The Oregon Institute of Technology (OIT) is installing a 150-foot-tall drilling tower which will punch into a geological fracture almost a mile below ground, tapping 300-degree water to feed a 1.5 megawatt (MW) electrical plant. The $4.5 million high-heat plant will produce enough energy to power the entire Klamath Falls campus and then some. At a total cost of about $8.5 million, the plan includes a second, low-temperature power plant that can run on existing wells on the campus.

Two large, heated aquaculture ponds and a pair of greenhouses will become incubators for researchers and companies that could bring industry to Klamath County.

Above all, the project will be a giant classroom for students drawn to OIT’s growing emphasis on renewable energy, said John Lund, director of the school’s Geo-Heat Center.

We’re going to instrument the heck out of them because it’s part of learning, said Lund, who envisions high school and younger students also learning from the geothermal array. The investment the Oregon University System has made into it hopefully will be paid off.

Eventually, the geothermal system could become part of a renewable energy park at OIT, where students will get hands-on experience with solar, wind and biofuels.

More than a century of use

Klamath Falls has taken advantage of the area’s geology by tapping into the earth’s heat for more than a century, and more than 500 wells warm homes and businesses, municipal swimming pools and sidewalks.

The Geo-Heat Center, housed in a small office lined with books and research papers, is internationally known and has advised companies locally and globally. It helped Klamath Basin Brewing Co. five years ago to become the first in the world to use geothermal energy for its brewing process. And nearby Liskey Farms uses geothermal wells to heat its leased greenhouses for fruits and vegetables and for a predator mite operation, as well as a canola crusher to process oil for biodiesel.

But OIT’s electric plants take geothermal use a step further, drilling into the same crack in the earth’s crust that supplies 195-degree water at three existing campus wells.

Ultrasound testing last spring brought the fault into sharp focus, like the image of a baby in its mother’s womb. Although the drill can change direction, engineers hope to have a direct shot from the drilling site in the middle of campus. Water drawn from about 4,000 feet should be at least 300 degrees, Lund said, and provide the pressurized steam to turn the turbine in the power plant. Wastewater will be used in the campus heating system, the low-heat power plant or sold to other users.

There is no guarantee they will strike hot water — for example, recent exploratory drilling at Newberry Crater near Bend revealed plenty of heat but no water. But Lund and others are fairly certain their deep well will hit liquid.

If it’s fractured, that means there are avenues for water to flow into it, Lund said. And we know there’s water in there because we’ve tapped into it.

50 truckloads of equipment

The drilling job itself is straightforward.

It will be a challenge logistically rather than geologically, said Patrick Hanson, marketing specialist for driller ThermaSource. This is a highly unique project for us because it’s right in the middle of the university — and right in the middle of a parking lot of the university.

ThermaSource, based in Santa Rosa, Calif., normally does large, multiwell projects in the wilderness, sometimes drilling more than two miles beneath the surface. But the company’s founders have worked with Lund, assistant director Toni Boyd and the Geo-Heat Center over the years.

We wanted to be a part of this, Hanson said. We’re a longtime networking friend of John and Toni, and it’s definitely something we’re interested in.

Fifty truckloads of equipment and pipe are due to arrive on campus today. Deep drilling should begin later this week and will take about a month, running round-the-clock.

Funding comes from federal and state money, and the Oregon University System. OIT will seek an additional $1.3 million from the Department of Energy during the next congressional session, and Lund said he expects private investors also will step forward.

Once you have a well, the investors flock to you because the risk is gone, he said.

The school already saves about $1 million annually in heating costs and plans to make about $200,000 by selling geothermal heat. The power plant will also cut $500,000 in electrical costs — and excess electricity could be sold to a commercial power company.

For decades, the Oregon Institute of Technology has drawn from the earth to warm its classrooms, heat its swimming pool and melt snow from its sidewalks.