Natural gas hydrate (NGH) has attracted considerable global attention as a promising energy resource in recent years. To acquire valuable insights into regarding the interplay between mechanical properties and production outcomes during the production, in this study, a fully coupled thermo-hydro-mechanical-chemical (THMC) model based on the geological features of reservoirs in the Shenhu area of the South China Sea (SCS) was developed to analyze the response characteristics of various physical fields within the reservoir during the exploitation. Furthermore, the study examined the influence of mechanical behavior on hydrate exploitation and investigated the effects of varying initial hydrate saturation and seawater depth on production efficiency and reservoir deformation. The simulation results indicated that neglecting the impact of solid mechanics in the analysis of hydrate productivity can result in overestimated results, particularly during the initial production stage. Reservoirs with higher hydrate saturation experience lower initial production rates due to the influence of permeability and capillary force. Moreover, reservoirs with high hydrate saturation exhibit greater compression but lower wellhead subsidence during the long-term development. The impact of seawater depth on production capacity primarily arises from the pressure's influence on the gas-water ratio, where greater seawater depth corresponds to increased reservoir compression and wellhead subsidence.
© 2023 The Authors. Published by American Chemical Society.