Finite Element Analysis of Composite Repairs With Full-Scale Validation Testing

Sheets, Colton; Rettew, Robert E.; Alexander, Chris; Iyer, Ashwin

doi:10.1115/ipc2016-64214

Volume 1: Pipelines and Facilities Integrity 2016

DOI: 10.1115/ipc2016-64214

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Finite Element Analysis of Composite Repairs With Full-Scale Validation Testing

Colton Sheets

Robert E. Rettew

Chris Alexander

et al.

Abstract: Composite repair systems for pipelines are continuing to be used for increasingly difficult and complex applications which can have a high consequence of failure. In these instances, full-scale testing is typically pursued at a high-cost to the manufacturer or operator. Finite element analysis (FEA) modeling is a valuable tool that becomes especially attractive as a method to reduce the number of full-scale tests required. This is particularly true when considering the costs associated with recreating complex … Show more

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Experimental Study of Elevated Temperature Composite Repair Materials to Guide Integrity Decisions

Sheets

Rettew

Alexander

et al. 2016

Volume 3: Operations, Monitoring and Maintenance; Materials and Joining

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Over the past two decades, a significant amount of research has been conducted on the use of composite materials for the repair and reinforcement of pipelines. This has led to vast improvements in the quality of composite systems used for pipeline repair and has increased the range of applications for which they are viable solutions (including corrosion and mechanical damage). By using composite repair systems, pipeline operators are often able to restore the structural integrity of damaged pipelines to levels equal to or even in excess of the original undamaged pipe. Although this research has led to substantial advancements in the quality of these repair systems, there are still specific applications where questions remain regarding the strength, durability, and effectiveness of composite repair systems, especially in elevated temperature, harsh environment conditions. This program initially involved composite repair systems from six manufacturers. The test group included both carbon and E-glass based systems. Performance based qualifications were used to reduce the size of the test group from the initial six systems down to three. The experimental study consisted of small-scale testing efforts that ranged from tensile tests performed over a range of temperatures to 10,000-hour material coupon tests at elevated temperatures. The elevated temperatures used for testing were intentionally selected by the operator to reflect the 248 °F design temperature of the target pipeline. Using small-scale qualification testing outlined in ASME PCC-2 – Repair of Pressure Equipment and Piping standard (Article 4.1, Nonmetallic Composite Repair Systems: High-Risk Applications) as a foundation, the test program described in this paper was able to demonstrate that, when properly designed, and installed, some composite materials are able to maintain their effectiveness at high temperatures. This study combined short-term and long-term testing of composite systems and demonstrated the advantages of a 10,000 hour test when aging properties are unknown. Finally, the study showed that, although high-temperature reinforcement using composite repair systems is feasible and commercially available, this capability is not standard practice across the composite repair industry. Proper analysis and verification using experimental methods, including full scale testing should be conducted prior to installation of a composite repair system in these types of harsh conditions.

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Experimental Study of Elevated Temperature Composite Repair Materials to Guide Integrity Decisions

Sheets

Rettew

Alexander

et al. 2016

Volume 3: Operations, Monitoring and Maintenance; Materials and Joining

Self Cite

View full text Add to dashboard Cite

show abstract

Full-Scale Elevated Temperature Testing of Composite Repairs in Bending and Compression

Sheets

Rettew

Alexander

et al. 2016

Volume 1: Pipelines and Facilities Integrity

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The increasing use of composite repair systems in critical and complex applications has brought greater scrutiny to their design and performance. This has been especially true in high-temperature, immersed environment applications where ambient temperature test results with industry standard de-rating factors are all that is available for design. Since this approach does not always adequately capture environmental effects or the performance of composite systems at elevated temperatures, it is beneficial to perform full-scale testing which accurately replicates the in-situ application. In order to accomplish this, a full-scale testing program was developed that subjected multiple composite repair systems to internal and external loads at temperatures up to 120 °C with and without water immersion. This program involved the reinforcement of 12.75-inch × 0.375-inch pipe samples that had simulated corrosion defects. Full-scale load and pressure testing was conducted to simulate the long-term performance of the composite repair systems in the environmental conditions of the application. A strain based performance threshold of 0.4% strain at 120 °C and 100% SMYS was used to develop a competitive program that ranked the participating systems and reduced the number of acceptable repairs from six down to three. This approach increased the efficiency of the full-scale testing and allowed for more in-depth analysis of the top-performing systems. The results of the full-scale testing of six composite repair systems at elevated temperature allowed for a quantitative measure of their effectiveness under in-situ conditions. Several of the systems were shown to provide inadequate reinforcement under these conditions; however, it was also observed that appropriately designed and installed systems are capable of meeting the intense demands of elevated temperature, harsh-service conditions.

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Finite Element Analysis of Composite Repairs With Full-Scale Validation Testing

Cited by 2 publications

References 2 publications

Experimental Study of Elevated Temperature Composite Repair Materials to Guide Integrity Decisions

Experimental Study of Elevated Temperature Composite Repair Materials to Guide Integrity Decisions

Full-Scale Elevated Temperature Testing of Composite Repairs in Bending and Compression

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