DARTS—Drone and Artificial Intelligence Reconsolidated Technological Solution for Increasing the Oil and Gas Pipeline Resilience

Premkumar Ravishankar; Seokyon Hwang; Jing Zhang; Ibrahim X. Khalilullah; Berna Eren-Tokgoz

doi:10.1007/s13753-022-00439-w

International Journal of Disaster Risk Science ›› 2022, Vol. 13 ›› Issue (5) : 810 -821. DOI: 10.1007/s13753-022-00439-w

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DARTS—Drone and Artificial Intelligence Reconsolidated Technological Solution for Increasing the Oil and Gas Pipeline Resilience

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Abstract

The need for safe operation and effective maintenance of pipelines grows as oil and gas demand rises. Thereby, it is increasingly imperative to monitor and inspect the pipeline system, detect causes contributing to developing pipeline damage, and perform preventive maintenance in a timely manner. Currently, pipeline inspection is performed at pre-determined intervals of several months, which is not sufficiently robust in terms of timeliness. This research proposes a drone and artificial intelligence reconsolidated technological solution (DARTS) by integrating drone technology and deep learning technique. This solution is aimed to detect the targeted potential root problems—pipes out of alignment and deterioration of pipe support system—that can cause critical pipeline failures and predict the progress of the detected problems by collecting and analyzing image data periodically. The test results show that DARTS can be effectively used to support decision making for preventive pipeline maintenance to increase pipeline system safety and resilience.

Keywords

Artificial intelligence / Asset management / Drone application / Midstream industry / Pipeline resilience / Predictive maintenance

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Premkumar Ravishankar, Seokyon Hwang, Jing Zhang, Ibrahim X. Khalilullah, Berna Eren-Tokgoz. DARTS—Drone and Artificial Intelligence Reconsolidated Technological Solution for Increasing the Oil and Gas Pipeline Resilience. International Journal of Disaster Risk Science, 2022, 13(5): 810-821 DOI:10.1007/s13753-022-00439-w

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References

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[1]

Alharam, A., E. Almansoori, W. Elmadeny, and H. Alnoiami. 2020. Real time AI-based pipeline inspection using drone for oil and gas industries in Bahrain. In Proceedings of the 2020 International Conference on Innovation and Intelligence for Informatics, Computing and Technologies, 20–21 December 2020, University of Bahrain, Bahrain.

[2]	Asadzadeh S, de Oliveira WJ, de Souza Filho CR. UAV-based remote sensing for the petroleum industry and environmental monitoring: State-of-the-art and perspectives. Journal of Petroleum Science and Engineering, 2022, 208: 109633

[3]	ASME (American Society of Mechanical Engineers). 2019. Pipeline transportation systems for liquids and slurries, standard B31.4. https://www.asme.org/codes-standards/find-codes-standards/b31-4-pipeline-transportation-systems-liquids-slurries. Accessed 2 Dec 2021.

[4]	ASME (American Society of Mechanical Engineers). 2020. Process piping, standard B31.3. https://www.asme.org/codes-standards/find-codes-standards/b31-3-process-piping. Accessed 2 Dec 2021.

[5]	ASME (American Society of Mechanical Engineers). 2021. Gas transmission and distribution piping systems, standard B31.8. https://www.asme.org/codes-standards/find-codes-standards/b31-8-gas-transmission-distribution-piping-systems. Accessed 2 Dec 2021.

[6]	Badrinarayanan V, Kendall A, Cipolla R. Segnet: A deep convolutional encoder-decoder architecture for image segmentation. IEEE Transactions on Pattern Analysis and Machine Intelligence, 2017, 39(12): 2481-2495

[7]	Chen, L.C., Y. Zhu, G. Papandreou, F. Schroff, and H. Adam. 2018. Encoder-decoder with atrous separable convolution for semantic image segmentation. In Proceedings of the 15th European Conference on Computer Vision, 8–14 September 2018, Munich, Germany, 801–818.

[8]	Chen Y, Sun Y, Yu W, Liu Y, Hu H. A novel lightweight bilateral segmentation network for detecting oil spills on the sea surface. Marine Pollution Bulletin, 2022, 175: 113343

[9]	Di Sarno L, Karagiannakis G. On the seismic fragility of pipe rack—Piping systems considering soil-structure interaction. Bulletin of Earthquake Engineering, 2020, 18(6): 2723-2757

[10]	EIA (The U.S. Energy Information Administration). 2021. U.S. natural gas total consumption (million cubic feet). https://www.eia.gov/dnav/ng/hist/n9140us2A.htm. Accessed 18 Nov 2021.

[11]	El-Abbasy MS, Senouci A, Zayed T, Mirahadi F, Parvizsedghy L. Artificial neural network models for predicting condition of offshore oil and gas pipelines. Automation in Construction, 2014, 45: 50-65

[12]	Everingham M, Van Gool L, Williams CK, Winn J, Zisserman A. The pascal visual object classes (voc) challenge. International Journal of Computer Vision, 2010, 88(2): 303-338

[13]	FAA (Federal Aviation Administration). 2020. Small unmanned aircraft systems (UAS) regulations (Part 107). https://www.faa.gov/newsroom/small-unmanned-aircraft-systems-uas-regulations-part-107. Accessed 18 Nov 2021.

[14]	Fazzini, P., J.L. Otegui, and H. Kunert. 2009. Predicting failure conditions of SMAW girth welded X70 pipelines subjected to soil movement. In Proceedings of the 24th World Gas Conference, 5–9 October 2009, Buenos Aires, Argentina.

