Surge Mitigation and Optimization Strategies for Aviation Turbine Fuel Pipelines in India

Osama Nasir; Kr Mohd. Salman; Ahmad Ali Khan

doi:10.66871/trf-j.v1i2.029

लेखक

Osama Nasir अलीगढ़ मुस्लिम विश्वविद्यालय ##default.groups.name.author##
Kr Mohd. Salman अलीगढ़ मुस्लिम विश्वविद्यालय ##default.groups.name.author##
Ahmad Ali Khan अलीगढ़ मुस्लिम विश्वविद्यालय ##default.groups.name.author##

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https://doi.org/10.66871/trf-j.v1i2.029

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Aviation Turbine Fuel (ATF), Pipeline Optimization, Surge Mitigation, Sustainable Aviation Fuel

सार

The rapid growth of India’s aviation sector has driven an unprecedented increase in the demand for aviation turbine fuel (ATF). With domestic consumption escalating at double-digit rates annually, optimizing the pipeline infrastructure for ATF transportation has become imperative to enhance efficiency, reduce costs, and mitigate environmental impacts. This paper critically examines the strategies for optimizing ATF pipelines in India, emphasizing the integration of advanced valve technologies, the implementation of surge mitigation strategies, and the use of Sustainable Aviation Fuel (SAF). Through an extensive literature review and analysis, this study identifies key areas where current practices can be improved, explores the impact of valve sizing on surge phenomena, and highlights the role of high-quality pipeline materials. The findings provide insights into the sustainable development of India's aviation fuel supply chain, offering policy recommendations and future research directions aimed at establishing India as a leader in SAF integration.

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Pursuing MBA in Finance & Operations from FMSR, Aligarh Muslim University (India)
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Associate Senior Mechanical Engineer at Burns and McDonnell, Mumbai
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Professor of Mechanical Engineering at Department of Mechanical Engneering, Aligarh Muslim University

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1.AFT. (2016). AFT Impulse User Manual. Applied Flow Technology.Benoit, D., et al. (2020). "Advanced Control Strategies for Surge Management in Pipelines." Journal of PipelineEngineering, 14(3), 245-262.

2.Benoit, D., et al. (2020)."Advanced Control Strategies for Surge Management in Pipelines." Journal of Pipeline Engineering, 14(3), 245-262.

3.Chen, L., et al. (2020)."Optimizing Flow Distribution with Bypass and Throttling Valves in Pipeline Systems." Journal of Fluid Engineering, 142(8), 081301.

4.Feng, Y., et al. (2015). "Surge Analysis and Control: A Comprehensive Review." Chemical Engineering Journal, 263, 129-146.

5.Huang, X., et al. (2023). "Transient Flow Behavior in Gasoline Pipelines: Impact of Water Hammer and Column Separation." Journal of Pipeline Systems Engineering and Practice.

6.Ishii, M., et al. (2021). "Economic Implications of Surge Management in Pipelines." International Journal of Fluid Flow, 45(2), 67-79.

7.Jiang, Y., et al. (2017)."Regulatory Challenges in Pipeline Surge Control." EnergyPolicy Review, 53, 14-22.

8.Kumar, A., et al. (2020). "Enhancing Pipeline Safety with Automated Isolation Valves." Chemical Engineering Research & Design, 146, 69-81.

9.Kumar, V., & Singh, P. (2020). "Challenges in Transient Flow Analysis: The Role of Valve Sizing in Pipeline Systems." Journal of Pipeline Engineering.

10.Li, X., et al. (2021). "Real-Time Data Integration for Surge Monitoring in Pipelines." Journal of Process Control, 93, 52-61.

11.Martinez, P., & Garcia, R. (2022). "Water Hammer Mitigation in Petroleum Pipelines: Case Studies and Practical Approaches." Pipelines and Risers.

12.Moussavi, A., & Lee, D. (2016). "Surge Relief Valves: Design and Application." Hydraulic Engineering Journal, 142(7), 102-110.

13.Patel, R., et al. (2018)."Electro-Hydraulic Control Systemsfor High-Pressure PipelineManagement." Journal of Pipeline Systems Engineering and Practice, 9(4), 04018018.

14.Rao, R., et al. (2017)."Environmental and SafetyImplications of PipelineMaterials in ATF Systems." Environmental Science & Technology, 51(9), 5602-5610.

15.Sharma, A., et al. (2019). "Corrosion Resistance of PipelineMaterials in Aviation TurbineFuel Systems: A Comparative Study." Materials Performance, 58(5), 45-52.

16.Singh, J., & Desai, S. (2018). "Economic Impact of High-Quality Materials in Pipeline Systems." Journal of Pipeline Systems Engineering and Practice, 9(2), 04018001.

17.Svetina, J., et al. (2019). "Pipeline Design Considerations for Surge Control." Journal of Hydraulic Engineering, 145(5), 03019004.

18.Wang, X., et al. (2016)."The Role of Pressure-Reducing Valvesin Managing PressureFluctuations in Pipeline Systems." Journal of Hydraulic Engineering, 142(6), 03115001.

19.Zhang, Y., et al. (2021)."Advances in SurgeAnalysis and Controlin Jet Fuel Pipelines." International Journal of Pressure Vessels and Piping.

20.Zhou, Y., et al. (2018)."Predictive Control Strategies for Pipeline Surge Mitigation." Control Engineering Practice, 75, 122-135.

21.Zhu, X., et al. (2017). "Computational Fluid Dynamics in Surge Analysis: A Review." Computers & Fluids, 153, 1-15.

22.National Policyon Biofuels. (2018).

23.Green Aviation Initiative.

24.Pumping Station Design. (2022). "Case Study: Impactof Incorrect Valve Sizing on Jet Fuel Pipeline Performance."

25.Harriss-White, Barbara. 2003. India Working: Essays on Society and Economy. Cambridge: Cambridge University Press.

26.Heaton, Janet. 2008. “Secondary Analysis of Qualitative Data: An Overview.” Historical Social Research 33 (3): 33–45. https://doi.org/10.12759/hsr.33.2008.3.33-45.

Surge Mitigation and Optimization Strategies for Aviation Turbine Fuel Pipelines in India

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