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A New Look at Geothermal Energy as an Energy Choice for the Future

A New Look at Geothermal Energy as an Energy Choice for the Future. W.D. Gosnold, D.F. Merriam, D.D. Blackwell . U. North Dakota Kansas Geol. Survey Southern Methodist U. Outline. Take home message Geothermal energy overview What we thought we knew What has changed What we now know.

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A New Look at Geothermal Energy as an Energy Choice for the Future

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  1. A New Look at Geothermal Energy as an Energy Choice for the Future W.D. Gosnold, D.F. Merriam, D.D. Blackwell U. North DakotaKansas Geol. SurveySouthern Methodist U.

  2. Outline • Take home message • Geothermal energy overview • What we thought we knew • What has changed • What we now know

  3. Take Home Message • Geothermal energy is an underestimated and largely untapped resource that could have a significant impact on the world’s energy future. • Advances in technology make electrical power generation from low-to-intermediate temperature geothermal waters a reality. • The power that could be generated from oil field waste waters alone is enormous. • Combining all potential geothermal resources could supply all electrical power needs for the US.

  4. Image Source: Geothermal Education Office, Tiburon CA

  5. The first coordinated assessment of US geothermal resources involved: • US Geological Survey • Circular 726 (1975) • Circular 790 (1979) • Circular 892 (1983) • DOE - State Coupled Program • Geothermal resource maps and reports • Industry • Working power plants • Universities • SMU, Utah, OIT, MIT, Va Tech, Nebraska, UND, UK, NMSU • Establishment of laboratories and many publications • Professional Organizations • Geothermal Resources Council

  6. Some key definitions • The temperature scheme established by the U.S. Geological Survey Circular 726 (White and Williams, 1975) categorized hot water resources as: • high-temperature (>150°C) • intermediate-temperature (150°C to 90°C) • low-temperature (<90°C)

  7. Types of Geothermal Systems • Hydrothermal systems • Conduction dominated systems • Stratabound systems • Geopressured systems • Engineering enhanced geothermal systems (EGS) • Ground source heat pump

  8. Geothermal Applications • Direct use heat • Electrical power • Ground source heat pumps 1018 = exa so 1 x 1018 J = 1 EJ 1 J = 1 W s 1 EJ = 0.278 TWh Kilo, Mega, Giga, Tera, Peta, Exa, Zetta, Yotta

  9. Direct Use • Space heating • Aquaculture • Greenhouses • Industrial processes • Although the potential for energy production from low to intermediate resources is great, actual usage has been slow to develop. • Lund and Boyd (2000) estimated that direct heat applications in the United States are 8.478 EJ y-1 (8,044 billion btu y-1). • The accessible resource in sedimentary basins is more than 3 x 106 greater than the amount in use.

  10. Source: Geothermal Education Office, Tiburon CA

  11. Source: Geothermal Education Office, Tiburon CA

  12. Electrical Power

  13. Source: Geothermal Education Office, Tiburon CA

  14. Geothermal Power Plant Dixie Valley, Nevada Geothermal Power Plant The Geysers Source: Geothermal Education Office, Tiburon CA

  15. Ground Source Heat Pumps • The potential for geothermal heat pumps (GHP) applications is enormous and GHPs are one of the fastest growing renewable energy applications world wide (Lund et al., 2004). • The global installed capacity is estimated to be 12 GWt and the annual energy use is about 72 PJ (Lund et al., 2004). • Lund et al., (2004) determined that coupling GHP systems with renewable electricity resources results in an apparent efficiency of 140% with an excess of 40% over the original energy consumed in generating the electricity.

  16. What we knew • High-temperature convection systems in the western U.S. contain 371 EJ(Renner, White, and Williams, USGS Cir. 726, 1975). • Intermediate temperature systems, which exist primarily in the western U.S., contain 42 ±13 EJ(Brook et al., USGS Cir. 790, 1978). • The accessible low-temperature resource base in the central United States contains 27,000 EJ(Sorey et al., USGS Cir. 893, 1983). • Undiscovered low temperature resources contain an additional 7,200 EJ(Sorey et al., USGS Cir. 893, 1983).

  17. What has changed • More and better data on heat flow and subsurface temperatures • Technology advances • Global energy economics

  18. Global average heat flow: 87 mW m-2 Total surface heat flux: 44.2 x TW 83% of present surface heat flow is due to radioactive decay of U, Th, and K Earth’s mantle is cooling at a rate of 36 °C Ga-1 Average solar flux at the surface: 400 W m-2 Average solar flux at TOA: 1365 W m-2 Global Heat Flow

  19. 1984

  20. Geothermal Map of North America, SMU Geothermal Laboratory, 2004 D. Blackwell and M. Richards, Eds.,

  21. Low-to-intermediate temperature resources were underestimated • USGS Circular 892: The GRA considered only one or two potential geothermal aquifers within well-known sedimentary basins. • Large basins such as the Williston Basin, Denver Basin, Powder River Basin, Anadarko Basin, and the US Gulf Coast region contain more than a dozen potential geothermal aquifers having temperatures greater than 100 °C. • LTITS Resource: Low-to-intermediate temperature stratabound resource

  22. LTITS in ND and SD • The estimate in USGS Circular 892, based on only the principal water producing formations, the Dakota Group and the Madison aquifer, in the Williston and Kennedy basins totaled 2,050 EJ. • Analysis of all potential aquifers in South Dakota and North Dakota indicates that the total accessible resource base in the two basins is approximately 33,700 EJ. • If the difference between earlier assessments and the current analysis applies to similar basins, the accessible resource base for the US may be of the order of 400,000 EJ. • The US LTITS resource was underestimated by 400%.

