D427 Reservoir Model Design
D427 Reservoir Model Design
This course offers a software-independent view on the process of reservoir model design and simulation model-building. It tackles the underlying reasons why some models disappoint and offers solutions that support the more efficient construction of fit-for-purpose models.
A virtual classroom course divided into 5 four hour webinar sessions (equivalent to a three-day classroom course), comprising of a mixture of lectures, discussion, case studies, and practical exercises to be completed by participants during and between sessions.
Considerable time is dedicated to reservoir modelling and simulation exercises in many companies but the results often disappoint: the time taken to build models is often too long, the models too detailed and cumbersome and the final model ultimately not fit-for-purpose. This course tackles the reasons why and offers remedies to fix these problems. The advice is based on the experience of the course originators, who have been involved in excess of 100 reservoir modelling and simulation projects over the last thirty years. The central theme of the course is Reservoir Model Design, on the premise that it is design rather than software knowledge that typically distinguishes ‘good models’ from ‘bad models’. This is organised around the following five themes, issues within which are often the cause of a poor model outcome:
1. Model purpose – why are we logged on in the first place and what is the question we are specifically trying to address? What do we really mean when we say 'fit for purpose?'
2. Elements and architecture – how much detail should be incorporated in the models? From the rich spectrum of potential lithofacies, electrofacies, biostratigraphic and analogue data inputs, how do we select the ‘right’ number of components (elements) to take forward into the modelling process? Once selected, how do these elements combine into a realistic description of length scales and reservoir architecture? How to capture this in an interpretative sketch which can be used as a cross-discipline communication tool.
3. Probability and determinism – is the balance of probabilistic and deterministic components appropriate given the model purpose? Should heterogeneities be handled implicitly or explicitly in the static and dynamic models and if implicitly, then how should we average properties? What are our expectations of geostatistics and how do we control the algorithms intuitively to replicate a sketched reservoir concept? This applies both to modelling of the matrix and also fractures, and we explore how we can use well test data to place deterministic constraints on our models.
4. Multi-scale modelling – what scale should we be modelling and simulating at given the fluid type and model purpose? Can everything be modelled at one scale, or are static/dynamic multi-scale models required? We address the full spectrum of heterogeneity using the concept of Representative Elementary Volumes and conclude that traditional static-dynamic upscaling is only part of the story, and not always the main part. Illustrations of fine-scale 'Ultimate Truth' models will be used to illustrate where we sometimes go wrong with over-simplifying a design.
5. Model-based uncertainty-handling – how to really go wrong. What are the tools we can use to identify natural bias in the modelling process and select workflows which capture useful ranges in a practical way, minimising bias in the process? We summarise the current range of stochastically- and deterministically-led options, including the current trend to 'ensemble' modelling, and discuss which techniques are appropriate to use, and when, and how to post-process the results and communicate them usefully to colleagues.
The ideal delegate group is a blend of geoscientists, petrophysicists, and engineers. It is highly valuable if geoscientists, petrophysicists and reservoir engineers working together in asset teams are able to join the class together.
Some practical experience of reservoir modeling and simulation software is assumed. For those looking to apply and build upon the learnings of this course, attendance on N012 (Reservoir Modelling Field Class, Utah, USA) and/or N033 (Characterisation, Modelling, Simulation and Development Planning in Deepwater Clastic Reservoirs, Tabernas, Spain) is recommended.
Click on a name to learn more about the instructor
Mark has 33 years industry experience, initially as a production geologist with Shell, working in the UK, Oman and the Netherlands and subsequently training and consulting with TRACS. He has spent most of his career working in integrated study teams on a wide variety of reservoir assets. His specialist fields of expertise are 3D reservoir modeling and scenario-based approaches to handling subsurface uncertainty and risk. He publishes widely on the topic and co-authored the reference text 'Reservoir Model Design' with Phil Ringrose.
In addition to his role as Training Director at AGR TRACS, he is also an Associate Professor in the Institute of GeoEnergy Engineering at Heriot-Watt University, holding a Chair in the field of Mature Field Management.
Affiliations and Accreditation
PhD University College of Wales, (Aberystwyth) - Structural Geology
BSc University College of Wales, (Aberystwyth) - Geology
Fellow of the Geological Society, London
Fellow of the Society of Petroleum Engineers
N033: Characterisation, Modelling, Simulation and Development Planning in Deepwater Clastic Reservoirs (Tabernas, Spain)
N106: Advanced Reservoir Modelling (Elgin, Scotland)
N310: Carbonate Reservoir Modelling and Field Development Planning (Provence, France)
N356: Production Geoscience (Pembrokeshire, UK)
N386: Reservoir Model Design (Pembrokeshire, UK)
N427: Reservoir Model Design, classroom based
N431: Reservoir Modelling of Deepwater Clastic Systems (Gres d’Annot, SE France)
D427: Reservoir Model Design (Distance Learning)
N444: Development Planning For Mature Fields
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