3D Printing Geological Models For Education, Research, and Technical Communication - 3D Printing as an Emerging Technology in Geosciences
By: Prof. Dr Franciszek Hasiuk & Dr Sergey Ishutov
Prof. Dr Franciszek Hasiuk (Iowa State University) &
Dr Sergey Ishutov
(University of Alberta)
4 - 7 May 2021;
9:00AM -1:00PM CET
4 hours/day
Reservoir Characterization – Rock Physics
This course is part of the EAGE Education Tours (EET), the flagship education programme of the Association. EET courses are specifically designed to bring members the latest developments in geoscience and engineering through experienced instructors from industry and academia. In 2020 we are proud to introduce EET courses that can be attended remotely over two half-day sessions. Participants will have the possibility to interact live with the instructor and ask questions. EET courses are supported by the EAGE Education Fund for the benefit of members, who can register for special discounted fees.
3D printing is an emerging technology in the geosciences that provides a fast, cost-effective way to transform digital designs into tangible models. These tangible models enable a physical representation of 3D geometries and enhance communication among researchers, students, technical management, and non-experts. Whereas digital models can be viewed only on a screen, a 3D printed model can be experienced with other senses: it can be viewed at different light angles and manipulated. For research purposes, 3D-printed models can be experimented with in the laboratory to validate numerical predictions of rock properties.
The course is designed in two days to cover broad topics related to various 3D printing applications. Day 1 provides an overview of different 3D printing techniques that use both rock-like materials (e.g., sand, gypsum, clay) and polymers (e.g., plastics, resins). While these cost-effective methods are shaping the future of manufacturing, 3D printing geological media requires profound understanding of capabilities and limitations of each technique and its material properties. Day 1 includes a module on how to digitally design and 3D print models for use in reservoir rock analysis, geomorphology, and paleontology. For reservoir rock analysis, 3D printing of near-identical rock proxies provides an approach to conduct repeatable laboratory experiments without destroying natural rock samples. The course also discusses case studies of 3D printing applications in the geoscience and engineering research as well as in the petroleum industry. Participants will learn how to deploy 3D-printed models to improve technical communication to diverse audiences (e.g., engineers, managers, community stakeholders). The integration of digital data sets with 3D-printed surface and subsurface features will help participant to learn about communication for societal objectives. Discussion of 3D printing as a teaching tool will help students and educators to understand the practical approaches of using 3D-printed models in explaining complex concepts and 3D data. The course will provide insights on future implementation of 3D printing techniques in geosciences, including reduced costs of 3D printers, open-source software, and free access to digital model repositories.
Day 2 involves practical components of using 3D printing for characterization of reservoir rocks and geomorphic features. 3D-printed porous and fracture models are used to investigate fundamental research questions in the areas of single and multiphase fluid flow as well as reactive transport in reservoir sandstones and carbonate rocks. Participants will design 3D-printable models containing pore and fracture networks using CAD and computed tomography data. They will have an opportunity to manufacture their models with local 3D printing shops. In addition, participants will be provided with pre-printed replicas equivalent to their digital models to investigate the fidelity of 3D printing techniques and materials. Participants will learn how 3D-printed models can be used in destructive and non-destructive analyses to study geomechanical and transport properties (e.g., porosity, pore sizes, grain sizes, fracture apertures, connectivity of pore and fracture networks). Participants will also gain experience with TouchTerrain app that allows to generate 3D-printable terrain models with no CAD or GIS software.
On completion of the course, participants will be able to:
The course is designed in 2 days to accommodate a broad range of participant groups. Day 1 of the course covers overview of 3D printing techniques and methods and is intended for general audience. It is useful for students, geoscientists, engineers, who are interested in current advances of 3D printing in research and teaching. It can also be beneficial for managers and stakeholders who want to learn the use of 3D printing in technical communications. Day 2 covers research applications of 3D printing in porous media and geomorphology and involves practical section on creating 3D-printable models of reservoir rocks and terrains. It is beneficial for geologists, petrophysicists, stratigraphers, geophysicists, geomorphologists, reservoir and geomechanical engineers and geomodellers from both industry and academia who are interested in transforming digital models into tangible objects that can be viewed, touched, manipulated, and tested in the lab as natural rocks. Participants will receive hand-on experience on creating digital rock and terrain models, validating their accuracy and exploring the best methods to 3D print them. In addition, day 2 of the course will involve review of current advances in research on 3D printing reservoir rock models that involves investigation of petrophysical and geomechanical properties of 3D-printed rock analogues. Skills obtained during day 1 will allow participants to be engaged in day 2 activities without prerequisites. If participants take only day 2, basic knowledge about major 3D printing techniques and materials as well as CAD modeling and computed tomography is required.
Prior knowledge of CAD modeling and interpretation of computed tomography data would be useful, but is not required
Prof. Dr. Franek Hasiuk, Associate Scientist at the Kansas Geological Survey, is an expert in carbonate geology and 3D printing. His dissertation from the University of Michigan involved understanding the secular variation of seawater chemistry and temperature from marine carbonate chemistry. He worked at ExxonMobil Upstream Research for four years where he developed a deep appreciation for carbonate petrophysics while working on a variety of projects including a global synthesis of carbonate microporosity. The mission of his "GeoFabLab" has been to better understand the chemistry and petrophysics of rocks by using 3D-printed rock models as well as man-made rocks, like concrete and asphalt.
Dr. Sergey Ishutov, researcher is an expert in 3D printing porous media from CAD and tomographic models. He is currently a researcher at the University of Alberta working on digital and experimental analysis of transport and geomechanical properties of 3D-printed porous models at nano-, micro- and macro-scales. He has received B.Sc. in petroleum geology from the University of Aberdeen in Scotland and M.Sc. in geology from California State University Long Beach. His research experience is in acquisition, processing, and interpretation of seismic data and analysis of computed tomography data from reservoir core plugs. Dr. Ishutov received multiple awards and research grants from professional societies and industry collaborators to establish foundation research in 3D printing reservoir rock samples. He has work experience at major petroleum companies, including ExxonMobil, Aramco, and Shell.