  23. Calculating the geothermal resource base Conductive heat flow at the surface is described by Fourier’s Law of Heat conduction Assuming we know heat flow, temperature at depth “z” may be calculated by

  24. Generalized Thermostratigraphy of the Williston Basin

  25. Three T-z profiles measured in wells in thermal equilibrium with the surrounding rocks and a model T-z profile.

  26. Use the equilibrium temperature not the BHT

  27. The energy resource in Joules is the product of density*volumetric heat capacity*volume*dT qr = ρcvad (t-tref) The Madison Fm in western North Dakota contains 1,476 EJ. Colors are temperature, contours are depth (m), lines are county boundaries

  28. Sediment thickness in the continental United States Source: "The Future of Geothermal Energy," MIT Report, January 22, 2007.

  29. North Dakotaand Eastern Montana • Heat flow in North Dakota and eastern Montana averages 52 ± 15 mWm-2 (n=40) and ranges from 45 mW m-2 in eastern North Dakota to 75 mW m-2 in the Williston basin in eastern Montana. • The mean accessible LTITS resource base is approximately 31,800 EJ.

  30. Eastern Colorado • Heat flow east of the Front Range in Colorado averages 91 ± 19 mWm-2 (n=15). • The mean accessible LTITS geothermal resource base is 2,640 EJ.

  31. South Dakota • Anomalous heat flow due to heat advection in topographically driven ground water flow in regional Paleozoic and Mesozoic aquifers occurs in an 80,000 km2 area in South Dakota between the Black Hills and the Missouri River. • Heat flow as low as 20 mW m-2 occurs in the recharge region near the Black Hills, and heat flow as high as 140 mW m-2 occurs above the discharge region in south central South Dakota. • The mean accessible LTITS resource base is 12,250 EJ.

  32. Nebraska • Heat flow in Nebraska averages about 65 ± 20 mWm-2 (n = 42), but the north central and western parts have anomalously high heat flow (80 to 145 mWm-2 ) due to regional groundwater flow in confined aquifers. • The mean accessible LTITS resource base is 3,720 EJ.

  33. Kansas • Heat flow in Kansas averages about 65 ± 9 mWm-2 (n = 20). • The mean accessible LTITSresource base is 4,980 EJ.

  34. Oklahoma and Texas • Heat flow averages 52 ± 22 mWm-2 (n = 11) in Oklahoma and 62 ± 56 mWm-2 (n = 50) in Texas. • The ORC power generation potential using waters from deep oil-producing formations in the Anadarko and Arkoma basins and Gulf Coast regions ranges rom 1,124 to 5,393 MWe in Oklahoma and 1,094 to 5,252 MWe in Texas (Blackwell, Negraru, and Richards, 2006). • This amount of energy is a thousand times greater than the annual electrical energy used in the entire state of Texas.

  35. Technology Advances • UTC Power and Ormat have reverse engineered industrial air conditioning systems (Organic Rankine Cycle - ORC) to create highly efficient turbine power generators.

  36. organic Rankine cycle binary generators • According to UTC, the efficiency of the ORC system is such that 10 MW of heat can be converted practically into about 1 MW of electrical power. • Water production at 1000 gpm at temperatures as low as 90 °C can be used to produce electricity at rates competitive with conventional power plants.

  37. UTC’s Pure Cycle-Model 200 provides 200 kW using 165ºF water at 480 gpm at Chena Hot Springs Resort, Chena, AK. Electricity cost dropped from 30¢ / kwh to 7¢ / kwh.

  38. Co-produced Oil Field Fluids • The potential power production using oil field waste waters with ORC technology is estimated to be at least 5.9 GW and could be as high as 21.9 GW (McKenna et al., 2005; MIT - 2007). • Requirements are: 1,000 gpm, for a well or a group of wells in relatively close proximity to each other. • Temperatures can be as low as 90 ºC (192 ºF).

  39. Opportunities for co-produced oil field waters • “Collecting and passing the fluid through a binary system electrical power plant is a relatively straightforward process.” • “Piggy-backing on existing infrastructure should eliminate most of the need for expensive drilling and hydrofracturing operations, thereby reducing the risk and the majority of the upfront cost of geothermal electrical power production.” Source: "The Future of Geothermal Energy," MIT Report, January 22, 2007.

  40. Equivalent geothermal power from co-produced hot water associated with existing hydrocarbon production in the mid-continent. Source: "The Future of Geothermal Energy," MIT Report, January 22, 2007.

  41. http://www.smu.edu/geothermal/ Geothermal Energy Utilization  Associated with  Oil & Gas Development Conference June 12-13, 2007

  42. The Future of Geothermal Energy The Future of Impact of Enhanced Geothermal Systems (EGS) on the United States in the 21st Century Massachusetts Institute of Technology http://geothermal.inel.gov/

  43. EGS Concept and Application

  44. Source: "The Future of Geothermal Energy," MIT Report, January 22, 2007.

  45. Source: "The Future of Geothermal Energy," MIT Report, January 22, 2007.

  46. Source: "The Future of Geothermal Energy," MIT Report, January 22, 2007.

  47. Source: "The Future of Geothermal Energy," MIT Report, January 22, 2007.

  48. Source: "The Future of Geothermal Energy," MIT Report, January 22, 2007.

  49. Source: "The Future of Geothermal Energy," MIT Report, January 22, 2007.

  50. Excerpts from MIT Report on EGS • “If we limit our calculation of stored thermal energy in place to a depth of 10 km beneath the land area of the United States, then the amount of thermal energy in the crust is so large (about 14 million quads) that we can view it as sustainable (see Chapter 2, Table A.2.1).” • “Even if we were to use it to provide all the primary energy consumed in the United States, we still would be depleting only a tiny fraction of it.”

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