Developed by a consortium of British firms as part of the UK government-backed Flywheel Hybrid System for Premium Vehicles (FHSPV) program, the mechanically-driven flywheel system delivers a claimed 80 horsepower of recovered energy from its self-contained hybrid module.
The consortium says mechanical hybrids solve many of the challenges associated with electrified vehicles. The firms claim the flywheel setup eliminates cost, weight, packaging and recycling issues associated with the batteries in conventional hybrids. Prodrive’s head of vehicle engineering, David Hemming, states:
The research shows the potential of mechanical hybrids as an affordable alternative to battery hybrids. Both the fuel economy results and the driveability are impressive, even with early-stage calibrations and no other design optimization.
The FHSPV vehicle recovers energy via its rear differential and continuously variable transmission and routes that juice into a flywheel. When the driver reapplies the accelerator pedal, the CVT transfers energy back to the wheels. The flywheel and its associated drive system are installed adjacent to the rear axle, in a space normally occupied by the spare tire. The whole system reportedly weighs in at less than 176 pounds.
Designed by Flybrid Systems, the flywheel is constructed from carbon composite and operates in a partial vacuum, allowing it to spin at up to 60,000 rpm. The CVT is built by transmission experts Xtrac and Torotrak. Engineering consultants Prodrive and Ricardo handle the system’s configuration and integration and automakers Jaguar, Land Rover and Ford pitched in to develop the FHSPV.
Improvements in fuel economy of up to 22.4 percent (in the new ARTEMIS test cycle, which represents typical real-world usage today) have been demonstrated by a research vehicle fitted with a flywheel hybrid system including stop-start. Developed by a consortium of British companies as part of the Government-supported Flywheel Hybrid System for Premium Vehicles (FHSPV) programme, the mechanically-driven flywheel system delivers up to 80bhp (82PS, 60kW) of recovered energy from a self-contained hybrid module.
In the industry-standard NEDC cycle, the flywheel hybrid including stop-start achieved an 11.9 percent improvement.
The consortium believes that mechanical hybrids solve many of the challenges associated with electric hybrids. There is no inefficient conversion of energy from kinetic to electrical to chemical and back. And the cost, weight, packaging and recycling issues associated with batteries are also eliminated.
“The research shows the potential of mechanical hybrids as an affordable alternative to battery hybrids,” confirms Prodrive’s head of vehicle engineering, David Hemming. “Both the fuel economy results and the driveability are impressive, even with early-stage calibrations and no other design optimisation.”
The FHSPV engineering development vehicle recovers energy via the rear differential through a continuously variable transmission (CVT) into a high-speed flywheel. When the driver reapplies the accelerator, the CVT smoothly transfers the energy back to the wheels. The flywheel and its drive system are installed adjacent to the rear axle, in the space normally occupied by the spare wheel and the whole system weighs 80 kg. Minimal body and packaging changes were required to integrate the system. There is no change to the driveline configuration.
Designed by Flybrid Systems, the flywheel is constructed from carbon composite and operates in a partial vacuum, allowing it to spin at up to 60,000rpm. The CVT, which manages the flywheel’s speed and the flow of energy in each direction, has been built by precision-engineering firm Xtrac using proven traction drive technology from Torotrak.
Automotive technology specialist Prodrive is responsible for the system’s configuration and integration into the vehicle. Prodrive also developed the system’s complex control strategy and software including preliminary calibrations. Ricardo and Ford provided specialist expertise around alternative technologies and applications.
“There is growing support for flywheel hybrid systems across the industry, fundamentally driven by affordability,” said Torotrak CEO Dick Elsy. “From Torotrak’s work in this market, the directional costs of the system look to be less than half of the cost of equivalent battery/electric hybrids. A mechanical hybrid with stop/start, at a transaction price that makes sense, has significant potential for widespread application in the drive to reduce CO2.”
ABOUT THE TECHNOLOGY STRATEGY BOARD:
The Technology Strategy Board (which part-funded this programme) is a business-led executive non-departmental public body, established by the government. Its role is to promote and support research into, and development and exploitation of, technology and innovation for the benefit of UK business, in order to increase economic growth and improve the quality of life. It is sponsored by the Department for Business, Innovation and Skills (BIS). For further information please visit www.innovateuk.org
