it also has low maintenance requirements. Thermal Flow MetersIn its primary sense, thermal flow meters measure the speed of the heat that dissipates as it is injected directly into a gas flow stream. Mostly, thermal flow meters are used exclusively for measuring gases.Heat dissipation varies depending on the composition and the temperature of the gas. Thermal flow meters are the best choice when either of the composition or the temperature is minimized or if that level of accuracy as within acceptable parameters. Turbine Flow MetersThis type of meter uses a mechanical rotor that is attached to a shaft that is inside the pipe. It is then used to measure the volume of gas, fluid, or vapor that passes through the tube. As the substance passes through the pipe, the rotor spins with its speed depending on how fast the material passes through the pipeline. The rotational speed that results from the spinning of the rotor is determined by the use of sensors or other mechanical methods.Typically, magnetism is used to let the sensors get reading from the rotor, with the magnet located outside the pipe. With the use of signals, sensors and transmitters determine the volume of the material traveling inside the tube.Turbine flow meters are cheap in terms of pricing. Also, they give more accurate results when the substance measured is gas or any other material that has no debris at a slow flow rate.One disadvantage of using a turbine flow meter is that it does not work well with a varying flow as the mechanical parts can wear out significantly and will need immediate replacement. Also, turbine flow meters work best when measuring the mass of a gas with unknown properties.In addition to its uses, it is also commonly used for billing meters to measure the amount of gas or water in commercial, industrial, and residential buildings. However, in this aspect, it competes with positive displacement flow meters. The latter is more suitable with pipes with a measurement of 1.5 to 10 inches while turbine flow meters are best suited with pipes 10 inches or above in size. Differential Flow MetersLike its distant cousin, ultrasonic flow meter, it also measures the volume of the flow that passes through within the pipe. What sets it apart from other flow meters is its use of Bernoulli’s equation. Also, differential flow meters use constriction to slow down the flow and pressure of substance inside the pipe.As the flow pressure slowly increases, the pressure drop’s size also increases proportionately. The data from this event is transmitted on varying sets of pressure readings. With that information, it calculates the difference in pressure to get the measurement of the volumetric flow.Differential flow meters are typically low-cost. And different versions for different substances also exist to make accurate measurements of every fluid. Gases are special cases, though, because, to get the precise reading of a particular gas, differential flow meters should be combined with other sensors for different factors like temperature, pressure, the composition of the gas, and the gas’ density.Although it is an excellent flow meter on its own, industries prefer other types of metering systems. This is mostly due to its inaccuracy when other factors are involved, like temperature, pressure, etc. Also, to get the most accurate measurement of gas, it needs to combine with other sensors or get a different version of a differential flow meter altogether. Because of the mentioned factors, it can be hard to get an accurate reading. It is mainly the reason why the oil and gas industry prefers other types of metering, especially when dealing with gases. Positive Displacement Flow MetersThere are different types of positive displacement meters: oval gear, piston, rotary, diaphragm, nutating disc, and helical.Positive displacement meters can be applicable for a wide variety of things that involve commercial, industrial, and residential applications. They are most commonly used to measure gas flow. Turbine flow meters, however, competes with positive displacement flow meters in this aspect. One of its advantages over turbine flow meters is that it is excellent in dealing with a steady flow rate in a pipeline that has a diameter of 10 inches or less.Both diaphragm and rotary-based positive displacement flow meters are typically used for measuring gas flow. Against competitors like Coriolis flowmeters, the latter is the first choice mainly because positive displacement flow meters do not have the required industry approvals for application in the field. Vortex Flow MetersOne of the most versatile of flow meters, vortex flow meters, can easily measure gas, liquid, steam flows.Over the past years, vortex flowmeters lacked the necessary approvals for application in the industry. However, in 2007, the American Petroleum Institute had approved a draft standard for the use of the said flow meter. And since then, several companies in the industry have been actively working with API for further developments regarding this standard and its approval.The said standard is applied to liquid, steam, and gas flows and was extended in 2010 for further use. Despite having an uncertain future, designs were made explicitly for gas and liquid exists. Vortex flow meters have had a limited impact on the market in recent years, but a steady increase in its preference is present for future companies. However, its effect on the market regarding custody-transfer in natural gas is low because of other competitors like ultrasonic, differential pressure, and turbine flow meters. ConclusionsThere are a lot of technologies readily available for the oil and gas industry to use and adapt. Not to mention that the market has been introducing new types of flow meters waiting for the API’s approval. Due to the different fluids that a lot of industries collect, the need for low cost and maintenance metering systems is on the rise. This had led to creating bigger models of Coriolis flowmeters, making it one of the most used metering systems to date. 

