Title: |
Active Tracers for Hydraulic Control of Cooled Short Circuits: Bench-Scale Demonstration and Numerical Simulation |
Authors: |
Adam HAWKINS, Dani TANG, Aaron BAXTER, Reeby PUTHUR, Daniel KORZUKHIN, Zach ZODY, Bryan ABDULAZIZ, Patrick FULTON, Sarah HORMOZI, Chris ALABI, Uli WIESNER, Jefferson TESTER |
Key Words: |
tracer, numerical simulation, laboratory experiment, hydraulic control, short circuits, premature thermal breakthrough |
Conference: |
Stanford Geothermal Workshop |
Year: |
2024 |
Session: |
Emerging Technology |
Language: |
English |
Paper Number: |
Hawkins |
File Size: |
1414 KB |
View File: |
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Commercially-successful geothermal systems require balance between thermal and hydraulic performance. An injector-producer well pair with exceptional hydraulic performance, for instance, may have inadequate thermal performance if the effective heat transfer surface area is insufficient. In such a circumstance the current state-of-the-art is to abandon such well pairs once production well temperatures fall below design/operating criteria. Here, an “active” tracer is introduced as a novel solution that enables cooled “short circuits” to be sealed off and circulating fluids to be redirected to hotter flow paths. This treatment increases the effective heat transfer area and subsequently improves thermal performance by increasing production well temperatures. Bench-scale laboratory experiments are presented and the anticipated improvement to thermal performance is determined from a hypothetical case.
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