Top
International Journal of Petroleum Technology
You are here: Archives/Articles/Vol. 4

Optimization of Hydrocarbon Production from Unconventional Shale Reservoirs using Numerical Modelling

Authors

J. Will , S. Eckardt

Files

PDF

Key Information

Published

July 25, 2017

Journal

Published in Vol. 4 (2017) of International Journal of Petroleum Technology.

The International Journal of Petroleum Technology (IJPT) is the go-to resource for researchers, academics, and practitioners seeking to stay on the cutting edge of the rapidly evolving field of petroleum technology. This interdisciplinary, peer-reviewed platform is dedicated to publishing research and development works of the highest technical standards, with an appropriate balance of practice and theory across the broad topics of Petroleum and Oil Technology.

IJPT encourages original research articles and insightful reviews in all aspects of the field, with a particular emphasis on the following areas of interest: Production of hydrocarbons, Petroleum Exploration (Drilling, Production and Flow), Single and Multiphase Fluid Flows in Porous Media, Physical-Chemical Properties and Rheological Behaviour, Petroleum Geochemistry, Petro Physics, Petroleum Economics, Petroleum Geology, Oil Refining and Process Engineering, Synthetic Fuel Technologies, Oil Shale Technology, Drilling, and Drilling Fluids.

In addition to providing cross-learning between scientific and technological realms, IJPT also takes into account the public's concerns regarding environmental, health, and safety issues. This includes original investigations focused on the multiscale approach of the modern, sustainable green petroleum and oil technology that is set to be encountered in the factory of the future. Process intensification that requires new green technologies such as catalysts, green solvents, exchangers, reactors, and separation equipment is also covered in IJPT.

About the Journal

How to Cite

1.
Optimization of Hydrocarbon Production from Unconventional Shale Reservoirs using Numerical Modelling. Int. J. Pet. Technol. [Internet]. 2017 Jul. 25 [cited 2026 May 7];4:14-23. Available from: https://www.avantipublishers.com/index.php/ijpt/article/view/812

Abstract

 The success of unconventional hydrocarbon extraction depends on the effective stimulation of reservoir rocks. Industry practice is to conduct a large number of field trials requiring high capital investment and long cycle-time. The workflow outlined in this paper, using best available reservoir data in combination with best available simulation models offer a cheaper and faster alternative approach for optimization of the complete design and for the improvement of production. Integrating subsurface characteristics, well completion, well operation, diagnostic and well performance analysis by using asset specific data, the development of an optimal completion design is possible. This results in the reduction of field trials, which is primarily necessary for achieving the optimal completion design. In addition, it provides valuable insights for further data acquisition to evaluate and forecast performance of the well. This paper introduces the workflow to model, calibrate and optimize the landing and orientation of the well including hydraulic fracturing stimulation design for naturally fractured unconventional shale reservoirs. For fracture simulation, the paper introduces an approach for parametric coupled hydro-mechanical 3D Finite Element (FEM) modeling, including non-linear material modeling of fracture propagation in sedimentary rocks. In order to calculate production out of the created fracture network, estimation of accessible connected hydrocarbons is calculated. For calibration and optimization purposes, automated sensitivity studies for uncertainty variations of the reservoir parameters as well as engineering and operational parameters are performed and are evaluated relative to the resulting Stimulated Reservoir Volume (SRV), Accessible Hydrocarbon initially in Place (AHCIIP) and Estimated Ultimate Recovery (EUR). The current version of this technology does not handle proppant transport and placement. Instead, assumptions are made for proppant acceptance in the fracture network and used in estimating the proppant accepting simulated rock volume, connected hydrocarbons, and hydrocarbon production. Further enhancement of the FEM workflow to capture 3D proppant transport and placement is under development and will be a major update in the upcoming hydraulic fracture simulator version.
PDF

References

ANSYS, Inc., ANSYS®, Release 17, Canonsburg, PA, 2016.

Dynardo GmbH, 3D Hydraulic fracturing simulator, version 3.7.4, documentation.ppt, Weimar, 2016.

Dynardo GmbH, optiSLang® - The optimizing structural language, Version 5.1, Weimar, 2016.

L. Weijers. Evaluation of oil industry stimulation practices for Engineered Geothermal Systems, Pinnacle Report DOEPS36- 04GO94001,“ October 2007.

M. G. Zielonka, K. H. Searles, J. Ning and S. R. Buechler, Development and validation of fully-coupled hydraulic fracturing simulation capabilities, in 2014 Simulia Community Conference, 2014.

W. Wittke, Felsmechanik: Grundlagen für wirtschaftliches Bauen im Fels, Springer-Verlag, 1984. https://doi.org/10.1007/978-3-642-52235-2 DOI: https://doi.org/10.1007/978-3-642-52235-2

T. Bai, J. Will, et al. Hydraulic modeling workflow and toolkits for well completion optimization in Unconventionals. SPE 179137 Hydraulic Fracturing Conference in Woodlands in USA 2016. DOI: https://doi.org/10.2118/179137-MS

J. Will, Beitrag zur Standsicherheitsberechnung im geklüfteten Fels in der Kontinuums- und Diskontinuumsmechanik unter Verwendung impliziter und expliziter Berechnungsstrategien, in Berichte des Institutes für Strukturmechanik 2/99, Dissertation, Bauhaus Universität Weimar, 1999.

R. Schlegel, J. Will and M. Jobmann, Using statistical methods for rock parameter identification to analyse the THM behaviour of Callovo-Oxfordian claystone, in Second EAGE Workshop on Geomechanics and Energy, Celle, 13-15 October 2015. https://doi.org/10.3997/2214-4609.201414298 DOI: https://doi.org/10.3997/2214-4609.201414298

T. Most and J. Will. Efficient sensitvity analysis for virtual prototyping, in Proceedings of the 6th European Congress of Computational Methods in Applied Sciences and Engineering, Vienna, 2012.

Y. Gao, R. Yuan, J. Will, T. Bai, et al. An integrated Geomechanics-Reservoir modeling workflow for Hydraulic Fracturing optimisation and EUR prediction for a shale gas play in Sichuan Basin; SPE 181801, Asia Pacific Hydraulic Fracturing Conference 2016. https://doi.org/10.2118/181801-MS DOI: https://doi.org/10.2118/181801-MS

Venkat S, Eckardt S, Will J. Simulation of penny shaped fracture using homogenized continuum approach; Proceedings Weimarer Optimierung- und Stochastiktage 2015, Weimar, Germany (www.dynardo.de).

Ranjan A, Eckardt S, Will J. Simulation of fracture design generation, production characteristics and temperature development of a Hot Dry Rock Geothermal Reservoir; Proceedings Weimarer Optimierung- und Stochastiktage 2015, Weimar, Germany.

Downloads

Download data is not yet available.

Details

Published

July 25, 2017

Issue

Vol. 4 (2017)

Section

Articles

How to Cite

1.
Optimization of Hydrocarbon Production from Unconventional Shale Reservoirs using Numerical Modelling. Int. J. Pet. Technol. [Internet]. 2017 Jul. 25 [cited 2026 May 7];4:14-23. Available from: https://www.avantipublishers.com/index.php/ijpt/article/view/812

Pages

14-23

License

All the published articles are licensed under the terms of the Creative Commons Attribution Non-Commercial License (CC BY-NC 4.0) which permits unrestricted, non-commercial use, distribution and reproduction in any medium, provided the work is properly cited.

Similar Articles

1-10 of 64

You may also start an advanced similarity search for this article.

Back to Top