Integrated research & development for advancing EGS commercialization - Tipping the scales

EGS Collab Team

Integrated research & development for advancing EGS commercialization - Tipping the scales

EGS Collab Team

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Fundamental to successful commercial scale enhanced geothermal systems (EGS) operations is the ability to maintain both fluid temperatures and flow rates at sufficiently high levels and durations to provide a return on investment. The persistence of such operational conditions will be required for many years to decades. Confidence in long term EGS performance is not yet sufficient to justify the level of private capital investment required for widespread commercialization. While a number of technical and non-technical barriers exist, we believe that a fundamental obstacle to establishing confidence is the lack of data associated with long-term thermal-flow performance of EGS. Data collected from long-term circulation tests are needed to validate model predictions and reduce uncertainties in predicted economic outcomes. Without these well-validated predictive modeling tools, long-term reservoir management will be fraught with uncertainties and this will hinder capital investment in EGS. Therefore, we postulate that understanding long term EGS reservoir performance and evolution requires datasets, initially from experimental demonstrations but ultimately from commercial-scale EGS sites, and validated modeling suites. We note here that similar tools and techniques, proposed herein, have become invaluable in the petroleum industry where dynamic reservoir characterization is used in the long-term management and optimization of oil and gas recovery. Techno-economic analyses have also been performed for EGS but owing to the dearth of available long-term performance data, their validity has not yet been demonstrated. In this paper, we discuss the potential for carefully scaled intermediate-scale field experiments that can serve as a time and cost-effective step toward building the necessary technical basis for validating predictive modeling tools. It is widely accepted that integration of laboratory, intermediate-scale, and field-scale efforts can be an important framework for lowering overall R&D costs, accelerating technology development timelines, reducing risks, and ultimately achieving the goal of commercializing EGS. We show here that an important step in developing those linkages lies in fundamental physical and dimensional analysis, and that with careful implementation seemingly intractable challenges of decoupling phenomena can be overcome.

Original language	English
Title of host publication	Using the Earth to Save the Earth - 2021 Geothermal Rising Conference, GRC 2021
Publisher	Geothermal Resources Council
Pages	736-747
Number of pages	12
ISBN (Electronic)	0934412278
State	Published - 2021
Event	2021 Geothermal Rising Conference: Using the Earth to Save the Earth, GRC 2021 - San Diego, United States Duration: Oct 3 2021 → Oct 6 2021

Publication series

Name	Transactions - Geothermal Resources Council
Volume	45
ISSN (Print)	0193-5933

Conference

Conference	2021 Geothermal Rising Conference: Using the Earth to Save the Earth, GRC 2021
Country/Territory	United States
City	San Diego
Period	10/3/21 → 10/6/21

Funding

This material was based upon work supported by the U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy (EERE), Office of Technology Development, Geothermal Technologies Office. Sandia National Laboratories is a multi-mission laboratory managed and operated by National Technology & Engineering Solutions of Sandia, LLC, a wholly owned subsidiary of Honeywell International Inc., for the U.S. Department of Energy’s National Nuclear Security Administration under contract DE-NA0003525. The United States Government retains, and the publisher, by accepting the article for publication, acknowledges that the United States Government retains a non-exclusive, paid-up, irrevocable, world-wide license to publish or reproduce the published form of this manuscript, or allow others to do so, for United States Government purposes. This material was based upon work supported by the U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy (EERE), Office of Technology Development, Geothermal Technologies Office. Sandia National Laboratories is a multi-mission laboratory managed and operated by National Technology & Engineering Solutions of Sandia, LLC, a wholly owned subsidiary of Honeywell International Inc., for the U.S. Department of Energy's National Nuclear Security Administration under contract DE-NA0003525. The United States Government retains, and the publisher, by accepting the article for publication, acknowledges that the United States Government retains a non-exclusive, paid-up, irrevocable, world-wide license to publish or reproduce the published form of this manuscript, or allow others to do so, for United States Government purposes.

Keywords

Collab
Enhanced Geothermal Systems
Geothermal
Hydraulic Fracture
Intermediate Scale Experimentation

Cite this

@inproceedings{ff2113b9fae547c0818df5b236b575d8,

title = "Integrated research & development for advancing EGS commercialization - Tipping the scales",

