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Main Authors: Rahaman, Md. Shakil, Sakib, Ahmed, Samad, Ataharuse, Islam, Md. Ashraful
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.12333
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author Rahaman, Md. Shakil
Sakib, Ahmed
Samad, Ataharuse
Islam, Md. Ashraful
author_facet Rahaman, Md. Shakil
Sakib, Ahmed
Samad, Ataharuse
Islam, Md. Ashraful
contents Decline-curve analysis (DCA) is a widely utilized method for production forecasting and estimating remaining reserves in gas reservoir. Based on the assumptions that past production trend can be mathematically characterized and used to predict future performance. It relies on historical production data and assumes that production methods remain unchanged throughout the analysis. This method is particularly valuable due to its accuracy in forecasting and its broad acceptance within the industry. Wells in the same geographical area and producing from similar geological formations often exhibit similar decline curve parameters. This study applies DCA to forecast the future production performance and estimate the ultimate recovery for the Semutang gas field's well 5 in Bangladesh. Using historical production data, decline curves were generated based on exponential, hyperbolic, and harmonic model equations. The cumulative production estimations were 11,139.34 MMSCF for the exponential model, 11,620.26 MMSCF for the hyperbolic model, and 14,021.92 MMSCF for the harmonic model. In terms of the well's productive life, the estimates were 335.13 days, 1,152 days, and 22,611 days, respectively. Among these models, the hyperbolic decline provided the most realistic forecast, closely aligning with observed production trend. The study highlights the importance of selecting an appropriate decline model for accurate production forecasting and reserve estimation, which is essential for effective reservoir management and resource optimization.
format Preprint
id arxiv_https___arxiv_org_abs_2505_12333
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Predicting Gas Well Performance with Decline Curve Analysis: A Case Study on Semutang Gas Field
Rahaman, Md. Shakil
Sakib, Ahmed
Samad, Ataharuse
Islam, Md. Ashraful
Computational Engineering, Finance, and Science
Decline-curve analysis (DCA) is a widely utilized method for production forecasting and estimating remaining reserves in gas reservoir. Based on the assumptions that past production trend can be mathematically characterized and used to predict future performance. It relies on historical production data and assumes that production methods remain unchanged throughout the analysis. This method is particularly valuable due to its accuracy in forecasting and its broad acceptance within the industry. Wells in the same geographical area and producing from similar geological formations often exhibit similar decline curve parameters. This study applies DCA to forecast the future production performance and estimate the ultimate recovery for the Semutang gas field's well 5 in Bangladesh. Using historical production data, decline curves were generated based on exponential, hyperbolic, and harmonic model equations. The cumulative production estimations were 11,139.34 MMSCF for the exponential model, 11,620.26 MMSCF for the hyperbolic model, and 14,021.92 MMSCF for the harmonic model. In terms of the well's productive life, the estimates were 335.13 days, 1,152 days, and 22,611 days, respectively. Among these models, the hyperbolic decline provided the most realistic forecast, closely aligning with observed production trend. The study highlights the importance of selecting an appropriate decline model for accurate production forecasting and reserve estimation, which is essential for effective reservoir management and resource optimization.
title Predicting Gas Well Performance with Decline Curve Analysis: A Case Study on Semutang Gas Field
topic Computational Engineering, Finance, and Science
url https://arxiv.org/abs/2505.12333