This interview details VoltServer, a company based in the United States. The interview is with James Eaves, Ph.D., Indoor Agriculture Director at VoltServer.
A fundamental truth in global development is that economic prosperity grows with increased access to energy and information. However, expanding electrical infrastructure is often hindered by high costs. Overcoming this barrier is crucial for broader energy access and, consequently, economic growth.
VoltServer's founder and CEO, Stephen Eaves, recognized that the high cost is largely due to the dangers associated with high-voltage electricity, necessitating complex construction methods to prevent injuries and fires. After selling his previous energy company, he set a new goal: to make high-voltage electricity inherently safe.
He succeeded, and VoltServer officially opened its doors in July 2013, beginning product shipments in early 2014. Our patented Digital Electricity™ is powering over 1,000 large venues, including sports stadiums, office towers, hotels, condominiums, medical buildings, and vertical farms.
Digital Electricity™ is the first high-voltage power listed as a “Class 2” circuit. This means you can distribute electricity throughout your farm using 75% less equipment and labor, employing thin 18AWG wires without the need for conduit, breakers, stepdown transformers, or GFCIs. This is despite Digital Electricity™ distributing thousands of watts at 336VDC. Additionally, the system allows for control, monitoring, and scheduling of each individual LED without needing a separate control system.
The implications of Digital Electricity™ are so profound that the NEC introduced a new category of power, “Class 4”, marking the first such innovation in over half a century—an achievement VoltServer holds in high regard. Today, Digital Electricity™ is still installed under the Class 2 listing in all 50 states and Canada.
Our challenge lies in "path dependence." The world's electrical infrastructure is built around Alternating Current (AC) power, meaning most electrical equipment is designed to use it. For example, many modern electronics, like computers, LEDs, and batteries, actually run natively on Direct Current (DC). However, device manufacturers often install power supplies that convert AC to DC. This is inefficient, but due to 150 years of infrastructure investment in AC power, manufacturers continue producing AC-compatible equipment.
For instance, in the Controlled Environment Agriculture (CEA) market, we face the task of convincing LED manufacturers to produce driverless LEDs. Removing the driver can significantly reduce costs and improve LED reliability, but it requires manufacturers to change their production methods. But the market is finally shifting, and today, over a dozen manufacturers build Digital Electricity™-compatible LEDs.
VoltServer stands out as the only high-voltage power distribution system installable using low-voltage wiring methods. Our real competition is traditional AC or DC systems. Sometimes, people mistakenly equate Digital Electricity™ with low-voltage DC or Power over Ethernet, but those systems can only power low-powered devices close to the power source. Such systems aren't practical for CEA facilities or large buildings.
The current hot topic is the slow market growth for new farms and the bankruptcy filings of notable companies. Some argue that indoor farming was a fad that won't make a comeback. However, commercial bankruptcy rates have risen across most industries in recent years due to high interest rates, leading to higher bankruptcies and all industries and less construction in all capital-intensive industries like factories and commercial buildings. Most indoor growers I've spoken with say there is more demand than ever for their products. So, as interest rates begin to decline, we expect the indoor farming market to pick up again.
Controlled Environment Agriculture is still an emerging technology and practice, with low levels of control being leveraged. For instance, it's common for greenhouses to have 5-acre lighting zones, even though natural light variation within those zones averages about 40%. A typical greenhouse could easily reduce electricity used for lights by 15% while maintaining the same yields through more granular lighting control. Similarly, temperature varies considerably across an average greenhouse and indoor farm's canopy. This creates another opportunity to significantly reduce energy use through more granular control of airflow and lighting.
Better electrical design can also contribute. For indoor farms, distributing power at higher voltages, eliminating equipment like stepdown transformers, and centralizing power supplies outside of grow spaces can reduce energy use by up to 8%. Additionally, if a farmer uses renewable energy and battery storage, switching to DC distribution rather than AC can increase the efficiency of the renewable microgrid by up to 13%. Assuming electricity constitutes about 50% of OPEX, better electrical design combined with more granular control can reduce OPEX by up to 20%. This is significant for an industry where the best-performing companies have single-digit profit margins.
Feel free to connect with me directly on LinkedIn or visit VoltServer.com for more information.
This interview details OMARFRA, a company based in Canada. The interview is with Fadi Al-Daoud, Greenhouse Vegetable Specialist of OMARFRA. To learn more about OMARFRA and other indoor farming companies, click on this link!
View Full InterviewThis interview details Libra Design, an indoor farming technology company based in the United States. The interview is with Travis Williams, Co-Founder & CEO of Libra Design. To learn more about Libra Design and other indoor farming companies, click on this link!
View Full InterviewThis interview details BioSafe Systems, a company based in the United States. The interview is with Eric Smith, National Sales Manager (Horticulture Division) at BioSafe Systems. To learn more about BioSafe Systems and other indoor farming companies, click on this link!
View Full InterviewThis interview details McNabb MicroFarm, an indoor farming company based in the United States. The interview is with Lauren McNabb, Head of Marketing at McNabb MicroFarm. To learn more about McNabb MicroFarm and other indoor farming companies, click on this link!
View Full InterviewThis interview details Griffin, an indoor farming company based in the United States. The interview is with Tami Van Gaal, Director of Vendor Relations at Griffin. To learn more about Griffin and other indoor farming companies, click on this link!
View Full InterviewThis interview details Virgo Global Inc., a company based in Canada. The interview is with Guillaume Paquet, Director R&D at Virgo Global Inc. To learn more about Virgo Global Inc. and other indoor farming companies, click on this link!
View Full InterviewThis interview details Corridor Farmers, an indoor farming company based in Singapore. The interview is with Roc Koh, CEO of Corridor Farmers. To learn more about Corridor Farmers and other indoor farming companies, click on this link!
View Full InterviewThis interview details Affinor Growers, an indoor farming technology company based in Canada. The interview is with Nick Brusatore, CEO of Affinor Growers. To learn more about Affinor Growers and other indoor farming companies, click on this link!
View Full InterviewThis interview details Ina Plastics, a company based in Greece. The interview is with Jacob Tsonakis, Founder and CEO of Ina Plastics. To learn more about Ina Plastics and other indoor farming companies, click on this link!
View Full InterviewThis interview details Funga Farm, an indoor farming company based in Denmark. The interview is with Thomas Kyle Cometta, Owner of Funga Farm. To learn more about Funga Farm and other indoor farming companies, click on this link!
View Full Interview