Simple ‘blast’ fences called baffles could deliver improvements in air quality for people living near airports, new research has found.
Placed behind a runway, the baffles could serve as a ‘virtual chimney’, funnelling emissions from aircraft engines upwards where they can disperse more effectively, thereby reducing the environmental impact on people living nearby.
Prototype baffles have been tested by a team of researchers from Manchester Metropolitan University, Cranfield University, the University of Southampton and the University of Cambridge, with funding from the Engineering and Physical Sciences Research Council (EPSRC).
After preliminary wind tunnel testing of various baffle shapes carried out by Cranfield University, an array of three rows of baffles was tested using laser scanning (Lidar, which is the optical equivalent of Radar) and chemical sensor techniques at Cranfield Airport in Bedfordshire. This demonstrated that the aircraft exhaust plume could be made to leave the ground within the airport’s boundary fence, using prototype baffles of less than a man’s height and constructed out of low-cost agricultural windbreak netting on lightweight frames.
Dr Mike Bennett, who led the project, says: “Airfield surfaces are typically covered with grass, over which the wind can blow freely. An array of baffles makes the surface rough in an aerodynamic sense. This sucks the momentum out of the exhaust jet, allowing its natural buoyancy to come into play. By suitably angling the baffles, we can also give the exhaust an upwards push, encouraging it to rise away from the ground.
“The baffles we tested were tilted at angles between 40° and 60° in order to optimise this vertical flow – and to ensure the baffles didn’t blow over! Although the exhaust will still disperse to the ground eventually, it will do so at a lower concentration. We might hope to see a reduction in surface concentrations of around 50 per cent at the perimeter fence behind the place where aircraft are taking off.”
Testing baffles at Cranfield airport
Long-term ground-level nitrogen dioxide (NO2) concentrations around many major airports in Europe already exceed the legal limit enforced by the EU.
The aim of the trial was essentially to test the baffles’ aerodynamics. As the prototype installation was temporary, it was constructed very differently from how a permanent installation might be made. Each baffle must be sufficiently robust to withstand the 80-90 knot blast from a jet engine, but flimsy enough to collapse harmlessly if an aircraft were to hit it. In the trial, this was achieved by restricting the prototype baffle widths to about two metres but it would be feasible to make them much narrower in a permanent installation. For full-scale use an area of baffles in the order of a thousand square metres would need to be erected behind a runway.
The tests also showed that the baffles dampened engine noise downstream by a modest amount and were helpful in reducing jet blast on the airport perimeter.
“There’s no reason why baffles couldn’t start to be installed at airports within two or three years,” Dr Bennett says. “From the point of view of local air quality, they represent a quick, cheap supplement to developing low-NOx jet engines.”
The project was carried out under the auspices of the EPSRC-funded Airport Energy Technologies Network (AETN), which was established in 2008 to undertake cutting-edge research in the field of aviation.
Notes for Editors
The development of the baffles has taken place as part of the three year project, under the Research Councils UK (RCUK) Energy Programme, ‘A Study of Practical Abatement Techniques for Exhaust Jets from Commercial Aircraft’, which concluded in the autumn of 2012 and received total EPSRC funding of £413,000. The University of Cambridge provided air quality monitoring expertise for the field tests. The Institute of Sound and Vibration Research in the University of Southampton carried out the acoustic studies.
The aircraft used in the field tests at Cranfield Airport was the Natural Environmental Research Council’s (NERC) Facility for Airborne Atmospheric Measurements, a four-engined BAe146. The aircraft took off 12 times in all and on each occasion burned its engines for 5 -15 seconds at the end of the runway prior to take-off.
Lidar is the optical equivalent of radar. A pulsed ultra-violet laser beam was scanned through the exhaust plume in order to monitor the plume’s dispersion.
The initial projects associated with the AETN were the outputs of an EPSRC Sandpit event in November 2009. Sandpits are intensive discussion forums where free thinking is encouraged in order to delve deep into specific issues and identify innovative solutions.
The Engineering and Physical Sciences Research Council (EPSRC) is the UK’s main agency for funding research in engineering and physical sciences. EPSRC invests around £800 million a year in research and postgraduate training, to help the nation handle the next generation of technological change. The areas covered range from information technology to structural engineering, and mathematics to materials science. This research forms the basis for future economic development in the UK and improvements for everyone’s health, lifestyle and culture. EPSRC works alongside other Research Councils with responsibility for other areas of research. The Research Councils work collectively on issues of common concern via Research Councils UK.
The Research Councils UK (RCUK) Energy Programme aims to position the UK to meet its energy and environmental targets and policy goals through world-class research and training. The Energy Programme is investing more than £530 million in research and skills to pioneer a low carbon future. This builds on an investment of £360 million over the past five years.
Led by the Engineering and Physical Sciences Research Council (EPSRC), the Energy Programme brings together the work of EPSRC and that of the Biotechnology and Biological Sciences Research Council (BBSRC), the Economic and Social Research Council (ESRC), the Natural Environment Research Council (NERC), and the Science and Technology Facilities Council (STFC).
The RCUK Energy Programme works closely with more than 500 public and private sector organizations and presently has 1,100 active collaborative projects. The Programme is helping the UK government make evidence-based decisions and policy.
Manchester Metropolitan University is the largest campus-based undergraduate university in the UK, with a total student population of more than 37,000 and an emphasis on vocational education and employability. With a history dating back 150 years, it was awarded university status in 1992.
The University of Southampton is a leading UK teaching and research institution with a global reputation for leading-edge research and scholarship across a wide range of subjects in engineering, science, social sciences, health and humanities.
With over 23,000 students, around 5000 staff, and an annual turnover well in excess of £435 million, the University of Southampton is acknowledged as one of the country's top institutions for engineering, computer science and medicine. We combine academic excellence with an innovative and entrepreneurial approach to research, supporting a culture that engages and challenges students and staff in their pursuit of learning.
The University is also home to a number of world-leading research centres including the Institute of Sound and Vibration Research, the Optoelectronics Research Centre, the Web Science Trust and Doctoral training Centre, the Centre for the Developmental Origins of Health and Disease, the Southampton Statistical Sciences Research Institute and is a partner of the National Oceanography Centre at the Southampton waterfront campus.
For more information contact:
Dr Mike Bennett, Manchester Metropolitan University, tel: 0161 247 6727.
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