Advanced Well Test Analysis

Application of Pressure and Derivative to Drawdown and Buildup Tests

• Review of fundamental concepts of well testing and measurement techniques (Video)
• Pressure-based analysis of flow and buildup tests
• Derivative-based analysis of flow and buildup tests, TDS technique
• Determining Average reservoir pressure
• Drainage area and pore volume of bounded systems, oil in place

On the first day, participants will learn how to understand the theory, applications, and practical limitations of conventional pressure analysis techniques.  Acquiring the skill to use the pressure derivative by recognizing unique finger prints of various flow regimes will also be covered.             

Hydraulically Fractured Wells and Gas Well Testing

• Practical aspects of fracturing and acidizing (Video)
• Uniform-flux and infinite-conductivity models of hydraulic fractures
• Finite-conductivity: linear, bilinear, and elliptical flow
• Geometry of inclined hydraulic fractures
• Interpreting gas well tests using pressure and pseudo-pressure derivative

How a post-frac pressure test may well be the most important and only effective tool to assess, both qualitatively and quantitatively, the stimulation treatment will be covered. Participants will be given simple equations, based on the pressure derivative, for calculating permeability, skin factor, fracture length, fracture conductivity, and fracture inclination angle.               

Naturally Fractured Reservoirs and Carbonates

• Evaluation of carbonate reservoirs (Video)
• Indicators and types of NFR
• Pseudo-steady state and unsteady state matrix flow models
• Storativity and Porosity Partitioning coefficient
• Fracture porosity from well logs and well test analysis
• Interpretation of interference and pulse tests, pressure derivative

The fact that carbonate reservoirs produce a major portion of the world’s oil and gas will be the main focus on this day.  Participants will also learn that they hold more than half of the world’s largest crude oil and natural gas reserves. Yet, accurately predicting amounts and types of porosity and, therefore, original oil-in-place and reserves, is still a major challenge in carbonate reservoirs.  Attendees will learn how to characterize the four different types of NFR, how to use unique finger prints of the pressure derivative to delineate the fracture system intensity and extent, as well as how to quantify reservoir pore volume.          

Multiphase Flow, Multirate Tests, and Partially Perforated Wells

• Role of fluid properties, Perrine Permeability
• Dynamic Reservoir Testing (Video)
• Conventional and modern interpretation of multi-rate tests
• Applications of TDS, convolution and deconvolution techniques
• Partially completed/penetrated/perforated wells
• Vertical permeability from spherical flow, MDT

On this day, participants will learn how fluid properties change with pressure and how they are used to calculate effective permeability to oil, gas, and water.  How to use the TDS technique to analyze pressure buildup tests preceded by variable rate will also be covered.  Determining vertical permeability will be one of the most important objectives of this day’s presentations.  Detailed discussion of spherical flow and MDT will be presented.              

Slanted and Horizontal Wells

• Effect of slant on pressure-response
• Determining angle of inclination of slanted well and partial penetration/perforation skin
• Overview of horizontal well completions and performance (Video)
• Flow regimes and analytical solutions
• Applications of pressure derivative to calculate directional permeability values
• Pressure analysis of hydraulically fractured horizontal wells

Participants will become familiar with several methods to analyze pressure drawdown and buildup tests in horizontal wells, including pressure-based conventional techniques, and techniques that are strictly based on the pressure derivative.  This is the only course where attendees will learn how to analyze the elliptical flow regime using the pressure derivative.