D997 Applied Reservoir Engineering

Course Facts

Course Code:
D997
Duration:
5 days
Type:
Virtual Classroom
CEU:
4 Continuing Education Units
PDH:
40 Professional Development Hours
Certificate:
Certificate Issued Upon Completion

Summary

Business Impact: Participants will develop the skills to add value by accurately assessing recoverable volumes, enhancing hydrocarbon recovery, and developing more robust reservoir simulation models.

This course aims to provide the practicing reservoir engineer with a range of analysis techniques and tools relevant to contemporary field development trends. Fundamental concepts will be discussed to ensure a solid foundation for understanding the applicability and limitations of the techniques presented. The learning will be supported and reinforced by examples and exercises throughout the course.

Duration and Training Method

A virtual classroom course divided into 10 three-hour webinar sessions over a two-week period (equivalent to a five-day classroom course), comprising lectures, discussion, case studies, and practical exercises to be completed by participants during and between sessions. Problems will focus on understanding the concepts and may require the use of a scientific calculator or laptop computer, but no specialized engineering software applications will be used.

Participants will learn to:

  1. Develop a robust understanding of the key concepts underpinning the practice of reservoir engineering; encompassing rock and fluid properties, and the physics of multiphase flow in porous media.
  2. Implement a range of analysis techniques to quantify recoverable volumes and productivity of oil, gas, and gas-condensate wells and reservoirs.
  3. Expand traditional techniques to provide familiarity and understanding of more contemporary reservoir analysis for improved and enhanced recovery techniques, and resource-play reservoirs.
  4. Determine the parameters for resource classification.
  5. Assess and apply techniques to assess Reserves volumes.
  6. Illustrate the appropriate uses of reservoir simulation and provide practical guidelines for planning reservoir modelling studies.
  • Fundamentals
    • Reservoir description (reservoir architecture, porosity and permeabiilty, distribution of properties)
    • Fluid properties (sampling, composition, phase behaviour, PVT studies, EoS modelling and characterisation)
    • Fluid distribution (pressure vs. depth, capillary pressure, wettability, contacts)
  • Fluid flow in porous media
    • Darcy's Law and flow potential (the 3 forces)
    • Diffusivity equation (steady state flow, transient flow, pseudosteady state flow)
    • Superposition
    • Relative permeability
  • Well performance
    • Inflow performance (radial flow, productivity index, skin, coning/cusping, horizontal wells, vertical lift)
    • Well testing (objectives, test types, after-flow, flow regimes for different well types, analysis techniques, gas well testing)
    • Rate-time Analysis (RTA) techniques
  • Resource estimates
    • Resource and reserves definitions (reserves vs. resources, SPE/PRMS classification, other classification systems, level of uncertainty)
    • Probabilistic estimates (proven, probable, possible, P90/P50/P10)
    • Estimation techniques (volumetrics, analogues, recovery factors, well drainage limits, decline curve analysis, material balance, simulation)
  • Drive mechanisms & evaluation techniques
    • Oil reservoirs (fluid expansion and introduction to material balance, alternative depletion mechanisms)
    • Material balance applied to oil reservoirs
    • Immiscible displacement (waterflood)
    • Fractured reservoirs
    • Gas reservoirs (dry/wet gas, difference in approach to development, alternative depletion mechanisms)
    • Material balance applied to gas reservoirs
    • Gas-condensate reservoirs (differences with dry/wet gas reservoirs, alternative depletion mechanisms)
    • Material balance of gas-condensate reservoirs, and recovery factors
    • 'Resource plays' (shale gas, tight oil and gas, analysis and performance prediction techniques)
  • Improved/Enhanced Oil Recovery (IOR/EOR)
    • IOR categories (infill recovery, miscible gas injection, chemical floods, thermal techniques)
    • Screening and analysis of alternative techniques
  • Reservoir simulation
    • Principles of simualtion (finite-difference, streamline, alternative simulator types, input data, well models, history matching)
    • Practice of simulation (integration of disciplines, objectives, multi-scale modelling, reservoir modelling process, dealing with uncertainty)
    • Upscaling (levels of scale, representativeness, pseudo-relative permeability)

Who should attend

The course is designed to provide practicing mid- to senior-level engineers with a fuller understanding of the basis and applicability of their engineering work and to introduce additional approaches to their reservoir analyses. Manages and team leaders could also benefit from exposure to applied reservoir engineering topics.

Prerequisites and linking courses

A basic understanding of engineering and physical principles is assumed. Some working experience in general reservoir engineering is recommended.

Related Nautilus Training Alliance courses include N484 (Reservoir Management for Unconventional Oil and Gas Resources), N986 (Reservoir and Production Engineering of Resource Plays), N406 (Unconventional Resource Assessment and Valuation), and N957 (Forecasting Production and Estimating Reserves in Unconventional Reservoirs).

Click on a name to learn more about the instructor

Jerry Hadwin

Dates for this Course

LOGIN TO BOOK A COURSE

Virtual

Date:
6 Dec. 2021
Event Code:
D997a21VC
Fee:
USD $4,860 (Exclusive of tax)

Related Subjects

It seems many courses relating to reservoir engineering tend to cover the same topics. This course did a good job of combining all the courses into one. It was efficient and more with reality. The instructor provided exercises that were applicable to many areas.