The W.M. Keck Observatory has been in operation for nearly 30 years atop Maunakea, a dormant volcano and the highest point in Hawaii. The twin telescopes are arguably the best place to go for astronomical observation in the Northern Hemisphere. At an elevation of 13,796 ft, stormfronts regularly pass below the observatory, and the skies above the Pacific Ocean are clear of light pollution.
With those conditions, why not put a solar array up there, too?
Significant astronomical research has been conducted at the W.M. Keck Observatory since its first telescope was built in 1993. W.M. Keck Observatory
Mark Devenot, infrastructure specialist at the Keck Observatory, often pondered the feasibility of a construction project like solar at that elevation. Duke Energy installation subsidiary REC Solar built a 100-kW array at Keck’s headquarters in 2013, but that site is in Waimea, which is a couple hours’ drive down the summit from the telescopes and was exempt from the extensive permitting process for construction projects on Maunakea.
A new challenge was accepted. Through the gamut of design, permitting, engineering and installation requirements, Keck Observatory now hosts a 137-kW solar array between its twin telescopes.
“This project took nearly four years,” Devenot said. “You have no idea how many times this project may not have happened.”
Putting solar atop a volcano
Keck Observatory’s first telescope was built in 1993. Since its inception, the site remains an often-used asset for groundbreaking space research, with each telescope booked out months in advance by astronomers and students from affiliate universities. For example, in October, UCLA professor Andrea Ghez was awarded the Nobel Prize in Physics 2020 for her research at Keck Observatory on the existence of a supermassive black hole in the Milky Way galaxy.
The technician team at Keck Observatory keeps the infrared telescopes running, replacing aging infrastructure with newer lighting, motors, air dryers and variable-frequency drives. Adding solar to a place that observes the stars was part of that upkeep.
“We have a responsibility to the science community to provide the telescope to be ready for them to use at night, so our mission during the day is to make sure everything’s good to go for them,” Devenot said.
The solar array installed between the Keck telescopes is technically a smaller footprint than its sibling system at the observatory’s headquarters, but it produces more power both at an equipment level and from higher UV exposure from the elevation. REC Solar, which was brought back for this second project, found the system was running at 115% efficiency in that environment. The array supplies 15% of Keck Observatory’s electricity needs. It was sited far enough from either tower to prevent ice falling from the telescopes from landing on the panels, and modules were laid flat to minimize resistance from high wind speeds atop the volcano.
REC Solar installed a 137-kW solar system between the twin telescopes at W.M. Keck Observatory atop Maunakea, a dormant volcano and the highest point in Hawaii. Mark Devenot/W.M. Keck Observatory
The array itself is made of 332 LG NeON 400-W modules, SMA Sunny Tripower 30-kW inverters and a specially designed foundation and structure, the latter using SnapNrack channels and clips atop a galvanized Unistrut frame.
Foundations turned out to be a major design element for the array. The roof surface between the Keck I and II telescopes is EPDM covered by cinder from the dormant volcano. Removing the rock by hand for the initial design took days, Devenot said. Installers brought a mini-excavator to Maunakea to carefully remove the cinder.
“You have what you call an inverted membrane roof system, and it’s unique, probably the only one in Hawaii,” he said. “But someone had the foresight back when they designed the facility to do this and it’s amazing, because the cinder acts like an insulator from both the weather conditions and the UV from attacking the EPDM.”
And it works. After 27 years under that cinder, according to inspection, the EPDM appeared brand new. To maintain the roof’s integrity, the solar system is ballasted with steel plates that are either 150 or 275 lbs and 2-ft or 3-ft squares. The plates rest on the EPDM, and the cinder was replaced, covering the ballasts.
“To me, the biggest challenge and risk we had for the project was how to attach the panels to the roof,” Devenot said.
Additional risks during installation resulted from the environment and altitude. The solar contractors worked for about four weeks in derated atmosphere, which at nearly 14,000 ft above sea level cuts oxygen quality by about 40% and could result in hypoxia.
The installation crew was housed at the Onizuka Center for International Astronomy on the mountain to acclimate to the climate, and installers were provided with emergency oxygen kits. The environment might be ideal for solar panels, but installers had to be cautious of UV exposure, low humidity and derated winds that could reach hurricane speeds.
“Keeping people healthy and safe up there was our primary concern,” said Lucas Shield, senior project manager with REC Solar. “We had supplemental oxygen on hand, made sure everybody took regular breaks and were always drinking water. And there was no cell phone use allowed up there because it interferes with telescope equipment. So, we had regular check-ins with everybody, but no cell phones created a logistical issue because you can’t just drive down the mountain to go grab some equipment.”
Construction projects on Maunakea fall under the jurisdiction of the Office of Maunakea Management and the Department of Land and Natural Resources. The dormant volcano holds a significant place in Native Hawaiian culture, and groups have protested the potential construction of the “Thirty Meter Telescope” that would join 13 others already in the mountain’s Astronomy Precinct.
The observatory and accompanying solar array reside at nearly 14,000 ft above sea level, where UV exposure is pronounced, wind speeds are derated and atmospheric pressure causes a 40% drop in oxygen levels. Mark Devenot/W.M. Keck Observatory
New construction on the volcano isn’t common and must pass certain requirements at environmental, aesthetic and cultural levels. The addition of the solar array alone went through years of meeting discussions, review boards and committees. Then there was the matter of arranging a lease agreement and getting permission from local utility Hawaiian Electric to export power. All the heavy equipment used on the mountaintop project also had to be approved.
Devenot doesn’t expect any more solar projects to be installed for the Keck Observatory on Maunakea given the permitting process, temperamental environment and lack of space.
It can be argued that Maunakea is the tallest mountain on the planet, if it’s measured from its base located below sea level. However, the solar array can’t claim to be installed at the highest elevation on the planet — that designation belongs to a 4-kW system in the Himalayas — but it is the largest one to be installed at this height.
“That system might have been seen by some as a challenge or outside of our usual work scope,” said Christopher Licciardi, senior director of project delivery at REC Solar, “but it was fun for us.”
Billy Ludt is associate editor of Solar Power World and currently covers topics on mounting, installation and business for the magazine.
This would be an experiment in terms of Solar that will either show us new value or bomb very hard. I think the big thing here is the maintenance and the power output, but I’m definitely curious how this pans out and what the upgrades may be for this.
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