2:15 PM - 2:30 PM
[HSC05-15] Numerical simulation of seafloor ground deformation during CO2 underground storage using gas hydrate
Keywords:A carbon dioxide capture and storage, gas hydrate, ground deformation, numerical simulation
In the present study, two-phase fluid–solid coupled analysis has been conducted to reproduce the ground deformation during CO2 underground storage a hydrate. Solid phase (soil, hydrate) and two liquid phases (CO2, water) are dealt with in the numerical analysis. An elasto-viscoplastic constitutive models are used for CO2 hydrate-bearing sediment. As a capillary pressure- saturation relation, van Genuchten model is used. Finite element method and Newmark’s β method is used as a discretization in space and time, respectively.
As a simulation example, the mechanical stability of the ground by CO2 liquid injection is examined, assuming a hydrate seal layer with a thickness of 2 m is formed in the seafloor ground at a water depth of 1000 m. Simulation results will be discussed regarding to the change of water pressure, CO2 liquid pressure, saturation, effective stress, and the soil deformation during CO2 liquid injection.
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