Sensitivity Analysis of Gas Production from Class 2 and Class 3 Hydrate Deposits

Gas hydrates are solid crystalline compounds in which gas molecules are lodged within the lattices of an ice-like crystalline solid. The vast quantities of hydrocarbon gases trapped in hydrate formations in the permafrost and in deep ocean sediments may constitute a new and promising energy source....

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Bibliographic Details
Main Authors: Reagan, Matthew, Moridis, George, Zhang, Keni
Language:unknown
Published: 2009
Subjects:
54
ANISOTROPY
EFFICIENCY
ENERGY SOURCES
GAS HYDRATES
GASES
HYDRATES
HYDROCARBONS
PERMAFROST
POROSITY
PRODUCTION
SEDIMENTS
SENSITIVITY ANALYSIS
WATER
WELL SPACING
Ice
permafrost
Online Access:http://www.osti.gov/servlets/purl/960375
https://www.osti.gov/biblio/960375
Description
Summary:Gas hydrates are solid crystalline compounds in which gas molecules are lodged within the lattices of an ice-like crystalline solid. The vast quantities of hydrocarbon gases trapped in hydrate formations in the permafrost and in deep ocean sediments may constitute a new and promising energy source. Class 2 hydrate deposits are characterized by a Hydrate-Bearing Layer (HBL) that is underlain by a saturated zone of mobile water. Class 3 hydrate deposits are characterized by an isolated Hydrate-Bearing Layer (HBL) that is not in contact with any hydrate-free zone of mobile fluids. Both classes of deposits have been shown to be good candidates for exploitation in earlier studies of gas production via vertical well designs - in this study we extend the analysis to include systems with varying porosity, anisotropy, well spacing, and the presence of permeable boundaries. For Class 2 deposits, the results show that production rate and efficiency depend strongly on formation porosity, have a mild dependence on formation anisotropy, and that tighter well spacing produces gas at higher rates over shorter time periods. For Class 3 deposits, production rates and efficiency also depend significantly on formation porosity, are impacted negatively by anisotropy, and production rates may be larger, over longer times, for well configurations that use a greater well spacing. Finally, we performed preliminary calculations to assess a worst-case scenario for permeable system boundaries, and found that the efficiency of depressurization-based production strategies are compromised by migration of fluids from outside the system.

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