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1 | US DOE Geothermal Program eere.energy.gov
Public Service of Colorado Ponnequin Wind Farm
Geothermal Technologies Program 2010 Peer Review
Imaging Fluid Flow in Geothermal Wells Using Distributed Thermal Perturbation Sensing
Barry FreifeldLawrence Berkeley National LaboratoryHigh Temperature Tools and Drilling
May 18, 2010
This presentation does not contain any proprietary confidential, or otherwise restricted information.
DTPS Images Courtesy GeoForschungsZentrum, Potsdam
2 | US DOE Geothermal Program eere.energy.gov
• Timeline – Project start – April 2010 – Project end – September 2011
• Budget – Total project funding $400K, DOE share $400K, – Funding for FY10 $196K, DOE share $196K
• Barriers– “High temperature instrumentation for borehole imaging and
other purposes is a key technology deficiency” (From multi-year RD&D Plan)
• Partners– High temperature hybrid cable manufacturer (contracting is
in process)
Project Overview
3 | US DOE Geothermal Program eere.energy.gov
Relevance/Impact of Research
Project Objective – A New Geothermal Well Imaging Tool
1. To develop a robust and easily deployable DTPS for monitoring in geothermal wells, and
2. Develop the associated analysis methodology for flow imaging, and—when possible by wellbore conditions—to determine in situ thermal conductivity and basal heat flux.
• DTPS will permit the quantitation of flow distribution within a well and provide
• Cost effective methodology for thermal and hydrological property evaluation
4 | US DOE Geothermal Program eere.energy.gov
Scientific/Technical Approach
• What is a Distributed Thermal Perturbation Sensor (DTPS)?
Temperature
Dep
th
Electrical GeneratorOr Grid Power
Fiber-optic DTSEnergy Meter
Line Source Heater
5 | US DOE Geothermal Program eere.energy.gov
Scientific/Technical Approach
• DTPS Low Temperature Examples – Yucca Mountain, Nevada
28
30
32
34
36
38
110 160 210 260 310 360
Depth (m)
Tem
p (d
egC
)
Cooling Series
Open Wellbore Data
Other examples at CO2SINK, Ketzin GermanyHigh Lake Site, Nunuvut Territory, Canada
6 | US DOE Geothermal Program eere.energy.gov
DTPS Data Reduction Example –CO2SINK
0
0.5
1
1.5
2
2.5
3
0.00E+00 1.00E+05 2.00E+05 3.00E+05 4.00E+05 5.00E+05time (s)
∆T
(o C)
561.6 λt=3.91±0.06 W/mK561.6 m data 625.3 λt=2.42±0.03 W/mK625.3 m data646.5 λt=1.74±0.02 W/mK646.5 m data
Data used for estimating λtherm
Well logs for Ktzi201 and Ktzi202 showing temperature changes (dT) during DTPS heating and calculated thermal conductivities (TC) along with well layouts and lithologies [after Förster et al., GHGT-9, 2008].
7 | US DOE Geothermal Program eere.energy.gov
Scientific/Technical Approach
• Thermal Logging at Groß Schönebeck, Germany 100 m3 cold water injection post-stimulation. (courtesy J. Henninges & E. Huenges)
Left: Colormap plot of DTS temperatures (left) and temperature logs (Henninges et al., 2005). • A = baseline after opening of well (Oct. 2001)• B = before massive stimulation (Nov. 4, 2003)• C = after cold water injection (Mar. 5, 2004)• D = Apr. 28, 2004Hydraulic active zones are denoted as Ia, Ib, and II.
8 | US DOE Geothermal Program eere.energy.gov
Example of DTS Imaging from Ikeda
“fiber-optic distributed temperature log, when it is properly deployed, literally can visualize the fluid movement occurring in wellbore, which consequently makes it easier to diagnose what is behind causing such phenomena”…Ikeda, 28th Stanford Workshop on Geothermal Res. Eng.
9 | US DOE Geothermal Program eere.energy.gov
Accomplishments, Expected Outcomes and Progress
• We have started the design process and scoping studies for prototype fabrication of a mid-temperature geothermal DTPS cable
• Future work - numerical sensitivity studies using existing data sets to determine applications and limitations of the proposed method
0
0.25
0.5T: 36.0 36.5 37.0 37.5 38.0 38.5 39.0 39.5 40.0 40.5 41.0Flow = 0.0 L/min-m2
(m)17.5 18 18.5 190
0.25
0.5Flow = 1.0 L/min-m2
(m)
0
0.25
0.5Flow = 0.1 L/min-m2
Groundwater Flow
TOUGH2 Heat & Mass flow simulations of DTPS system
10 | US DOE Geothermal Program eere.energy.gov
Project Management/Coordination
• Project management – effort split between co-PIs (2 yr effort)– Task 1 Development of DTPS cables suitable for application in mid- to
high-temperature geothermal wells $250k – Barry Freifeld– Task 2 Development of a numerical method for analysis of DTPS data
for flow profile imaging and in situ determination of thermal conductivity profiles and heat flux $100k – Stefan Finsterle
– Task 3 – Reporting $50k• Schedule
– FY10 Development of DTPS technology < 250°C (fabrication, bench top testing, numerical data reduction techniques)
– FY11 Development of DTPS technology ≤ 350°C• Leveraged Funds
– DTPS is being used in some Carbon Sequestration demonstration projects (CO2SINK & CO2CRC Otway Project) → leveraging of engineering and modeling effort through cross fertilization is planned
11 | US DOE Geothermal Program eere.energy.gov
Future Directions
• Identification and deployment at geothermal field sites.– Preliminary contacts have been made for potential field
deployments at various sites– Depending on success of cable development will determine
when we can go from technology development to technology demonstration
– Decision point (go/no go) based upon success of bench top testing of a DTPS at elevated temperatures
12 | US DOE Geothermal Program eere.energy.gov
• The DTPS has successfully been used for non-geothermal applications
• Our program will develop the technology and methodology for application of DTPS for geothermal applications
• A successful outcome will be – Development of robust, deployable hardware– Software tools for interpretation of acquired data– Formulation of plans for technology demonstration at a field site
DTPS Summary Slide
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