Mathematical Modeling of Fluid Flow and Heat Transfer in Petroleum Industries and Geothermal Applications
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ArticleLanguage: English Publication details: MDPI - Multidisciplinary Digital Publishing Institute 2020Description: 1 electronic resource (470 p.)ISBN: - books978-3-03928-721-5
- 9783039287208
- 9783039287215
- karst carbonate reservoir
- fracture compressibility
- enhanced gas recovery
- cost of electricity (COE)
- microstructure
- permeability
- CO2 permeability
- ammonia
- shale oil
- process simulation
- aquifer support
- spatiotemporal characteristics
- semi-analytical solution
- injection orientation
- CO2 diffusion
- wellbore temperature
- fluid front kinetics
- nest of tubes
- supercritical CO2
- multiple parallel fractures
- multifractal theory
- real-scale
- techno-economic model
- fractal
- inter-well connectivity
- apparent permeability
- heat transfer
- porous media
- multiple structural units (MSU)
- coupled heat conduction and advection
- diffusion
- bottom-hole pressure
- tight reservoir
- ventilation
- surface diffusion
- unsteady process
- underground coal gasification (UCG)
- dynamic crack tip
- mercury intrusion porosimetry
- energy conservation analysis
- methanol
- comprehensive heat transfer model
- pressure fluctuations
- production optimization
- numerical simulation
- percolation model
- rheology
- drilling
- AE energy
- pipeline network
- natural gas
- huff-‘n-puff
- cement
- viscosity
- mathematical modeling
- enhanced geothermal systems
- cement slurries
- yield stress
- non-Newtonian fluids
- capacitance-resistance model
- thixotropy
- conductivity
- enhanced oil recovery
- leakage and overflow
- geothermal
- coal and rock fracture
- impact pressure
- computational fluid dynamics (CFD)
- GSHP (ground source heat pump)
- pore size distribution
- Knudsen diffusion
- hydraulic fracturing
- efficient simulation
- constitutive relations
- electricity generation
- fractal theory
- pore structure
- complex fracture network
- sloshing
- cost-effective
- slippage effect
- dynamic hydraulic-fracturing experiments
- critical porosity
- fracture uncertainty
- carbon capture and utilization (CCU)
- tube bundle model
- continuity/momentum and energy equations coupled
- main gas pipeline
- Coal excavation
- longitudinal dispersion coefficient
- computational fluid dynamic (CFD)
- flowback
- fracture simulation
- highly viscous fluids
- carbon capture and storage (CCS)
- energy dissipation
- economics
- particles model
- variable viscosity
- multi-pressure system
- frequency conversion technology (FCT)
- three-dimensional numerical simulation
- tight oil reservoirs
- multiphase flow
- methane removal
- Navier-Stokes equations
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Geothermal energy is the thermal energy generated and stored in the Earth's core, mantle, and crust. Geothermal technologies are used to generate electricity and to heat and cool buildings. To develop accurate models for heat and mass transfer applications involving fluid flow in geothermal applications or reservoir engineering and petroleum industries, a basic knowledge of the rheological and transport properties of the materials involved (drilling fluid, rock properties, etc.)—especially in high-temperature and high-pressure environments—are needed. This Special Issue considers all aspects of fluid flow and heat transfer in geothermal applications, including the ground heat exchanger, conduction and convection in porous media. The emphasis here is on mathematical and computational aspects of fluid flow in conventional and unconventional reservoirs, geothermal engineering, fluid flow, and heat transfer in drilling engineering and enhanced oil recovery (hydraulic fracturing, CO2 injection, etc.) applications.
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