Scaling parameters for characterizing gravity drainage in naturally fractured reservoir

Miguel-Hernandez, Nemesio

28 August 2008

Not available / text

Rocks--Fracture--Simulation methods

Rocks--Permeability

Hydraulic fracture optimization using hydraulic fracture and reservoir modeling in the Piceance Basin, Colorado

Reynolds, Harris Allen

06 November 2012

Hydraulic fracturing is an important stimulation method for producing unconventional gas reserves. Natural fractures are present in many low-permeability gas environments and often provide important production pathways for natural gas. The production benefit from natural fractures can be immense, but it is difficult to quantify. The Mesaverde Group in the Piceance Basin in Colorado is a gas producing reservoir that has low matrix permeability but is also highly naturally fractured. Wells in the Piceance Basin are hydraulically fractured, so the production enhancements due to natural fracturing and hydraulic fracturing are difficult to decouple. In this thesis, dipole sonic logs were used to quantify geomechanical properties by combining stress equations with critically-stressed faulting theory. The properties derived from this log-based evaluation were used to numerically model hydraulic fracture treatments that had previously been pumped in the basin. The results from these hydraulic fracture models, in addition to the log-derived reservoir properties were used to develop reservoir models. Several methods for simulating the reservoir were compared and evaluated, including layer cake models, geostatistical models, and models simulating the fracture treatment using water injection. The results from the reservoir models were compared to actual production data to quantify the effect of both hydraulic fractures and natural fractures on production. This modeling also provided a framework upon which completion techniques were economically evaluated. / text

Hydraulic fracturing

Unconventional gas

Reservoir simulation

Hydraulic fracture simulation

Piceance Basin

Groundwater inflow into rock tunnels

Chen, Ran

09 November 2010

Prediction of groundwater inflow into rock tunnels is one of the essential tasks of tunnel engineering. Currently, most of the methods used in the industry are typically based on continuum models, whether analytical, semi-empirical, or numerical. As a consequence, a regular flow along the tunnel is commonly predicted. There are also some discrete fracture network methods based on a discontinous model, which typically yield regular flow or random flow along the tunnel. However, it was observed that, in hard rock tunnels, flow usually concentrates in some areas, and much of the tunnel is dry. The reason is that, in hard rock, most of the water flows in rock fractures and fractures typically occur in a clustered pattern rather than in a regular or random pattern. A new method is developed in this work, which can model the fracture clustering and reproduce the flow concentration. After elaborate literature review, a new algorithm is developed to simulate fractures with clustering properties by using geostatistics. Then, a discrete fracture network is built and simplified. In order to solve the flow problem in the discrete fracture network, an existing analytical-numercial method is improved. Two case studies illustrate the procedure of fracture simulation. Several ideal tunnel cases and one real tunnel project are used to validate the flow analysis. It is found that fracture clustering can be modeled and flow concentration can be reproduced by using the proposed technique. / text

Groundwater

Tunnels

Discrete fracture network

Geostatistics

Fracture simulation

Underground excavations

Tunnel engineering

CRASHWORTHINESS SIMULATION OF ROADSIDE SAFETY STRUCTURES WITH DEVELOPMENT OF MATERIAL MODEL AND 3-D FRACTURE PROCEDURE

Wu, Jin

January 2000

No description available.

Roadside Safety

Crashworthiness Simulation

Guardrail Vehicle Impact

Wood Material Modeling

Fracture Simulation

Towards real-time simulation of interactions among solids andfluids

Chen, Zhili

January 2015

No description available.

Computer Science

computer graphics

computer animation

simulation

physics based simulation

fracture simulation

fluid simulation

CUDA

GPU

real-time graphics