Resolution, dynamic range, horizontal linearity, vertical linearity, sensitivity, signal to noise ratio.

(1) When the ultrasonic wave propagates in the medium, it has the characteristic of reflection at different quality interfaces. If the defect is encountered and the size of the defect is equal to or greater than the ultrasonic wavelength, the ultrasonic wave is reflected back on the defect, and the flaw detector can display the reflected wave. Come out; if the size of the defect is even smaller than the wavelength, the sound wave will bypass the ray and cannot reflect it;(2) The directionality of the wave sound is good. The higher the frequency, the better the directionality. The beam is radiated into the medium with a narrow beam, and the position of the defect is easily determined.(3) The propagation energy of the ultrasonic wave is large, such as the energy propagated by the super-wave with a frequency of 1 MHZ (100 Hz), which is equivalent to 1 million times the sound wave with the same amplitude and a frequency of 1000 Hz (Hertz).

According to a survey conducted by the National Aeronautics and Space Administration, many non-destructive testing methods are considered to be divided into six categories and about 70 kinds. However, the following are common in practical applications:Conventional non-destructive testing methods are:　　－ Ultrasonic Testing（ UT）；　　－Radiographic Testing（RT）；　　－Magnetic particle Testing（MT）；　　－Penetrant Testing ( PT）；　　－Eddy current Testing（ET）；Unconventional non-destructive testing techniques are:－Acoustic Emission(AE)；　　－Leak Testing（UT）；　　－Optical Holography；　　－Infrared Thermography；　　－Microwave Testing

(1) Non-destructive testing is a test method for inspecting the surface and internal quality of the parts to be inspected without damaging the working state of the workpiece or raw materials.(2) NondestructiveTesting: abbreviated NDT

(1) Non-destructive testing is a test method for inspecting the surface and internal quality of the parts to be inspected without damaging the working state of the workpiece or raw materials.(2) NondestructiveTesting: abbreviated NDT

API: It is the abbreviation of English American Petroleum Institute, Chinese means American Petroleum Institute.OCTG: It is the abbreviation of English Oil Country Tubular Goods. Chinese means oil special tubing, including product oil casing, drill pipe, drill collar, coupling, short circuit and so on.Tubing: A tubing used in oil wells for oil recovery, gas production, water injection, and acid fracturing.Casing: A pipe that has been drilled into the lining wall from the surface of the ground to prevent the wall from collapsing. Drill pipe: A pipe used for drilling a hole.Line pipe: A pipe used to transport oil and gas.Coupling: A cylinder used to connect two threaded tubes with internal threads. Coupling: A tube used to make a coupling.API thread: Pipe thread specified in API 5B standard, including tubing round thread, casing short round thread, casing long round thread, sleeve tapered thread, line pipe thread, etc.Special buckle: Non-API threaded type with special sealing performance, joint performance and other properties.

Oil well tubing is a basic material for the petroleum industry. It is an indispensable special pipe for oil exploration and development. It is also a major strategic material for the oil industry. Its quality and performance are related to the comprehensive economic and security benefits of the oil industry.Oil well tubings are classified according to their uses; casings, oil pipes, drill pipes, etc.; they can be classified into seamless oil well tubings and welded oil well tubings according to the production process. Casing is mainly used to support the wellbore during and after drilling to ensure the drilling process and the normal operation of the well after the well. The tubing mainly transports the oil and gas at the bottom of the well to the ground; the main oil drilling pipe used to connect drill collars and drill bits and transfer drilling power.

3PE anti-corrosion steel pipe base metal includes seamless steel pipe, spiral steel pipe and straight seam steel pipe. The three-layer polyethylene (3PE) anti-corrosion coating has been widely used in the oil pipeline industry for its good corrosion resistance, water vapor permeability resistance and mechanical properties. 3PE anti-corrosion steel pipe anti-corrosion layer is of vital importance to the life of buried pipelines, the same material pipeline, and some buried in the ground for decades do not corrode, and some years leaked. It is because they use different external coatings.

Hydrogen induced cracking (HIC) English full name is: Hydrogen induced cracking. Hydrogen sulfide is one of the most corrosive and harmful media in oil and natural gas. In the process of natural gas transmission, the stress corrosion of hydrogen sulfide in the transmission pipeline accounts for a large proportion. When used in a wet hydrogen sulfide environment, hydrogen blistering (HB), hydrogen induced cracking (HIC), and stress induced hydrogen induced cracking (SOHIC) can occur within the carbon steel. In the acidic environment such as hydrogen sulfide contained in the pipe, cracks generated by corrosion-induced hydrogen intrusion into the steel become hydrogen induced cracking (HIC).