Tag: David Blackwell

DOE awards SMU $5.25 million to expand U.S. geothermal production

Post author By Margaret Allen
Post date November 2, 2009

The Geothermal Laboratory at SMU has been awarded $5.25 million by the U.S. Department of Energy to help provide data for the planned National Geothermal Data System.

The grant allocation is part of $338 million in Recovery Act funding that was announced Oct. 29 by DOE Secretary Steven Chu. The funding is intended to help dramatically expand geothermal production in the United States.

SMU will work with a diverse team of experts from academia, industry and national labs with experience in conventional hydrothermal geothermal resource assessment, Enhanced Geothermal Systems, oil and gas data, geopressure geothermal and produced water non-conventional geothermal systems in providing the data, including:

An expanded and updated version of the SMU Heat Flow database that covers the whole onshore U.S. and offshore regions in the Gulf of Mexico.
The Geothermal Resources Council library with over 36K in documents and over 1.3 million pages on geothermal research
Extensive information on Enhanced Geothermal System research including legacy data files and the latest developing results of research in the northeastern U.S.
Core logs, well logs, and current and legacy geopressure data from the Texas Bureau of Economic Geology covering many states
Detailed nationwide data on produced water collected from numerous states’ oil and gas agencies and several federal agencies plus relevant geological, spatial, well bore, injection/disposal, and water well data.

Principal investigators are SMU’s David Blackwell, Hamilton Professor of Geothermal Studies, and Fabian Moerchen of Siemens Corporate Research. The project team also includes Jefferson Tester, the Kroll Professor of Chemical Engineering at Cornell University; William Gosnold, chair of geology and geological engineering at the University of North Dakota; Seiichi Nagihara, associate professor of geosciences at Texas Tech University; John Veil, manager of the water policy program at the Argonne National Laboratory and Martin Kay, president of MLKay Technology LLC.

“The primary benefit of this project is that it will support developers of geothermal power plants by decreasing the costs of the resource identification and the risks inherent in the exploration phase,” Blackwell said. “The project will rescue important data from deterioration or complete loss and provide a set of tools to be used by other parties to submit data to the NGDS.”

A distributed network of databases, NGDS was established by the U.S. Department of Energy to collectively build a system for acquisition, management and maintenance of geothermal and related data.

The SMU Geothermal Lab is hosting its annual conference, “Geothermal Energy Utilization Associated with Oil & Gas Development,” Nov. 3-4 on the Dallas campus. Registration is available at the door. Find more information at the conference web site. — Kim Cobb

Tags David Blackwell, Dedman College, Huffington Department of Earth Sciences, SMU Geothermal Lab

Earth & Climate Energy & Matter

Geothermal heat: Will Earth’s “hot rocks” become new “Texas tea”?

Post author By Margaret Allen
Post date June 15, 2009

Texas, which has been the nation’s largest fossil-fuel producer, also has an abundant supply of another natural resource for a different kind of energy boom: clean, renewable, geothermal energy.

Like the oil and gas beneath Texas, there’s a huge quantity of naturally occurring “hot rocks” underground that could be tapped for geothermal energy to produce electricity, according to new research by SMU scientists. South and East Texas have an abundant supply, say the researchers.

iphone%20feb%205%202008%20058.jpg “There is more than enough heat below our feet to take all the state’s industrial consumption off the existing transmission grid,” says Maria Richards, program coordinator for the SMU Geothermal Laboratory.

Lab researchers recently completed an assessment of geothermal resources in South and East Texas for the Texas State Energy Conservation Office, or SECO. They found enough heat to supply Texas with clean, renewable, affordable electricity for hundreds of years, Richards says. Some of the state’s largest urban areas sit atop the vast regional geothermal zone, which extends east from Interstate 35 and includes Dallas-Fort Worth, Houston, Austin, Corpus Christi and Kilgore.
Maria Richards with a driller on an oil rig.

The SMU analysis will be part of The Energy Report, a SECO report on clean and renewable energy resources in Texas. SECO funded the SMU Geothermal Laboratory research with a $200,000 grant. SMU will submit the assessment to SECO later in June.

Currently Texas gets the bulk of its electricity from natural gas-, coal- and nuclear-powered generating plants. But commercial interest in geothermal energy is growing both in the state and nationwide, says David Blackwell, one of the country’s foremost authorities on geothermal energy and a professor at SMU. Over the past 12 months, SMU’s Geothermal Laboratory has received a record number of requests from private entities asking for help in developing commercial projects, says Blackwell, who has advised the industry for the past 40 years.

The two also helped author a 2007 study led by Massachusetts Institute of Technology that found geothermal energy could supply a substantial amount of the energy the United States will need in the future, likely at competitive prices and with minimal environmental impact. The MIT study’s authors said geothermal energy is especially attractive because it is widely available, doesn’t have to be stored to supply minimum demand, and has a small footprint with low or no emissions. It is also considered virtually inexhaustible, according to the Geothermal Energy Association.

