Numerical analysis of experimental studies of methane hydrate dissociation induced by depressurization in a sandy porous medium

Abstract Methane Hydrates (MHs) are a promising energy source abundantly available in nature. Understanding the complex processes of MH formation and dissociation is critical for the development of safe and efficient technologies for energy recovery. Many laboratory and numerical studies have investigated these processes using synthesized MH-bearing sediments. A near-universal issue encountered in these studies is the spatial heterogeneous hydrate distribution in the testing apparatus. In the absence of direct observations (e.g. using X-ray computed tomography) coupled with real time production data, the common assumption made in almost all numerical studies is a homogeneous distribution of the various phases. In an earlier study (Yin et al., 2018) that involved the numerical description of a set of experiments on MH-formation in sandy medium using the excess water method, we showed that spatially heterogeneous phase distribution is inevitable and significant. In the present study, we use as a starting point the results and observations at the end of the MH formation and seek to numerically reproduce the laboratory experiments of depressurization-induced dissociation of the spatially-heterogeneous MH distribution. This numerical study faithfully reproduces the geometry of the laboratory apparatus, the initial and boundary conditions of the system, and the parameters of the dissociation stimulus, capturing accurately all stages of the experimental process. Using inverse modelling (history-matching) that minimized deviations between the experimental observations and numerical predictions, we determined the values of all the important flow, thermal, and kinetic parameters that control the system behaviour, which yielded simulation results that were in excellent agreement with the measurements of key monitored variables, i.e. pressure, temperature, cumulative production of gas and water over time. We determined that at the onset of depressurization (when the pressure drop – the driving force of dissociation – is at its maximum), the rate of MH dissociation approaches that of an equilibrium reaction and is limited by the heat transfer from the system surroundings. As the effect of depressurization declines over time, the dissociation reaction becomes kinetically limited despite significant heat inflows from the boundaries, which lead to localized temperature increases in the reactor.

[1]  G. Moridis,et al.  User's Manual of the TOUGH+ Core Code v1.5: A General-Purpose Simulator of Non-Isothermal Flow and Transport through Porous and Fractured Media , 2014 .

[2]  Gorjan Alagic,et al.  #p , 2019, Quantum information & computation.

[3]  Yu Zhang,et al.  Three dimensional experimental and numerical investigations into hydrate dissociation in sandy reservoir with dual horizontal wells , 2015 .

[4]  George J. Moridis,et al.  Strategies for gas production from hydrate accumulations under various geologic conditions , 2003 .

[5]  D. G. Russell,et al.  Methods for Predicting Gas Well Performance , 1966 .

[6]  Zhenyuan Yin,et al.  Experimental investigations on energy recovery from water-saturated hydrate bearing sediments via depressurization approach , 2017 .

[7]  Gang Li,et al.  Gas Production from Methane Hydrate in a Pilot-Scale Hydrate Simulator Using the Huff and Puff Method by Experimental and Numerical Studies , 2012 .

[8]  G. J. Moridis,et al.  User's Manual for the Hydrate v1.5 Option of TOUGH+ v1.5: A Code for the Simulation of System Behavior in Hydrate-Bearing Geologic Media , 2014 .

[9]  Thomas de Quincey [C] , 2000, The Works of Thomas De Quincey, Vol. 1: Writings, 1799–1820.

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

[11]  Yongchen Song,et al.  Numerical Simulation of the Gas Production Behavior of Hydrate Dissociation by Depressurization in Hydrate-Bearing Porous Medium , 2012 .

[12]  Peter Englezos,et al.  Magnetic Resonance Imaging of Gas Hydrate Formation in a Bed of Silica Sand Particles , 2011 .

[13]  George J. Moridis,et al.  Numerical Predictions of Experimentally Observed Methane Hydrate Dissociation and Reformation in Sandstone , 2014 .

[14]  L. Kent Thomas,et al.  A Nonlinear Automatic History Matching Technique for Reservoir Simulation Models , 1972 .

[15]  George J. Moridis,et al.  X-Ray computed tomography examination and comparison of gas hydrate dissociation in NGHP-01 expedition (India) and Mount Elbert (Alaska) sediment cores: Experimental observations and numerical modeling , 2014 .

[16]  George J. Moridis,et al.  Numerical Studies of Gas Production From Methane Hydrates , 2003 .

[17]  George J. Moridis,et al.  Numerical analysis of experimental studies of methane hydrate formation in a sandy porous medium , 2018, Applied Energy.

[18]  H. K. Tan,et al.  Numerical Analysis of Experiments on Thermally Induced Dissociation of Methane Hydrates in Porous Media , 2017 .

[19]  I︠u︡. F. Makogon Hydrates of Hydrocarbons , 1997 .

[20]  G. A. Jeffrey,et al.  Clathrate Hydrates , 2007 .

[21]  Yongchen Song,et al.  Gas recovery from depressurized methane hydrate deposits with different water saturations , 2017 .

[22]  Tsuyoshi Murata,et al.  {m , 1934, ACML.

[23]  George J. Moridis,et al.  Depressurization-induced gas production from Class 1 hydratedeposits , 2005 .

[24]  Timothy J Kneafsey,et al.  Methane Hydrate Distribution from Prolonged and Repeated Formation in Natural and Compacted Sand Samples: X-Ray CT Observations , 2010 .

[25]  M. Reagan,et al.  Strategies for gas production from oceanic Class 3 hydrate accumulations , 2007 .

[26]  E. D. Sloan,et al.  NMR Investigation of Methane Hydrate Dissociation , 2007 .

[27]  장윤희,et al.  Y. , 2003, Industrial and Labor Relations Terms.

[28]  Sung Chan Nam,et al.  Recovery of Methane from Hydrate Formed in a Variable Volume Bed of Silica Sand Particles , 2009 .

