INIS
energy storage systems
100%
thermal recovery
100%
low temperature
100%
efficiency
100%
aquifers
100%
storage
100%
volume
77%
ground water
66%
values
33%
energy storage
33%
optimization
33%
losses
33%
increasing
22%
design
22%
screens
22%
energy
22%
simulation
22%
range
22%
dispersions
22%
velocity
22%
length
22%
space cooling
11%
sensitivity
11%
space heating
11%
surface area
11%
heat losses
11%
energy losses
11%
Earth and Planetary Sciences
Impact
100%
Heat Storage
100%
Thermal Recovery
100%
Efficiency
100%
Aquifer
100%
Groundwater Flow
55%
Loss
44%
Investigation
33%
Optimization
33%
Flow Velocity
22%
Increasing
22%
Thermal Energy
22%
Show
11%
Cooling
11%
Surface Area
11%
Technology
11%
Derivation
11%
Selection
11%
Energy Dissipation
11%
World System
11%
Heating
11%
Approach
11%
Heat
11%
Energy Saving
11%
Groundwater
11%
Engineering
Recovery Efficiency
100%
Storage
100%
Aquifer Thermal Energy Storage
100%
Thermal Energy Storage System
100%
Low-Temperature
100%
Optimization
37%
Radius
25%
Thermal Energy
25%
Flow Velocity
25%
Loss
25%
Design Value
12%
Heat Losses
12%
Increasing Surface Area
12%
Systematic Analysis
12%
Optimal Design
12%
Space Heating
12%
Volume Ratio
12%
Energy Conservation
12%
Specific Site
12%
Simulation Result
12%
Principal Factor
12%
Design
12%
Main Parameter
12%
Temperature
12%
Energy Dissipation
12%
Conduction Loss
12%
Analytical Approach
12%
Main Process
12%
Keyphrases
Thermal Radius
25%
Ambient Flow
25%
Displacement Loss
12%
Thermal Energy Losses
12%
Hydrogeological Conditions
12%
Storage Study
12%
Energy Storage Design
12%
Groundwater Flow Velocity
12%
Sustainable Space
12%