CMG's superior technology continues to break new ground for simulator capabilities, model building and the refinement of advanced recovery processes through a combination of parallel processing, dynamic gridding and the multi-physics required to correctly model each process, including cross-disciplinary interactions like thermal effects, geochemistry, geomechanics, fluid and phase behavior as well as wellbore hydraulics and completions.

IMEX, one of the world's fastest conventional black oil reservoir simulators is used to obtain history matches and forecasts of primary, secondary, and enhanced or improved oil recovery processes. In addition, IMEX models complex, heterogeneous, faulted oil and gas reservoirs, using millions of grid blocks, to achieve the most reliable predictions and forecasts. Use IMEX for screening prospects, setting up pilot designs, monitoring and optimizing field operations, and improving production performance.

With IMEX, you will:

Achieve simulation results faster than with any other black-oil simulator
Quickly screen a variety of recovery mechanisms before moving to more complex simulations
Accurately model the matrix-fracture transfer in naturally and/or hydraulically fractured reservoirs
Use the speed of IMEX to model shale gas adsorption effects
Easily transition to EOR process modelling in GEM and STARS
Seamlessly interface with CMOST to facilitate rapid history matching and optimization of reservoir management workflows

GEM is the world’s leading reservoir simulation software for compositional and unconventional reservoir modelling. GEM is an advanced general Equation-of-State (EoS) compositional simulator that models the flow of three-phase, multi-component fluids. GEM can model any type of recovery process where effective fluid composition is important.

GEM accurately simulates structurally complex and varying fluid combinations including, processes in which the effects of inter-phase mass transfer (i.e. changing fluid phase composition) are important. GEM will effectively model laboratory scale projects, pilot areas, elements of symmetry, or full-scale field studies.

Replicates reservoir physics and chemistry to assist in optimizing field, surface operating conditions and overall recovery
Improves understanding of fluid property composition and behaviour
Simulates complex reservoirs to identify optimal reservoir processes
Models naturally and hydraulically fractured reservoirs
Increases estimated NPV through accurate phase behaviour models
Optimizes field and surface operating conditions for improved overall recovery

STARS is the undisputed industry standard in thermal and advanced processes reservoir simulation. STARS is a thermal, k-value (KV) compositional, chemical reaction and geomechanics reservoir simulator ideally suited for advanced modelling of recovery processes involving the injection of steam, solvents, air and chemicals. The robust reaction kinetics and geomechanics capabilities make it the most complete and flexible reservoir simulator available.

Accurately model the physics of all in-situ recovery processesƒ
Multi-scale modelling from core floods to field-scale
Increase confidence in field development plans and support capital expenditures
Modelling for dispersed components and simulate formation of emulsions and foams, and predict asphaltene precipitation/deposition
Design accurate SAGD well pairs
Seamless integration with CMOST for rapid, accurate history matches and uncertainty analyses, while leveraging limited engineering time

CMOST is a state-of-the-art reservoir engineering tool, employing innovative experimental design, and sampling and optimization techniques to efficiently determine reservoir parameters defining production and recovery of oil and gas fields. Used in conjunction with CMG simulators – IMEX, GEM and STARS – engineers increase productivity and make well-informed engineering decisions, faster and with higher resolution.

Increase confidence in forecasts

Increase asset and team effectiveness through optimization
Assess the sensitivity of objectives to different parameter values
Calibrate and history match models with field and lab data, including temperature logs and 4D seismic
Optimize well and fracture spacing to increase production, NPV and EUR
Optimize chemical EOR operational parameters to increase recovery and reduce chemical costs
Quantify uncertainty to manage risk and identify opportunities
Optimize operational and completion strategies to reduce steam-oil ratio and increase NPV and ultimate recovery

With CMOST, engineers can effortlessly optimize the placement of wells, frac spacing, infill drilling plans, injection rates, and pressure maintenance, using virtually any reservoir model parameter, to improve economics, reduce risk and quantify uncertainty.

Only for V.I.P