Research Council ‘Sandpits’

Sandpits are an increasingly popular choice for the distribution of Research funding by RCUK. I have just been part of an EPSRC evaluation exercise on Sandpits, so I thought I would dig some photos out of the archive and give an idea of what goes on, which I hope is helpful to those unfamiliar to this process.

PIC1: Participants at the 'Low Carbon Airports' Sandpit putting together the mind map at the end of day 1

I’ll deal with the application process in another blog, as it requires a different approach to conventional grant applications. My experience is with EPSRC sandpits, which are held in country hotels with large function facilities.

PIC1 illustrates the state of play towards the end of day 1 of the EPSRC ‘LowCarbon Airports’ Sandpit which was held towards the end of 2008. At this point, we had checked in, completed some ice-breakers, and in groups had started to brainstorm the issues associated with the theme. The yellow cards on the floor are the outputs of this process which are now being moved around and coalescing into challenges (PIC2).

 

PIC2: Part of the mind map relating to environmental issues

The process is one of the most intensive and tiring experiences. Starting at 9.00, the activities run generally until 18.00, however that’s when the hard work really starts, with clusters working long into the night. Actually in some cases, all night!.

Be prepared to do a lot of presenting! The ideas, as they coalesce are repeatedly presented by their champions and honed by criticism (both positive and negative) from the floor. It’s at these points that clear projects and project groupings start to emerge (PIC3).

Who’s there?

PIC3: A project definition and grouping starting to emerge at the Sandpit

There are generally three groups of attendees:

Academics who are the focus of the Sandpit

Facilitators – a professional team which runs the Sandpit and guides the process through its stages to fruition

Stakeholders – Industry and commercial interest groups are represented to maintain the applicability of the outcomes

Interestingly, in the background of PIC3 is a poster which I put up with points which are highly salient golden rules for Sandpit participants on all sides:

Stakeholders – ‘suspend disbelief’ in impracticalities

Issues – problems rather than solutions

Academics – ‘forget’ initial preferences and objectives – think outside the box

PIC4: L-R Prof Qing-Chang Zhong, Prof Edmund Burke and Prof Paul Stewart present on 'Integrating and Automating Airport Operations' which was successfully funded

All of which is intended to facilitate the creative process. By day 3, a number of projects have started to emerge, with a core set of champions, loose ‘memberships’ and plenty of ‘floating voters’. Essentially, there is a fixed budget for each sandpit, and open competition for funding, so the process is both collaborative and highly competitive. In this case, there was a budget of £3.4M, with 10 strong contenders emerging….

Roger Gardner, Sandpit Director and Director of the Omega Partnership addresses a project presentation session

Now the strategic ‘haggling’ between individuals and groups begins, as the competition increases to produce credible,fundable projects, and also to maximise individual involvement. A word of caution here is credibility. There is no difference between this part of the process and any other proposal procedure. Not only is a well thought out project plan with credible partnerships an absolute necessity, but also the crucial aspects of adventure, risk and most importantly ‘risk mitigation strategies’.

Unique to this process is that funding is allocated on the final day of the Sandpit, so all potential projects must be fully costed, with finalised members, objectives and project plans.

Prof Paul Stewart presenting the costed version of 'Airport Energy Technologies Network' which was successfully funded

There is no limit to the number of projects which you can propose, or the number of projects in which you can be involved. However there is generally a strong steer from the Stakeholders as to the preferred projects and groupings as they develop. Finally, the projects are ranked in preferential order, and a steer is given as to what adjustments need to be made to costings on the individual projects.

Roger Gardner, Sandpit director, giving out the good and bad news

In this Sandpit, 10 projects were proposed, with 7 being funded to a total of £3.4M. Three of the projects are currently running here at the University of Lincoln in the School of Engineering.

Most importantly, 19 out of the 22 participants came away with something to show for all the effort, ranging from studentships up to PI of large multi-centre projects.

Winners and losers: 7 successful and 3 unsuccessful proposals

All in all a very positive experience on the whole. In particular, the sandpit sparked multi-disciplinary, inter university collaboration which has acted as gearing for subsequent collaborative projects. all that’s left to do after the event is to make sure you get your full proposal in through the JeS system in time!

You can find out more about the funded projects via the Airport Energy Technologies Network (AETN) which is hosted in the School of Engineering at the University of Lincoln:

Airport Energy Technologies Network (AETN) LInk

The Lotus Free Piston Engine project story part I

Graham Smith, Technician in Aeronautical and Automotive Engineering at the University of Loughborough brings in the new engine

The idea to develop a free piston engine has a long history, mainly focusing on two-stroke designs with a combustion chamber at each end of a linear motor generator. the main idea is to remove the physical constraints imposed by conventional crankshaft based engines, reduce the mechanical losses to improve the engine efficiency, and to introduce elements of piston trajectory control to allow advanced combustion control.

As if that wasn’t challenging enough, Jamie Turner of Lotus Engineering and I had the idea of pushing the envelope even further, to create a single combustion chamber, four-stroke design. This developed from the fact that two-ended designs are generally constrained to operate via an oscillating principle akin to simple harmonic motion for increase efficiency. In our view, we wanted to push the technology of the possible even further, and design what was originally called the Lotus Active Crank Train (ACT) and eventually became the Zero Constraint Free Piston Energy Converter.

We originally applied to the EPSRC ‘Adventure Fund’, but the application was rejected on the grounds that the proposal was ‘too adventurous’! The EPSRC however invited us to re-submit, and the project became…

EPSRC Grant: GR/S97507/01 ‘Zero Constraint Free Piston Energy Converter
PI: Paul Stewart. Co-Investigator: D. Howe. (University of Sheffield) Collaborating University: Dr Rui Chen, Dept. Aeronautical and Automotive Engineering, University of Loughborough UK. Collaborating Company: Lotus Engineering, Consortium Project Manager: Paul Stewart.

P. Stewart: £326,00, R. Chen £260,000, Lotus Engineering Contribution: £330,000

Rui Chen wondering what he has got himself involved with!

I was a Junior Lecturer at the time in the Electrical Machines and Drives Group at Sheffield University. I needed an engines/combustion collaborator, and since I had worked at Loughborough as a Post-doc, searched their web-site and approached Dr Rui Chen who was then also a Junior Lecturer (now Professor of Low Carbon Power Engineering) in the Department of Aeronautical and Automotive Engineering at the University of Loughborough. This was the start of a research relationship and friendship which lasts to this day.

In order to ‘de-risk’ the project, the free-piston was originally tethered to the crankshaft of a General Motors 1.8l engine so that we could conduct our initial development in relative safety. The engine as delivered from lotus is pictured above, the free-piston part (nick named the ‘rocket launcher’) is the tube and cylinder head sticking up from the GM crankcase. In the next part of the story, we get it running, and discover we can look at some hitherto unattainable fundamental aspects of combustion.