[15]	Fedorova, A.A., V.A. Beliautsou, and A.N. Barysevich. 2020. Determining the composition of the group of drones and the basing method for oil pipeline monitoring. In Proceedings of the 2020 International Russian Automation Conference (RusAutoCon), 6–12 September 2020, Sochi, Russia, 330–335.

[16]	Ghorbani Z, Behzadan AH. Monitoring offshore oil pollution using multi-class convolutional neural networks. Environmental Pollution, 2021, 289: 117884

[17]

Hong, S., H. Noh, and B. Han. 2015. Decoupled deep neural network for semi-supervised semantic segmentation. In Advances in Neural Information Processing Systems 28, ed. C. Cortes, N.D. Lawrence, D.D. Lee, M. Sugiyama, and R. Garnett, 1495–1503. La Jolla, CA: Neural Information Processing Systems.

[18]	Hosseini S, Barker K, Ramirez-Marquez JE. A review of definitions and measures of system resilience. Reliability Engineering & System Safety, 2016, 145: 47-61

[19]

Huff, S.A., J.P. Leach, and D.S. Vail. 2015. The importance of high energy piping support maintenance to enhance system useful life. In Proceedings of the ASME 2015 Power Conference collocated with the ASME 2015 9th International Conference on Energy Sustainability, the ASME 2015 13th International Conference on Fuel Cell Science, Engineering and Technology, and the ASME 2015 Nuclear Forum, 28 June–2 July 2015, San Diego, CA, USA.

[20]	Iqbal H, Tesfamariam S, Haider H, Sadiq R. Inspection and maintenance of oil & gas pipelines: A review of policies. Structure and Infrastructure Engineering, 2017, 13(6): 794-815

[21]	Jackson RB, Down A, Phillips NG, Ackley RC, Cook CW, Plata DL, Zhao K. Natural gas pipeline leaks across Washington, DC. Environmental Science and Technology, 2014, 48(3): 2051-2058

[22]	Jia, S., and Q. Feng. 2011. Identifying minimum safe distance between adjacent parallel pipelines. In Proceedings of the ICPTT 2011: Sustainable Solutions for Water, Sewer, Gas, and Oil Pipelines, 26–29 October 2011, Beijing, China, 744–750.

[23]	Jiao Z, Jia G, Cai Y. A new approach to oil spill detection that combines deep learning with unmanned aerial vehicles. Computers & Industrial Engineering, 2019, 135: 1300-1311

[24]	Kim DG, Shin KJ, Woo JH. Displacement measurement of steel pipe support using image processing technology. Journal of Image and Graphics, 2020, 8(3): 80-84

[25]	Lee, A., M. Dahan, and S. Amin. 2017. Integration of sUAS-enabled sensing for leak identification with oil and gas pipeline maintenance crews. In Proceedings of the 2017 International Conference on Unmanned Aircraft Systems (ICUAS), 13–16 June 2017, Miami, FL, USA, 1143–1152.

[26]	Long, J., E. Shelhamer, and T. Darrell. 2015. Fully convolutional networks for semantic segmentation. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, 7–12 June 2015, Boston, MA, USA, 3431–3440.

[27]	Mattar RA, Kalai R. Development of a wall-sticking drone for non-destructive ultrasonic and corrosion testing. Drones, 2018, 2(1): 8

[28]	Mohan A, Poobal S. Crack detection using image processing: A critical review and analysis. Alexandria Engineering Journal, 2018, 57(2): 787-798

[29]	Nayyar ML. Piping Handbook, 1999 6 New York: Mcgraw-hill

[30]	Noh, H., S. Hong, and B. Han. 2015. Learning deconvolution network for semantic segmentation. In Proceedings of the IEEE International Conference on Computer Vision, 7–13 December 2015, Santiago, Chile, 1520–1528.

[31]	Paczkowski, W., and S. Skibicki. 2019. Corrosion as a cause of the failure of the pipeline steel supporting structure. In MATEC Web of Conferences 284. Les Ulis, France: EDP Sciences.

[32]	Peng LC, Peng TL. Pipe Stress Engineering, 2009, New York: ASME Press

[33]	PHMSA (Pipeline and Hazardous Materials Safety Administration). 2021a. PHMSA website. https://www.phmsa.dot.gov/. Accessed 18 Nov 2021.

[34]	PHMSA (Pipeline and Hazardous Materials Safety Administration). 2021b. Pipeline incident 20 year trends. Washington, DC: PHMSA. https://www.phmsa.dot.gov/data-and-statistics/pipeline/pipeline-incident-20-year-trends. Accessed 18 Nov 2021a.

[35]	PHMSA (Pipeline and Hazardous Materials Safety Administration). 2021c. Pipeline failure causes. Washington, DC: PHMSA. https://www.phmsa.dot.gov/incident-reporting/accident-investigation-division/pipeline-failure-causes. Accessed 18 Nov 2021b.

[36]	Phung MD, Dinh TH, Ha QP. System architecture for real-time surface inspection using multiple UAVs. IEEE Systems Journal, 2019, 14(2): 2925-2936.

[37]	Ramalli G, Giovani M, Pacchiacucchi F, Manneschi M. Pipeline monitoring with drones. Studia Universitatis Babes-Bolyai, Ambientum, 2016, 61: 105-118.

[38]	Sorensen SP, Meyer KJ. Beavers JE. Effect of the Denali fault rupture on the Trans-Alaska pipeline. Advancing Mitigation Technologies and Disaster Response for Lifeline Systems, 2003, Reston, VA: American Society of Civil Engineers 547-555

[39]	Sudevan, V., A. Shukla, and H. Karki. 2018. Current and future research focus on inspection of vertical structures in oil and gas industry. In 2018 18th International Conference on Control, Automation and Systems (ICCAS), 17–20 October 2018, PyeongChang, South Korea, 144–149.