First commercially viable exhaust heat recovery system demonstrated at Brighton University

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Rig trials to validate small scale 20kWe system which will be showcased at Linear Power 2015

Brighton, UK, 16th June 2015... A new type of automotive waste heat recovery system has been fired up on a recently commissioned test rig at the University of Brighton. The organic rankine cycle test rig uses a novel linear free piston expander to overcome the technical and economic barriers to using rankine cycle technology for automotive waste heat recovery. Initially configured to simulate heavy duty truck applications, the 20kWe system can be scaled down to 3kWe for light duty trucks and passenger cars. It has the potential to become the first commercially viable method to capture heat energy normally wasted in the exhaust, improving the efficiency of all types of vehicles.

The results from rig tests are expected to confirm the system’s potential to convert the high grade heat in the exhaust into electrical power, which can contribute to either powertrain or auxiliary loads. By providing physical test results to validate simulation tools, the data will allow Libertine to model specific customer applications with high confidence.

The test rig and linear free piston expander technology will form a centrepiece at Linear Power 2015, billed as the world’s first technology forum for linear power systems technology researchers and application developers.

“Visitors to Linear Power 2015, held in Brighton in September, will be able to see the system working in the lab, review the results and discuss potential applications,” said Libertine’s CEO, Sam Cockerill. “As part of our continuing relationship with Brighton University, we are co-sponsoring the Linear Power event together with NIDEC SR drives, an industrial partner on the heat recovery demonstration project.”

The project at Brighton, part-funded by the UK government through Innovate UK, uses a pair of Libertine’s linear free-piston expanders in an ethanol rankine cycle to extract energy from a hot gas source which represents the flow of a vehicle’s exhaust under a range of steady-state conditions. A free piston expander system has a number of advantages over turbo-generator systems. The operational flexibility and two-phase flow tolerance permits useful output to be generated during part load and transient conditions, which represent the majority of drive cycle conditions. In addition, the system provides a larger single-stage expansion ratio which suits ethanol/water rankine cycles.

Libertine’s piston geometry, electrical machine design and cylinder construction are ideally suited to rankine cycle applications. By integrating the electrical machine into the cylinder wall, rather than attempting to isolate it with seals, the high friction losses often encountered by free piston engine developers are dramatically reduced. Libertine’s expander also uses a novel ‘transfer valve’ arrangement to meter the high pressure working fluid into the expansion chamber without the need for active inlet valve control. This offers a simpler and more efficient solution than alternative inlet valve arrangements.

Initial results from the trials will be published during Q3 this year, with completion of the tests scheduled for the year end. Further information about the Linear Power 2015 event can be found at http://www.linearpower.org/

About Libertine
Libertine makes ‘Linear Power Systems' that enable the development of low cost, high efficiency appliances for small scale power generation, heating, cooling and transport. Libertine’s technologies combine linear electrical machines with linear gas expander systems and can be applied in a wide range of small scale energy conversion applications. Libertine’s patented and lab-proven technology dispenses with the crankshaft and other mechanical powertrain components that contribute to the high cost and low efficiency of today’s small power generation technologies.

Press contact:
Richard Doherty of Market Engineering
+44 (0)1295 277 050
Richard.doherty@m-eng.com

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