First Successful Deployment of Nonmetallic Casing Strings: A Case History
Abstract: For the first time, two different sizes of nonmetallic casing strings were installed in water wells to cover shallow potable aquifers. This paper describes the reasons for deployment, planning and design, logistics, operational challenges, lessons learned, and the way forward for this newly deployed technology. In the initial stages of the project, fiberglass-reinforced thermoset resin (RTR) pipes manufactured locally were evaluated in terms of ratings, dimension, and method of connection and fe… Show more
Search citation statements
Paper Sections
Citation Types
Year Published
Publication Types
Relationship
Authors
Journals
Cited by 5 publications
References 0 publications
Non-metallic tubing manufactured from fiberglass have been around for decades, and for good reason with multiple physical advantages over carbon steel tubing. However, this has also came with certain physical constraints such as the type of tubing connections and material brittleness with resultant low-pressure ratings. This has restricted a more widespread use of the material, particularly for downhole applications. In recent years, extensive research and development has evolved to manufacture 100% non-metallic composite tubulars with increased mechanical strength combined with high performance machined threads. The development of non-metallic composite tubulars have been in progress for many years, obstacles to the manufacturing process to deliver a material that was suitable for downhole conditions were numerous. The fully non-metallic fiberglass tubular is manufactured with aromatic amine cured epoxy resin, which not only provides the required strength but also an effective resistance to the harsh downhole conditions. Deep water supply wells that provide water injection are ideal candidates for this technology. The material is corrosion resistant, lightweight, zero maintenance, extremely durable with a superior hydraulic performance over carbon steel. The challenges of using carbon steel tubulars in harsh water environments are well known, and can lead to premature failure of the completion. Such failure can result in flow circulation across the electrical submersible pump (ESP) eventually leading to pump failure due to excessive heat in the motor. Fiberglass lined carbon steel protects the inner part of the tubing but still leaves the external side exposed to the harsh environment. The next step in the evolution for tubulars exposed to harsh conditions is 100% non-metallic manufactured tubulars. A custom designed resin system and manufacturing process with precise winding angle patterns delivered this high strength and chemically stable product. These properties allow for a maximum running depth of 12,000 ft, a maximum working pressure of 2500 psi and an expected life expectancy in the 10's of years. The tubing joints have API specification composite machined threads and are made up similar to traditional carbon steel tubing but requiring less torque. The successful deployment of 100% non-metallic composite tubulars in ESP powered water supply wells is another step towards increased utilization of this technology. A review has been completed of the manufacturing process, flow assurance, design integrity improvements and economic analysis of the 100% non-metallic fiberglass tubular. This completion design ensures well integrity & prolongs the lifetime of the assets and is in-line with the adoption of circular economy practices, simultaneously providing cost effective solutions and ensuring continuous improvement.
Non-metallic tubing manufactured from fiberglass have been around for decades, and for good reason with multiple physical advantages over carbon steel tubing. However, this has also came with certain physical constraints such as the type of tubing connections and material brittleness with resultant low-pressure ratings. This has restricted a more widespread use of the material, particularly for downhole applications. In recent years, extensive research and development has evolved to manufacture 100% non-metallic composite tubulars with increased mechanical strength combined with high performance machined threads. The development of non-metallic composite tubulars have been in progress for many years, obstacles to the manufacturing process to deliver a material that was suitable for downhole conditions were numerous. The fully non-metallic fiberglass tubular is manufactured with aromatic amine cured epoxy resin, which not only provides the required strength but also an effective resistance to the harsh downhole conditions. Deep water supply wells that provide water injection are ideal candidates for this technology. The material is corrosion resistant, lightweight, zero maintenance, extremely durable with a superior hydraulic performance over carbon steel. The challenges of using carbon steel tubulars in harsh water environments are well known, and can lead to premature failure of the completion. Such failure can result in flow circulation across the electrical submersible pump (ESP) eventually leading to pump failure due to excessive heat in the motor. Fiberglass lined carbon steel protects the inner part of the tubing but still leaves the external side exposed to the harsh environment. The next step in the evolution for tubulars exposed to harsh conditions is 100% non-metallic manufactured tubulars. A custom designed resin system and manufacturing process with precise winding angle patterns delivered this high strength and chemically stable product. These properties allow for a maximum running depth of 12,000 ft, a maximum working pressure of 2500 psi and an expected life expectancy in the 10's of years. The tubing joints have API specification composite machined threads and are made up similar to traditional carbon steel tubing but requiring less torque. The successful deployment of 100% non-metallic composite tubulars in ESP powered water supply wells is another step towards increased utilization of this technology. A review has been completed of the manufacturing process, flow assurance, design integrity improvements and economic analysis of the 100% non-metallic fiberglass tubular. This completion design ensures well integrity & prolongs the lifetime of the assets and is in-line with the adoption of circular economy practices, simultaneously providing cost effective solutions and ensuring continuous improvement.
