IDTechEx: Solar roads find many uses

Feb. 24, 2016

Nowadays a major trend is the move to off-grid clean energy created by “energy harvesting” to produce electricity where it is needed. This is more controllable and increasingly at lower cost than grid power or diesel gensets, cleaner and often less subject to interruption. It is taking new forms as revealed in the IDTechEx Research report, “High Power Energy Harvesting 2016-2026.”

Installing photovoltaics in roads seems a daft idea at first. It sounds expensive and unlikely to work unless the surface is cleaned, free of snow and ice, and in direct sunlight—all too infrequent in most places. Indeed, roads are constantly dug up by utilities, repairmen, and others. How do you do that with sheets of glass?

Nevertheless, a closer look reveals that most of the problems are easily overcome, and even at poor efficiency, that local electricity has viable uses. U.S. start-up Solar Roadways has a modular system of specially engineered solar panels that can be driven upon but also carry cables. They contain LED lights to create lines and signage without paint and heating elements to prevent snow and ice accumulation.

Microprocessors let the panels to communicate with each other, a central control station, and vehicles. The glass has a tractioned surface, which is equivalent to asphalt. So far they can only support the weight of semi-trucks, but eventually these panels will be available for highways, but first will come noncritical applications such as driveways and parking lots.

Solar Roadways has completed two funding contracts with the U.S. Department of Transportation and has been awarded a third contract in November 2015. An Indiegogo campaign took things further, and the company says on its website, new in 2016, “Our goal is to modernize the infrastructure with modular, intelligent panels, while producing clean renewable energy for homes and businesses. We’ll be able to charge electric vehicles with clean energy from the sun, first on our solar parking lots and when we have enough highway infrastructure, while driving.”

At IDTechEx we do not see solar roads replacing power stations: do that with a field full of solar panels, not transmission and maintenance over long distances on roads. However, they could be excellent for dynamic (in-motion) charging of electric vehicles possibly coupled with roadside wind turbines or tethered multicopters providing airborne wind energy (AWE) in the new jargon.

The bike path that connects the Amsterdam suburbs of Krommenie and Wormerveer is popular: 2,000 cyclists ride its two lanes daily. Back in 2014, TNO made a 70-meter stretch into the world’s first public road with embedded solar panels. Costing around €3 million ($3.6 million) and funded mostly by the local authority, this road is made up of rows of crystalline silicon solar cells, encased within concrete and covered with a translucent layer of tempered glass. A non-adhesive finish and a tilt help the rain wash off dirt. The panels produced roughly 30% less energy than those fixed on to roofs but when the path is extended to 100 meters in 2016, it will produce enough kilowatts to power three households, they claim.

Sten de Wit of TNO predicted that up to 20% of the Netherlands’ 140,000 km of road could potentially be adapted, helping to power anything from traffic lights to electric cars. Tests have seen the solar panels successfully carry the weight of vehicles such as tractors.

Not to be outdone, a subsidiary of the French construction giant Bouygues is joining in. Minister of ecology and energy Ségolène Royal announced the French government would pave 1,000 km (621 miles) of road with photovoltaic panels in the next five years. The project aims to supply electricity to 5 million people—about 8% of France’s population.

The road photovoltaics are being produced by a French company called Colas, which is calling the project Wattway. The panels are composed of stacked photovoltaic cells that ensure resistance and tire grip. They do not require destruction of existing roadways: they can simply be added on to them. There are issues beyond cost and servicing pipes and so on beneath them. When their heating is on, animals will lie on them and be crushed by traffic. The heating will not cope with extreme cold or with deep snow or mud. To work at all the heating will have to be connected to the grid or to expensive, short-lived, batteries needing regular maintenance unless designs improve.

Solar roads have competition. The U.S. is funding research into roads that harvest movement to make electricity, but IDTechEx considers moving parts in such an application to be potentially troublesome. All the same, although piezoelectric walkways have not proved commercial, Pavegen is having some modest success with electrodynamic ones.

The huge move to energy harvesting EH both on land and on and in vehicles and buildings will covered thoroughly in the forthcoming IDTechEx Show! in Berlin, April 27-28. Over 50 of the 160+ exhibitors participating in the EH value chains and the parallel conferences, “Energy Harvesting and Storage” and “Electric Vehicles: Everything is Changing,” reveal new advances in thermoelectric, photovoltaic, electrodynamic, piezoelectric, and other EH technologies and applications, including the use of energy independent electric vehicles (EIVs) that never plug in and are currently mainly solar, like those roads. On the days before and after the event, masterclasses also teach many aspects of EH.

IDTechEx Research has released two reports on EIVs—the overview “Energy Independent Vehicles 2016-2026” and the technology drill down “Energy Independent Electric Vehicle Technology Roadmap 2016-2036.” Another angle is how conventional vehicles cannot cope with a lot of energy harvesting, but modifying them into so-called 48-V mild hybrids makes it all possible. That is covered in the  new IDTechEx Research report “Mild Hybrid 48V Vehicles 2016-2031” and also at the event.

About the Author

Rick Nelson | Contributing Editor

Rick is currently Contributing Technical Editor. He was Executive Editor for EE in 2011-2018. Previously he served on several publications, including EDN and Vision Systems Design, and has received awards for signed editorials from the American Society of Business Publication Editors. He began as a design engineer at General Electric and Litton Industries and earned a BSEE degree from Penn State.

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