The MIT study estimated the U.S. geothermal resource base at more than 13 million exajoules, which is a measurement of stored thermal energy. The extractable portion of that is estimated at more than 200,000 exajoules, or about 2,000 times the annual U.S. consumption in 2005 of primary energy, according to the report.

Currently the U.S. has more geothermal generating capacity online than any other country, about 30% of the world’s total, according to the Geothermal Energy Association.

MikePaul%5B1%5D.JPG Texas is uniquely positioned for geothermal development, according to Blackwell and Richards. That’s due in large part to the state’s thousands of existing oil and gas wells that could be developed in various ways to tap geothermal heat.

Pictured right: Michael Paul, SMU director of energy management and engineering, collects temperatures at a field near Corpus Christi

The SMU Geothermal Lab’s research has proven the potential for drawing electricity from low-temperature geothermal sources through “binary” technology. A binary power plant circulates hot groundwater through an existing oil or gas well to heat a secondary fluid. The resulting vapor then drives turbines to generate electricity.

There are thousands of oil and gas wells in Texas that could be economical for geothermal development, Richards says. That’s especially true since the technology can operate concurrently in oil and gas wells, which would significantly reduce the cost of geothermal exploration. Geothermally produced electricity could then offset the power normally required to operate oil-field production units. Additionally, excess electricity could be sold back to the statewide electric transmission grid. Depleted oil and gas wells that are slated for abandonment could again generate revenue when tapped for geothermal production.

SMU’s regional assessment for SECO covered 91 counties. It calculated the geothermal heat under South and East Texas at 921,085 exajoules, giving the state enormous geothermal potential. Anywhere from 2 percent to 10 percent of that is recoverable, depending on the efficiency of the conversion technology and the location of the resource.

“As humans we have no real concept as to how much heat is below our feet,” Richards says. “We feel the sun in our face, and the wind in our hair, but we don’t feel the Earth’s heat through our feet.”

SMU’s researchers analyzed historical temperature data for wells drilled since the early 1990s. Drilling logs for each hole include temperature recordings taken at various depths. The SMU analysis looked at wells ranging from 2,000 feet to 20,000 feet deep. The researchers were surprised that the temperature in some wells ran as hot as 450 degrees Fahrenheit, Richards says.

Wells drilled from 9,000 feet to 14,000 feet deep, with temperatures downhole of 250 degrees or greater, will likely be economical for geothermal energy. They would be sufficiently hot and reasonably close to the surface. In deeper wells, unless they flow naturally, the binary technology would require too much electricity.

The team of SMU Geothermal Laboratory researchers included six graduate and undergraduate students.

“This turned out to be a wonderful project for the students,” Richards says. “With President Barack Obama’s push for more emphasis on science and renewable energy, these are students on the leading edge of that whole process. And they are focused on a project that was funded by the state of Texas.” — Margaret Allen

Tags David Blackwell, Dedman College, Geothermal Map of North America, Huffington Department of Earth Sciences, Maria Richards, SMU Geothermal Lab

Earth & Climate Energy & Matter Events Technology

SMU conference: Geothermal energy from oil, gas wells

Post author By Margaret Allen
Post date June 12, 2009

Enhancing existing oil and gas wells for the purpose of producing electricity from the Earth’s heat will be the focus of an annual international geothermal conference at SMU in November. The conference is coordinated by the SMU Geothermal Laboratory and SMU’s Roy M. Huffington Department of Earth Sciences.

“Geothermal Energy Utilization Associated with Oil and Gas Development” will connect landowners with technical, operational and financial players interested in embarking on a geothermal energy project. The two-day conference is set for Nov. 3-4.

Geothermal energy can be extracted from well fluids using compact turbines with binary fluids, according to Maria Richards, program coordinator for the SMU Geothermal Laboratory. The systems are now sized to fit a single well or multiple wells with approximately 120 degrees Fahrenheit temperature differential between produced and cooling temperatures.

This is a good year to start a project, Richards says. In addition to federal passage of the Renewable Electricity Production Tax Credit, there’s also federal stimulus money available for renewable energy projects. Texas and other oil-producing states with thousands of existing oil and gas wells are uniquely positioned for economical geothermal development, says David Blackwell, one of the country’s foremost authorities on geothermal energy and a professor at SMU who has advised the geothermal industry for the past 40 years. Projects are being submitted now for Texas demonstration sites in response to a request for proposals from the Department of Energy. Proposals are due in July.

“Geothermal energy produces clean, renewable electrical power that is considered a base load source since it produces 24 hours a day, 365 days a year,” Richards says. “This capability to generate power gives a new revenue stream to low-yield producers with high-water volume and a reason to keep them producing.”

The conference is sponsored by Pratt & Whitney, SMU Cox Executive Education, the Texas State Energy Conservation Office, Perma Works LLC, Telios, the Research Partnership to Secure Energy for America, Gulf Coast Green Energy, Hilcorp Energy Co., and Texas Alliance of Energy Producers.

