An artist’s rendition of the frontal view of SCORE
The £2 million (Rs 16 crore approx) Stove for Cooking, Refrigeration and Electricity (SCORE) project brings together experts from across the world to develop a wood-powered generator capable of both cooking and cooling food. By developing an affordable, versatile domestic appliance, SCORE aims to address the energy needs of rural communities in Africa and Asia, where access to power is extremely limited.
Across the world, two billion people use open fires as their primary cooking method. These fires have been found to be highly inefficient, with 93 per cent of the energy generated being lost. And when used in enclosed spaces, smoke from the fires can cause health problems.
Led by the School of Electrical and Electronic Engineering at The University of Nottingham in UK, the project team will use thermoacoustic technology for the first time to convert biomass fuels into energy, powering the stove, fridge and generator.
What is Thermoacoustics?
Thermoacoustics refers to the generation of sound waves through the non-uniform heating of gas – such as the ‘singing’ of hot glass vessels which can be heard during the glass blowing process. This phenomenon has been known for centuries, but could offer new possibilities in the energy conversion process.
The concept of the proposed device is based on proven thermoacoustic engines and refrigerators developed for applications such as combustion-fired natural gas liquefaction and radioisotope-fuelled electric power generation.
Using thermoacoustic technology is a more efficient way of using wood as a fuel than using an open fire to cook. It produces less pollutants. The device will also have few moving parts making it more reliable.
This moving part – the linear alternator – would be developed at the University in conjunction with GP Acoustics, a company which produces loudspeaker equipment.
“Two things excite me about this project: First, we’re taking technology concepts from satellite and military
applications to deliver appropriate technology to some of the world’s poorest rural communities. And second, we’re integrating technologies in a novel way to deliver a totally new concept in energy conversion,” said Professor Mark Johnson of the University’s School of Electrical and Electronic Engineering.
“One of the biggest engineering challenges will be to ensure that the majority of the developed system can be built and maintained within the community that uses it,” he added.
HOW IT WORKS
The project will work with other UK universities as well as governments, universities and civil organisation across Africa and Asia, many of whom have already offered support. This collaboration will ensure the device is affordable, socially acceptable and that it has scope for communities to develop businesses to manufacture and repair locally.
Professor Maksud Helali, Head of the Department of Mechanical Engineering at the Bangladesh University of Engineering and Technology has offered his support.
“Bangladesh’s energy infrastructure is relatively small and inefficient, even to low income standards, and its access to energy is difficult,” he said.
“An efficient, expanding energy system is essential for accelerated economic growth and poverty alleviation. Industry and commerce depend on readily available, reliable, reasonably-priced energy to operate and expand. It will improve the quality of people’s lives,” he added.
Researchers from Los Alamos Laboratories – a leader in thermoacoustic technology – are also supporting the project. The SCORE consortium is funded by UK’s Engineering and Physical Sciences Research Council as part of its initiative on energy and international development.