Polycrystalline diamond drill bits open up options for geothermal energy

Mar 19, 2012
Elton Wright shows a torsional spring that’s used to simulate the rotational vibration of the drill string in a Sandia experiment. Credit: Randy Montoya

Nearly two-thirds of the oil we use comes from wells drilled using polycrystalline diamond compact (PDC) bits, originally developed nearly 30 years ago to lower the cost of geothermal drilling. Sandia and the U.S. Navy recently brought the technology fullcircle, showing how geothermal drillers might use the original PDC technology, incorporating decades of subsequent improvements by the oil and gas industry.

Sandia and the Navy’s Geothermal Program Office (USN GPO) conducted the Phase One demonstration tests as part of a geothermal resources evaluation at the Chocolate Mountains Aerial Gunnery Range in Imperial Valley, Calif.

Sandia has a long history in geothermal research and drill bit technology development. Three decades ago, Sandia played a large role in developing PDCs for geothermal . That work focused on resolving issues with materials, devising laboratory tests and developing data and design codes that now form the basis of the bit industry. Recently, Sandia received American Recovery and Reinvestment Act (ARRA) funding to improve PDC bits, potentially increasing access to geothermal resources in the continental U.S. by enabling the drilling of deeper, hotter geothermal resources in hard, basement rock formations.

Geothermal drilling more demanding

Because oil and gas drilling is generally less complicated than geothermal drilling, PDCs were first used to drill for oil and gas, said principal investigator David Raymond.

“Oil and gas drilling is normally done in softer and less-fractured rock, resulting in fewer problems with fluid circulation to remove debris and cool the bit,” he said. “Oil and gas drilling also doesn’t usually involve the higher temperatures that geothermal wells exhibit.”

But as the looks for new sustained resources in deeper reservoirs, it encounters more difficult drilling conditions similar to those found in geothermal drilling.

“Oil and gas drilling must now go deeper into the ground, into harder and sometimes fractured rocks, and in hotter environments,” said Raymond.

Elton Wright examines a prototype drill bit used for an experiment in Sandia’s Hard-Rock Drilling Facility. Credit: Randy Montoya

Raymond said geothermal resources are typically associated with igneous and metamorphic rocks, which are harder than the sedimentary rocks through which most oil and gas wells are drilled. Igneous and metamorphic rocks also can contain large amounts of abrasives such as quartz, which can cause vibration and accelerated wear that damages drill bits. These types of rocks are often fractured, which can change the impact loading on drills and cause more damage.

“Drilling for geothermal energy is still the most difficult drilling on a cost-per-foot basis,” said Raymond. “You have to go through the hardest rock, sometimes at high temperatures and pressures. The DOE (Department of Energy) vision for advanced geothermal development is to drill to great depths, up to 30,000 feet, to access heat for geothermal.”

The economic risk for oil and gas wells also is different. Because many more oil and gas wells are drilled per year, that industry has the resources and can invest significantly in research and testing to improve the ability to drill under increasingly difficult conditions.

The geothermal industry has advanced far more slowly. Because geothermal drillers create only a small number of new wells each year, the drilling service industry finds it difficult and expensive to support innovation, since each well represents a substantial risk.

The Sandia/Navy demonstration project called for a test hole to evaluate geothermal resources in the Camp Billy Machen/Hot Mineral Spa region that would have been otherwise undetectable at the surface. The basement rock at the Chocolate Mountains includes granite and andesite, formations typically encountered during geothermal drilling.

A key part of the demonstration project was to test and evaluate PDC bits and related technologies in a real-world drilling environment. Sandia worked with PDC bit manufacturer National Oilwell Varco (NOV) of Houston to find specific solutions for the company’s ReedHycalog PDC bits. NOV provided commercially available drill bits and on-site experts to counsel the drilling contractor during the demonstration drill runs.

Sandia worked with the Navy’s geothermal drilling contractor, Barbour Well Inc. of Henderson, Nev., in evaluating drilling technologies during production drilling.

Sandia also formed partnerships with Albuquerque’s Prime Core Systems, and the Barbour Well mud logging company, Prospect Geotech, to field instruments to monitor the Barbour drill rig during the drilling process.

In the tests, two bits drilled 1,291 feet of the overall well depth of 3,000 feet. The two bits were in the well just over four days, penetrating approximately 30 feet per hour throughout their drilling interval, nearly three times better than standard roller bits used for comparison. The team retrieved and downloaded downhole data from both bits for analysis.

In a planned second phase of the project, Sandia will continue work with NOV to evaluate drill performance and improve the bit design and materials.

Cooperative work between the Navy and Sandia was covered by a memorandum of understanding between the Department of Defense and the DOE on collaborative development of renewable energy resources.

The demonstrations and planned phase two drilling are funded through an American Recovery and Reinvestment Act project, “Technology Development and Field Trials of EGS Drilling Systems,” under the supervision of DOE.

How PDC cutters are made

Polycrystalline diamond compact cutters on the cutting faces of bits allow more aggressive drilling than bits traditionally used for geothermal drilling. They are created by a sintering process. Graphite powder is applied to the leading face of a cutter made of tungsten carbide. The material assembly is compressed in three directions at pressures of 1 million pounds per square inch. When heated to a transition temperature, the graphite converts a to a 1-millimeter layer of synthetic diamond.

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Moebius
2.5 / 5 (2) Mar 19, 2012
Geothermal is the way to go. If we put the effort behind it like we did to get to the moon we could have unlimited clean power. Too bad we don't have a geothermal JFK with the foresight to do it.
dschlink
1 / 5 (1) Mar 19, 2012
Yeah, we got to the moon and basically abandoned space afterwards.

Geothermal power has severe corrosion problems, regardless of the working medium. Anything pumped into the ground will come back up with a witches brew of contaminates.
hemitite
5 / 5 (1) Mar 19, 2012
dschink,

If one could somehow install heat exchangers at depth, the resulting closed system could keep the witches brew six miles down while bringing the energy up.

Perhaps a "wagon wheel" design with injector wells on the "rim" feeding a central recovery well through slant drilled "spokes" could be one possible design,
Kinedryl
1 / 5 (1) Mar 19, 2012
Geothermal is the way to go.

Geothermal drills gets exhausted after ten years, not to say about earthquakes and water sources pollution. http://www.nytime...tml?_r=1 http://www.scient...thquakes
hjbasutu
1 / 5 (1) Mar 20, 2012
Think cold fusion..
Howhot
not rated yet Mar 21, 2012
Geothermal in some cases may work, but as @dschlink says "Geothermal power has severe corrosion problems". Geothermal is not a panacea.

Of course cold fusion needs to be studied more. With heavy electron screening of the proton in some sort of low energy "Rydberg Neutron" I can buy into it.