abstract = "Fundamental to successful commercial scale enhanced geothermal systems (EGS) operations is the ability to maintain both fluid temperatures and flow rates at sufficiently high levels and durations to provide a return on investment. The persistence of such operational conditions will be required for many years to decades. Confidence in long term EGS performance is not yet sufficient to justify the level of private capital investment required for widespread commercialization. While a number of technical and non-technical barriers exist, we believe that a fundamental obstacle to establishing confidence is the lack of data associated with long-term thermal-flow performance of EGS. Data collected from long-term circulation tests are needed to validate model predictions and reduce uncertainties in predicted economic outcomes. Without these well-validated predictive modeling tools, long-term reservoir management will be fraught with uncertainties and this will hinder capital investment in EGS. Therefore, we postulate that understanding long term EGS reservoir performance and evolution requires datasets, initially from experimental demonstrations but ultimately from commercial-scale EGS sites, and validated modeling suites. We note here that similar tools and techniques, proposed herein, have become invaluable in the petroleum industry where dynamic reservoir characterization is used in the long-term management and optimization of oil and gas recovery. Techno-economic analyses have also been performed for EGS but owing to the dearth of available long-term performance data, their validity has not yet been demonstrated. In this paper, we discuss the potential for carefully scaled intermediate-scale field experiments that can serve as a time and cost-effective step toward building the necessary technical basis for validating predictive modeling tools. It is widely accepted that integration of laboratory, intermediate-scale, and field-scale efforts can be an important framework for lowering overall R&D costs, accelerating technology development timelines, reducing risks, and ultimately achieving the goal of commercializing EGS. We show here that an important step in developing those linkages lies in fundamental physical and dimensional analysis, and that with careful implementation seemingly intractable challenges of decoupling phenomena can be overcome.",

keywords = "Collab, Enhanced Geothermal Systems, Geothermal, Hydraulic Fracture, Intermediate Scale Experimentation",

author = "{EGS Collab Team} and Chris Strickland and Jeff Burghardt and Hunter Knox and Pengcheng Fu and Paul Schwering and Tim Johnson and Tim Kneafsey and J. Ajo-Franklin and Bauer, {S. J.} and T. Baumgartner and K. Beckers and D. Blankenship and A. Bonneville and L. Boyd and Brown, {S. T.} and Burghardt, {J. A.} and T. Chen and Y. Chen and K. Condon and Cook, {P. J.} and Dobson, {P. F.} and T. Doe and Doughty, {C. A.} and D. Elsworth and J. Feldman and A. Foris and Frash, {L. P.} and Z. Frone and P. Fu and K. Gao and A. Ghassemi and H. Gudmundsdottir and Y. Guglielmi and G. Guthrie and B. Haimson and A. Hawkins and J. Heise and Herrick, {C. G.} and M. Horn and Horne, {R. N.} and J. Horner and M. Hu and H. Huang and L. Huang and K. Im and M. Ingraham and Johnson, {T. C.} and B. Johnston and M. MacEira and Y. Polsky",

note = "Publisher Copyright: Copyright {\textcopyright} 2021 Geothermal Rising.; 2021 Geothermal Rising Conference: Using the Earth to Save the Earth, GRC 2021 ; Conference date: 03-10-2021 Through 06-10-2021",

year = "2021",

language = "English",

series = "Transactions - Geothermal Resources Council",

publisher = "Geothermal Resources Council",

pages = "736--747",

booktitle = "Using the Earth to Save the Earth - 2021 Geothermal Rising Conference, GRC 2021",

}

EGS Collab Team 2021, Integrated research & development for advancing EGS commercialization - Tipping the scales. in Using the Earth to Save the Earth - 2021 Geothermal Rising Conference, GRC 2021. Transactions - Geothermal Resources Council, vol. 45, Geothermal Resources Council, pp. 736-747, 2021 Geothermal Rising Conference: Using the Earth to Save the Earth, GRC 2021, San Diego, United States, 10/3/21.

Integrated research & development for advancing EGS commercialization - Tipping the scales. / EGS Collab Team.
Using the Earth to Save the Earth - 2021 Geothermal Rising Conference, GRC 2021. Geothermal Resources Council, 2021. p. 736-747 (Transactions - Geothermal Resources Council; Vol. 45).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Integrated research & development for advancing EGS commercialization - Tipping the scales

AU - EGS Collab Team

AU - Strickland, Chris

AU - Burghardt, Jeff

AU - Knox, Hunter

AU - Fu, Pengcheng

AU - Schwering, Paul

AU - Johnson, Tim

AU - Kneafsey, Tim

AU - Ajo-Franklin, J.

AU - Bauer, S. J.

AU - Baumgartner, T.

AU - Beckers, K.

AU - Blankenship, D.

AU - Bonneville, A.

AU - Boyd, L.

AU - Brown, S. T.

AU - Burghardt, J. A.

AU - Chen, T.

AU - Chen, Y.

AU - Condon, K.

AU - Cook, P. J.

AU - Dobson, P. F.

AU - Doe, T.

AU - Doughty, C. A.

AU - Elsworth, D.

AU - Feldman, J.

AU - Foris, A.

AU - Frash, L. P.

AU - Frone, Z.

AU - Fu, P.

AU - Gao, K.

AU - Ghassemi, A.

AU - Gudmundsdottir, H.

AU - Guglielmi, Y.

AU - Guthrie, G.