[29]  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 .

[30]  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 .

[31]  Praveen Linga,et al.  Review of natural gas hydrates as an energy resource: Prospects and challenges ☆ , 2016 .

[32]  T. Ebinuma,et al.  Analysis of Production Data for 2007/2008 Mallik Gas Hydrate Production Tests in Canada , 2010 .

[33]  George J. Moridis,et al.  Methane hydrate formation and dissociation in a partially saturated core-scale sand sample , 2005 .

[34]  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 .

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

[36]  Yu Zhang,et al.  Effect of horizontal and vertical well patterns on methane hydrate dissociation behaviors in pilot-scale hydrate simulator , 2015 .

[37]  Van Genuchten,et al.  A closed-form equation for predicting the hydraulic conductivity of unsaturated soils , 1980 .

[38]  Scott J. Wilson,et al.  Regional long-term production modeling from a single well test, Mount Elbert Gas Hydrate Stratigraphic Test Well, Alaska North Slope , 2011 .

[39]  J. Schicks,et al.  Characterizing electrical properties and permeability changes of hydrate bearing sediments using ERT data , 2015 .

[40]  Gang Li,et al.  Kinetic studies of methane hydrate formation in porous media based on experiments in a pilot-scale hydrate simulator and a new model , 2014 .

[41]  Gang Li,et al.  Kinetic Behaviors of Methane Hydrate Formation in Porous Media in Different Hydrate Deposits , 2014 .

[42]  Syed S. H. Rizvi,et al.  Kinetics of methane hydrate decomposition , 1987 .

[43]  S. Mathias,et al.  Masuda’s sandstone core hydrate dissociation experiment revisited , 2017 .

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

[45]  Miss A.O. Penney (b) , 1974, The New Yale Book of Quotations.

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

[47]  Goodarz Ahmadi,et al.  Computational modeling of methane hydrate dissociation in a sandstone core , 2007 .

[48]  George J. Moridis,et al.  Numerical studies of gas production from several CH4 hydrate zones at the Mallik site, Mackenzie Delta, Canada , 2004 .

[49]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[50]  E. D. Sloan,et al.  Molecular measurements of methane hydrate formation , 1999 .

[51]  S. Bryant,et al.  Salinity‐buffered methane hydrate formation and dissociation in gas‐rich systems , 2015 .

[52]  Yongchen Song,et al.  In Situ Observation of Methane Hydrate Dissociation under Different Backpressures , 2015 .

[53]  Stephen M. Masutani,et al.  A Review of the Methane Hydrate Program in Japan , 2017 .

[54]  Mingjun Yang,et al.  Methane hydrate formation in excess water simulating marine locations and the impact of thermal stimulation on energy recovery , 2016 .

[55]  J. Howard,et al.  ConocoPhillips Gas Hydrate Production Test , 2013 .

[56]  George J. Moridis,et al.  Challenges, uncertainties and issues facing gas production from gas hydrate deposits , 2010 .

[57]  M. Clarke,et al.  Determination of the activation energy and intrinsic rate constant of methane gas hydrate decomposition , 2001 .

[58]  Abdolmajid Liaghat,et al.  Estimation of the van Genuchten soil water retention properties from soil textural data. , 2010 .

[59]  J. Schicks,et al.  A cylindrical electrical resistivity tomography array for three-dimensional monitoring of hydrate formation and dissociation. , 2013, The Review of scientific instruments.

[60]  Kishore K. Mohanty,et al.  Kinetic simulation of methane hydrate formation and dissociation in porous media , 2006 .

[61]  H. O. Kono,et al.  Synthesis of methane gas hydrate in porous sediments and its dissociation by depressurizing , 2002 .

[62]  Yongchen Song,et al.  Numerical simulation for laboratory-scale methane hydrate dissociation by depressurization , 2010 .

[63]  Jiafei Zhao,et al.  Effect of depressurization pressure on methane recovery from hydrate–gas–water bearing sediments , 2016 .

[64]  E. D. Sloan,et al.  Fundamental principles and applications of natural gas hydrates , 2003, Nature.

[65]  G. MacDonald The Future of Methane as an Energy Resource , 1990 .

[66]  Timothy J. Kneafsey,et al.  Permeability of Laboratory-Formed Methane-Hydrate-Bearing Sand: Measurements and Observations Using X-Ray Computed Tomography , 2011 .

[67]  H. L. Stone Probability Model for Estimating Three-Phase Relative Permeability , 1970 .

[68]  T. Uchida,et al.  Dissociation of Natural Gas Hydrates Observed by X‐ray CT Scanner , 2000 .

[69]  T. Inoue,et al.  Scientific results from the Mallik 2002 gas hydrate production research well program, Mackenzie Delta, northwest territories, Canada: Preface , 2005 .

[70]  Barry Freifeld,et al.  X-ray Computed Tomography Observation of Methane Hydrate Dissociation , 2002 .

[71]  A. Milkov Global estimates of hydrate-bound gas in marine sediments: how much is really out there? , 2004 .

[72]  Jun Mikami,et al.  Occurrences of Natural Gas Hydrates beneath the Permafrost Zone in Mackenzie Delta: Visual and X‐ray CT Imagery , 2000 .

[73]  M. Reagan,et al.  Feasibility of gas production from a gas hydrate accumulation at the UBGH2-6 site of the Ulleung basin in the Korean East Sea , 2013 .

[74]  Shigenao Maruyama,et al.  Numerical analysis of core-scale methane hydrate dissociation dynamics and multiphase flow in porous media , 2016 .

[75]  M. Kowalsky,et al.  Gas Production from Unconfined Class 2 Oceanic Hydrate Accumulations , 2006 .