Experimental evaluation of the gas recovery factor of methane hydrate in sandy sediment

Gas production tests have been conducted on artificial sandy sediments saturated by methane hydrate and water using a unique apparatus referred to as High-pressure Giant Unit for Methane-hydrate Analyses (HiGUMA), which is the world's largest reservoir simulating vessel intended for gas hydrate analysis. The gas recovery factor was investigated at various depressurization schemes, including one-step depressurization, multistep depressurization, and depressurization below the quadruple point of methane hydrate. The gas production rate increased during the depressurization process with sediment temperature reduction; however, the rate decrease and stabilized at a very low level after the temperature reached a newly established equilibrium condition. This result indicates that an appropriate heat of the hydrate-bearing sediments is a crucial factor for driving hydrate dissociation. The potential economic recovery factor was 14% for 4.6 MPa of production pressure in the one-step depressurization. In the multistep depressurization, the recovery factor was increased with a reduction in production pressure and showed values of 13%, 31%, and 40% for 4.0 MPa, 3.1 MPa, and 2.5 MPa, respectively. However, depressurization above the quadruple point could not dissociate all the existing hydrate due to the lack of heat. In contrast, it was determined that 65% of the in-place methane could be produced when the production pressure was decreased to 2.1 MPa, which is below the quadruple point, because the latent heat of ice formation was efficiently used for hydrate dissociation. The results show that intentional ice formation by adjusting production pressure can potentially enhance methane hydrate recovery at a comparable level of conventional natural gas production.

[1]  M. H. Yousif,et al.  Depressurization of natural gas hydrates in berea sandstone cores , 1990 .

[2]  Qing Yuan,et al.  Experimental Study on Gas Production from Methane Hydrate-Bearing Sand by Hot-Water Cyclic Injection , 2010 .

[3]  Marco J. Castaldi,et al.  Thermal Stimulation Based Methane Production from Hydrate Bearing Quartz Sediment , 2013 .

[4]  George J. Moridis,et al.  Comparison of kinetic and equilibrium reaction models in simulating gas hydrate behavior in porous media , 2006 .

[5]  Gang Li,et al.  Experimental Investigation into the Production Behavior of Methane Hydrate in Porous Sediment by Depressurization with a Novel Three-Dimensional Cubic Hydrate Simulator , 2011 .

[6]  Gang Li,et al.  Experimental and Numerical Studies on Gas Production from Methane Hydrate in Porous Media by Depressurization in Pilot-Scale Hydrate Simulator , 2012 .

[7]  G. Tsypkin Effect of decomposition of a gas hydrate on the gas recovery from a reservoir containing hydrate and gas in the free state , 2005 .

[8]  Marco J. Castaldi,et al.  Large scale reactor details and results for the formation and decomposition of methane hydrates via thermal stimulation dissociation , 2012 .

[9]  R. Boswell,et al.  Current perspectives on gas hydrate resources , 2011 .

[10]  Marco J. Castaldi,et al.  Experimental Investigation of Methane Gas Production from Methane Hydrate , 2009 .

[11]  Qing Yuan,et al.  Gas Production from Methane-Hydrate-Bearing Sands by Ethylene Glycol Injection Using a Three-Dimensional Reactor , 2011 .

[12]  George J. Moridis,et al.  Toward Production From Gas Hydrates: Current Status, Assessment of Resources, and Simulation-Based Evaluation of Technology and Potential , 2008 .

[13]  J. Schicks,et al.  New Approaches for the Production of Hydrocarbons from Hydrate Bearing Sediments , 2011 .

[14]  Gang Li,et al.  Experimental Investigations into Gas Production Behaviors from Methane Hydrate with Different Methods in a Cubic Hydrate Simulator , 2012 .

[15]  Liyuan Liang,et al.  A new experimental facility for investigating the formation and properties of gas hydrates under simulated seafloor conditions , 2001 .

[16]  Qing Yuan,et al.  A three-dimensional study on the formation and dissociation of methane hydrate in porous sediment by depressurization , 2012 .

[17]  J. C. Santamarina,et al.  Gas Production from Hydrate-Bearing Sediments: The Role of Fine Particles , 2012 .

[18]  G. Moridis Estimating the upper limit of gas production from Class 2 hydrate accumulations in the permafrost: 2. Alternative well designs and sensitivity analysis , 2011 .

[19]  Peter Englezos,et al.  Recovery of Methane from a Variable-Volume Bed of Silica Sand/Hydrate by Depressurization , 2010 .

[20]  Xiao-Sen Li,et al.  Production behavior of methane hydrate in porous media using huff and puff method in a novel three-d , 2011 .

[21]  Bei Liu,et al.  Recovery of methane from hydrate reservoir with gaseous carbon dioxide using a three-dimensional middle-size reactor , 2012 .

[22]  K. Rose,et al.  Simulations of Variable Bottomhole Pressure Regimes to Improve Production from the Double-Unit Mount Elbert, Milne Point Unit, North Slope Alaska Hydrate Deposit , 2011 .

[23]  Wang Xue,et al.  Methane recovery from natural gas hydrate in porous sediment using pressurized liquid CO2 , 2013 .

[24]  Hisanao Ouchi,et al.  Dissociation Behavior of Methane Hydrate in Sandy Porous Media below the Quadruple Point , 2012 .

[25]  優 安田,et al.  メタンハイドレート第二回陸上産出試験 (2007年) の報告 , 2007 .

[26]  Gang Li,et al.  Control Mechanisms for Gas Hydrate Production by Depressurization in Different Scale Hydrate Reservoirs , 2007 .

[27]  Bo Li,et al.  Experimental study on gas production from methane hydrate in porous media by huff and puff method in Pilot-Scale Hydrate Simulator , 2012 .