AU - Haimson, B.

AU - Hawkins, A.

AU - Heise, J.

AU - Herrick, C. G.

AU - Horn, M.

AU - Horne, R. N.

AU - Horner, J.

AU - Hu, M.

AU - Huang, H.

AU - Huang, L.

AU - Im, K.

AU - Ingraham, M.

AU - Johnson, T. C.

AU - Johnston, B.

AU - MacEira, M.

AU - Polsky, Y.

PY - 2021

Y1 - 2021

N2 - Fundamental to successful commercial scale enhanced geothermal systems (EGS) operations is the ability to maintain both fluid temperatures and flow rates at sufficiently high levels and durations to provide a return on investment. The persistence of such operational conditions will be required for many years to decades. Confidence in long term EGS performance is not yet sufficient to justify the level of private capital investment required for widespread commercialization. While a number of technical and non-technical barriers exist, we believe that a fundamental obstacle to establishing confidence is the lack of data associated with long-term thermal-flow performance of EGS. Data collected from long-term circulation tests are needed to validate model predictions and reduce uncertainties in predicted economic outcomes. Without these well-validated predictive modeling tools, long-term reservoir management will be fraught with uncertainties and this will hinder capital investment in EGS. Therefore, we postulate that understanding long term EGS reservoir performance and evolution requires datasets, initially from experimental demonstrations but ultimately from commercial-scale EGS sites, and validated modeling suites. We note here that similar tools and techniques, proposed herein, have become invaluable in the petroleum industry where dynamic reservoir characterization is used in the long-term management and optimization of oil and gas recovery. Techno-economic analyses have also been performed for EGS but owing to the dearth of available long-term performance data, their validity has not yet been demonstrated. In this paper, we discuss the potential for carefully scaled intermediate-scale field experiments that can serve as a time and cost-effective step toward building the necessary technical basis for validating predictive modeling tools. It is widely accepted that integration of laboratory, intermediate-scale, and field-scale efforts can be an important framework for lowering overall R&D costs, accelerating technology development timelines, reducing risks, and ultimately achieving the goal of commercializing EGS. We show here that an important step in developing those linkages lies in fundamental physical and dimensional analysis, and that with careful implementation seemingly intractable challenges of decoupling phenomena can be overcome.

AB - Fundamental to successful commercial scale enhanced geothermal systems (EGS) operations is the ability to maintain both fluid temperatures and flow rates at sufficiently high levels and durations to provide a return on investment. The persistence of such operational conditions will be required for many years to decades. Confidence in long term EGS performance is not yet sufficient to justify the level of private capital investment required for widespread commercialization. While a number of technical and non-technical barriers exist, we believe that a fundamental obstacle to establishing confidence is the lack of data associated with long-term thermal-flow performance of EGS. Data collected from long-term circulation tests are needed to validate model predictions and reduce uncertainties in predicted economic outcomes. Without these well-validated predictive modeling tools, long-term reservoir management will be fraught with uncertainties and this will hinder capital investment in EGS. Therefore, we postulate that understanding long term EGS reservoir performance and evolution requires datasets, initially from experimental demonstrations but ultimately from commercial-scale EGS sites, and validated modeling suites. We note here that similar tools and techniques, proposed herein, have become invaluable in the petroleum industry where dynamic reservoir characterization is used in the long-term management and optimization of oil and gas recovery. Techno-economic analyses have also been performed for EGS but owing to the dearth of available long-term performance data, their validity has not yet been demonstrated. In this paper, we discuss the potential for carefully scaled intermediate-scale field experiments that can serve as a time and cost-effective step toward building the necessary technical basis for validating predictive modeling tools. It is widely accepted that integration of laboratory, intermediate-scale, and field-scale efforts can be an important framework for lowering overall R&D costs, accelerating technology development timelines, reducing risks, and ultimately achieving the goal of commercializing EGS. We show here that an important step in developing those linkages lies in fundamental physical and dimensional analysis, and that with careful implementation seemingly intractable challenges of decoupling phenomena can be overcome.

KW - Collab

KW - Enhanced Geothermal Systems

KW - Geothermal

KW - Hydraulic Fracture

KW - Intermediate Scale Experimentation

UR - http://www.scopus.com/inward/record.url?scp=85120091179&partnerID=8YFLogxK

M3 - Conference contribution

AN - SCOPUS:85120091179

T3 - Transactions - Geothermal Resources Council

SP - 736

EP - 747

BT - Using the Earth to Save the Earth - 2021 Geothermal Rising Conference, GRC 2021

PB - Geothermal Resources Council

T2 - 2021 Geothermal Rising Conference: Using the Earth to Save the Earth, GRC 2021

Y2 - 3 October 2021 through 6 October 2021

ER -

Integrated research & development for advancing EGS commercialization - Tipping the scales

Abstract

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Keywords

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