SMU Geothermal Laboratory researchers recently completed an assessment of geothermal resources for the Texas State Energy Conservation Office. It found that the volume of geothermal heat in the ground beneath Texas could supply the state with clean, renewable, affordable electricity for hundreds of years. Some of the state’s largest urban areas sit atop the vast regional geothermal zone, which extends east from Interstate 35 beneath Dallas-Fort Worth, Houston, Austin, Corpus Christi and Kilgore.

Over the past 12 months, SMU’s Geothermal Laboratory has received a record number of requests from private entities asking for help in developing commercial projects, Blackwell says.

Pioneers in assessing the nation’s geothermal resources, Blackwell and Richards revealed the potential for widespread geothermal development with their Geothermal Map of North America, published in 2004 by the American Association of Petroleum Geologists. The two also helped author a 2007 study led by Massachusetts Institute of Technology that found geothermal energy could supply a substantial amount of the energy the United States will need in the future, likely at competitive prices and with minimal environmental impact.

Geothermal projects and research, while cutting-edge, are not new for SMU, Richards says.

“When I talk about the SMU Geothermal Laboratory at a professional meeting, I mention the fact that it’s been around for 40 years,” she says. “It’s not just a start-up because of a trend. We’ve been doing this for a long time — and we’re still at the leading edge.”

Tags David Blackwell, Dedman College, Maria Richards, SMU Geothermal Lab

Earth & Climate Economics & Statistics Energy & Matter

Earth’s inner heat holds promise of generating much-needed electric power in Northern Mariana Islands

Post author By Margaret Allen
Post date October 29, 2008

A chain of 14, breathtaking Pacific islands is paradise lost without reliable electricity.

The Northern Mariana Islands, a U.S. commonwealth some 1,500 miles east of the Philippines, has seen its garment industry waste away in the face of global competition. Attracting replacement industry is difficult, in part because of the commonwealth’s undependable power supply. Rolling blackouts are the norm, caused by aging power plant equipment and the irregular delivery of expensive, imported diesel to run the plants.

SMU’s geothermal energy team of faculty and graduate students is aiming to prevent the Islands’ economic oblivion by helping to convert their volcanic heat into affordable, renewable energy.

“This [energy crisis] could be the United States 20 years from now,” says James E. Quick, associate vice president for research and dean of graduate studies at SMU.

Quick knows from his own work in the Marianas what it would mean for residents to cut their dependence on costly diesel fuel. He directed a volcano-monitoring program for the islands during his previous career with the U.S. Geological Survey.

Most recently Quick has served as a liaison for the island government in its search for renewable energy: He introduced Northern Mariana officials to SMU’s recognized experts in geothermal energy: David Blackwell, W.B. Hamilton Professor of Geophysics in Dedman College, and Maria Richards, coordinator of SMU’s Geothermal Lab.

In the Marianas, the SMU team is studying the potential applications for two different types of geo-thermal systems that use Earth-heated water and steam to drive turbines and produce electricity.

Testing has been completed on volcanic Pagan Island, where the results are being studied to determine if a large, steam-driven power plant like those found in California and Iceland may be a fit.

On Saipan, the most populated island in the Marianas chain, subsurface water temperatures are lower because there is no active volcano. Testing of existing water wells completed in early summer supports the potential for building smaller power plants designed for lower temperatures. Plans call for drilling a test bore hole on Saipan to confirm water temperatures at deeper depths.

Interest in geothermal energy has been growing against a backdrop of rising oil prices.

Google.org is providing nearly $500,000 to SMU’s Geothermal Lab for improved mapping of U.S. geothermal resources. Blackwell, who has been collecting heat flow data for 40 years, is credited with drawing attention to the untapped potential energy source with his Geothermal Map of North America, first published in 2004.

The Google.org investment in updating that map will allow Blackwell to more thoroughly mark locations where potential exists for geothermal development.

Blackwell and Richards are convinced that oilfields may be some of the most overlooked sites for geothermal power production in the United States. SMU’s geothermal team is offering an energy solution that would boost capacity in low-producing oilfields by using the deep shafts drilled for petroleum products to also tap kilowatt-generating hot water and steam.

The process of pumping oil and gas to the surface frequently brings up a large amount of hot wastewater that the industry treats as a nuisance. Install a binary pump at the well head to capture that waste hot water, Blackwell says, and enough geothermal energy can be produced to run the well, mitigating production costs for low-volume wells. It can even make abandoned wells economically feasible again.

Taken a step further, surplus electricity generated from an oilfield full of geothermal pumps could be distributed to outside users at a profit. This kind of double dipping makes sense for short and long-term energy production, Richards says.

“This is an opportunity,” she says, “for the energy industry to think outside the box.” — Kim Cobb

Tags David Blackwell, Dedman College, Geothermal Map of North America, Maria Richards, SMU Geothermal Lab