Challenges in High Sour Gas Field Development and Non-Metallics Opportunities in Upstream Processes
High sour fields beyond 10% H2S concentration are considered one of the severe environments that require suitable tubular components and accessories in upstream environment to ensure sustainable production. Such environments represent a challenging operating envelop where durability and safety are the top concerns due to higher H2S concentration at a higher partial pressure and higher temperature (HPHT). The risk is amplified for the wells with higher than 10% H2S concentration, namely the High H2S wells, and those exceeding 25% H2S concentration which are typically labeled as Ultra-High H2S wells. Corrosion in gas operations can be aggravated in downhole where high H2S at higher temperatures pose additional challenges. Selection of proper material to ensure a sustainable well condition is one of the important elements for the development of these HPHT gas wells. Various challenges were identified, including the selection of cost-effective material which is capable of withstanding short and long term H2S and CO2 partial pressures as well as control generalized CO2 corrosion, sulfide stress cracking (SSC), and stress-oriented hydrogen induced cracking (SOHIC). With the advancement of Non-Metallics (NM) materials in several applications across the O&G sector, it holds a promise to provide an alternative material solution in lieu of CRA alloy material for the HPHT downhole applications. NM materials are lightweight and they can be designed to withstand higher strength capability in addition to their outstanding corrosion resistance properties in a high H2S environment. Moreover, they can be engineered to fulfill the intended application due to their high design flexibility and durability. In the downhole applications, there is a number of NM products that have been implemented in sour environments, including sealants as well as downhole accessories and tools, where the list of NM technologies is considerably growing. This paper highlights the concept of using NM products such as coiled tubulars, pressure control equipment and elastomers as well as the challenges on the development and deployment of these key components in high sour fields.
First Fully Bonded Carbon Fiber Reinforced Spoolable Composite Tubular for Downhole Oil and Gas Applications
In the oil & gas (O&G) industry, non-metallic (NM) composite pipes are gaining traction to mitigate corrosion-related issues that might arise from using carbon steel pipes in severe environment with presence of highly salinity water, carbon dioxide, and hydrogen sulfide. The substitution of the carbon steel pipes to NM composite pipes reduces the number of workover and intervention needed for carbon steel pipes due to corrosion, which indirectly reduces the carbon footprint over the well lifetime. This paper outlines the steps involved in the development, deployment, and operation of the first fully bonded carbon fiber spoolable composite downhole tubular, which reduces the majority of carbon emissions over the tubular lifetime. This paper highlights key activities, variables and support systems involved in NM composite tubular development and qualification for O&G downhole application. New product development follows general workflow that includes comprehensive understanding on application requirements, environment, load, and challenges. This step is followed by evaluation of feasible pipe designs, construction and material selection, feasibility study on suitable manufacturing process and finally multi-level qualification programs to confirm product specification. Performance envelope derived from qualification tests is utilized to benchmark pipe specification against load scenarios covering the entire pipe lifecycle. Similar approach is also utilized to develop supporting items such as connection and interfaces to other well components. O&G downhole deployment is typically high-risk operations hence, supporting exercises are required to ensure equipment compatibility and operation safety to meet user’s standard practice requirements. The installation, deployment, and operating environments for various O&G applications- from surface to offshore to downhole fields vary, particularly for load cases in terms of temperature, pressure, and mechanical strength. This results in different material requirement and compatibility in the use environment. As NM composite tubulars are made with different layers and materials typically NM fibers, polymers, and others, material compatibility between layers is crucial during pipe manufacturing. Testing requirements differ too since they have different load cases in different applications, as well as the type of pipe design and construction also demands different qualification needs. This prompts the move to develop a new guideline for qualifying NM composite tubulars in downhole application as existing standards for composite tubulars in other O&G operations are not exactly applicable to downhole conditions, nevertheless, there are interrelated testing concepts between the new guideline and existing standards. NM tubular development process reflects the missing gaps during pipe research and development and eventually allows one to systematically follow the process to develop the first fully bonded carbon fiber composite tubular for downhole application. Utilizing NM downhole tubulars comprises high complexity, compared to pipes used in other applications. This is the first fully bonded carbon fiber reinforced spoolable composite tubular developed for downhole O&G applications, leveraging newly established holistic protocols. While pipe development poses only about one third of the challenges, the remaining two thirds are associated with the connections and the necessary system components for the different lifecycle phases, making NM downhole tubulars a reality.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2025 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
