Related Datasets

Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS

DOI 10.15121/1148805

Publicly accessible License

EGS field projects have not sustained production at rates greater than half of what is needed for economic viability. The primary limitation that makes commercial EGS infeasible is our current inability to cost-effectively create high-permeability reservoirs from impermeable, igneous rock within the 3,000-10,000 ft depth range.
Our goal is to develop a novel fracturing fluid technology that maximizes reservoir permeability while reducing stimulation cost and environmental impact. Laboratory equipment development to advance laboratory characterization/monitoring is also a priority of this project to study and optimize the physicochemical properties of these fracturing fluids in a range of reservoir conditions. Barrier G is the primarily intended GTO barrier to be addressed as well as support addressing barriers D, E and I.

Acoustic emission setup.jpg

Acoustic analysis setup for in operando monitoring of fracturing processes

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Final High P&T PAA_NMR_rev2a.pptx

NMR spectra showing speciation of our polymer with CO2 but limited to 150C and 130 atm

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Fracturing high P&T system.jpg

High P/T fracturing system

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NMR capability and needs.pptx

NMR instrumentation and high P/T rotors for chemical speciation analysis of our fracturing fluid in operando

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PAA Recycling.jpg

Recycling fracturing fluid demo

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PAA Rheology vs T and P.jpg

Demonstration of volume expansion of our fracturing fluid

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Pics of four Coso samples subjected to 7 atm CO2 pressure.jpg

Images of fractured rock from Coso geothermal site using our fluid technology

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Pics of two PAA-fractured Coso samples subjected to KI seepage.jpg

Images of fractured rock from Coso geothermal site using our fluid technology

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Pics vs time of PAA-fractured Coso 1-2 sample subjected to KI seepage.jpg

Images of Ki seepage analysis on fractured rock from Coso geothermal site using our fluid technology

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Pulse echo Setup and Data report 3-7-13 final.docx

Report on Pulse Echo Analysis data on rock samples previous to fracturing to learn about the potential of this technique for in operando acoustic monitoring of fracturi... more

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Rheology 3-window cell.jpg

High P&T cell and system for rheology studies

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Rheology high P&T system.jpg

High P/T system schematic

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Rheometer system.jpg

Rheorimeter for viscosity analysis as a function of P, T and shear rate

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Viscosity Test-2_Results PAA.xlsx

Viscosity as a function of P on our proposed fracturing fluid

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Viscosity Test-3_Results Xanthan.xlsx

Viscosity versus P on xanthan solution

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Viscosity Test-4_Results-SDS.xlsx

Viscosity versus P on SDS solution

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XMT showing local fractures created by PAA on Coso 1-2.jpg

XMT image showing a 3D local fracture generated on highly crystalline rock using our fracturing fluid technology

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XMT summary of four fracturing experiments.docx

Summary of XMT images as well as photographs of rock samples from Coso Geothermal site using our fluid technology as compared to other common fluids

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water-CO2 control.jpg

Viscosity versus P on water

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Citation Formats

Pacific Northwest National Laboratory. (2013). Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS [data set].  Retrieved from https://dx.doi.org/10.15121/1148805.

Export Citation to RIS

A., Carlos. Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS. United States: N.p., 25 Sep, 2013. Web. doi: 10.15121/1148805.

A., Carlos. Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS. United States. https://dx.doi.org/10.15121/1148805

A., Carlos. 2013. "Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS". United States. https://dx.doi.org/10.15121/1148805. https://gdr.openei.org/submissions/258.

@div{oedi_3103, title = {Reservoir Stimulation Optimization with Operational Monitoring for Creation of EGS}, author = {A., Carlos.}, abstractNote = {EGS field projects have not sustained production at rates greater than half of what is needed for economic viability. The primary limitation that makes commercial EGS infeasible is our current inability to cost-effectively create high-permeability reservoirs from impermeable, igneous rock within the 3,000-10,000 ft depth range. 

Our goal is to develop a novel fracturing fluid technology that maximizes reservoir permeability while reducing stimulation cost and environmental impact. Laboratory equipment development to advance laboratory characterization/monitoring is also a priority of this project to study and optimize the physicochemical properties of these fracturing fluids in a range of reservoir conditions. Barrier G is the primarily intended GTO barrier to be addressed as well as support addressing barriers D, E and I.

}, doi = {10.15121/1148805}, url = {https://gdr.openei.org/submissions/258}, journal = {}, number = , volume = , place = {United States}, year = {2013}, month = {09}}

https://dx.doi.org/10.15121/1148805

Details

Data from Sep 25, 2013

Last updated May 30, 2017

Submitted Oct 17, 2013

Organization

Pacific Northwest National Laboratory

Contact

Carlos A. Fernandez

509.375.2121

Authors

Carlos A.

Pacific Northwest National Laboratory

Original Source

https://gdr.openei.org/submissions/258

Research Areas

Geothermal Energy

Keywords

geothermal, fracturing fluid, monitoring, XMT, NMR, Acoustic, rheology, permeability, EGS, igneous rock

DOE Project Details

Project Lead William Vandermeer

Project Number FY13 AOP 25726