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Professor Julian Vincent, a biologist, and Dr George Jeronimidis, an engineer,
demonstrate how cross faculty brainstorming can elicit valuable results
One of the differences
between engineers and biologists is that engineers are faced with the
problem of making something and they’ve got to look for answers whereas
biologists are looking at the end product of evolution, so they’re looking
at a whole range of answers to problems and they’ve got to try and work
out what the question was.
Dr George Jeronimidis explains that he is trying to imitate some of the function of muscle.
"The
idea is to use some of the features of muscles in designing engineering
components of variable stiffness. Muscle is more or less the architype
system for variable stiffness because you can hold a glass of beer and
it would be very stiff and you can release it and it would be very soft."
Muscle is something which is able to change in volume, and as the change in volume takes place, a contraction is produced. The contraction is transmitted to a tendon and that is how the force is generated the force.
Prof Julian Vincent says that when it comes to producing systems, nature can give us a good idea of what we might be able to do:
"We have the
idea and then we think well that’s obviously going to be too expensive
to do it the way nature does it because it’s so incredibly complicated
and so much fine detail there that maybe if we did it this way we could
do it more quickly and more cheaply."
The molecular mechanism
for muscle contraction is for the moment way beyond our scientists' reach.
However, they have got materials which can do some of the things that
muscle does i.e. swell. The team has
created a structure of fibres. Inside the cylinder is a gel which is capable
of expanding.
The
whole lot is put in contact with a solvent, for example, immersed in water
so that the gel will absorb the water, and will try to swell out. In swelling
out, the orientation of the fibres will change and it is possible to make
the gel either contract in the long direction and expand laterally or
else contract in diameter and become longer. The swelling of the gel can
be stimulated by applying an electrical field.
Julian hopes that by having an adapted system like this he can use the elements in all sorts of other ways and one of the ways that he'd like to try is in robotics.
George says that where they want to replicate in a mechanical context some of the actions of arms and legs and muscles, they are obliged to use equivalent systems.
He says: "The ones we use normally are not based on active gels – they are based more on springs, chains and gears and wheels, more traditional engineering ones. We developed our own way of thinking of what biology can offer in an engineering context: how to look at biology as a source of inspiration for engineering technical solutions. We looked at something, tried to understand what features make it work and tried to see if there is a benefit to be had somewhere else."
Julian continues:
"Because both the biologist and engineer can bring something different to the party then they can bring something which is outside the normal experience of the other person and the chance of coming up with a novel solution is much greater".
OU Courses
OU
Science Faculty website
Practising
Science (SXR103)
Discovering
Science (S103)
Investigative
Biology (SXR204)
Biology:
Uniformity and Diversity (S204)