Numerical simulation research on downhole methane combustion heating tool for hydrate exploitation: Gas−liquid heat transfer performance

Natural gas hydrates are considered a promising clean energy resource with significant development potential. This study focuses on the research and application of energy supplementation tools in natural gas hydrate extraction. First, a methane combustion heating process is proposed, and a methane combustion heating tool is designed to heat hydrate reservoirs through methane combustion. The tool includes key components such as a pressure-bearing pipe and an igniter, with the primary goal of promoting hydrate dissociation by increasing the reservoir temperature. To assess the tool’s ignition and heating capabilities in a water-immersed environment, surface experiments are conducted, and the tool’s actual value for reservoir development is verified using a gas production model. Next, a flow field model of the tool in the downhole environment is established using Computational Fluid Dynamics (CFD), and the flow field characteristics and heat transfer performance of the tool are systematically studied. The results show that the tool can increase the reservoir temperature by 10 °C. Further analysis of the impact of various operational parameters on the internal flow field and heating efficiency reveals that a higher inlet gas flow rate (methane at 6 m/s) and optimized gas ratio (e.g., 1:5) significantly improve heating efficiency. Additionally, the influence of key structural parameters, such as the number of combustion ports and combustion channel dimensions, on the tool’s heating performance is analyzed. Based on these findings, recommendations for optimizing the tool’s design are proposed.