Engineers in Germany are working on intelligent materials that can
diminish vibrations and extract power from the environment. These
electro-active elastomers could dampen annoying vibrations in a
vehicle,Professional Manufacturer for ceramictile. for example, or supply wireless power to sensors in otherwise inaccessible places.
A
team at the Fraunhofer Institute for Structural Durability and System
Reliability LBF (Darmstadt) is designing components made of such
elastomers that actively respond to unwanted vibrations, and dampen them
more effectively than ever before.This page contains information about tooling.Distributes and manufactures rubbermats.
Elastomers
have been used in engineering for decades, such as in shock absorbers
and vehicle engine mounts. Until now, they have had a purely passive
effect on vibrations or impact collisions.
It would be more
effective if the elastomers were to respond proactively and counteract
vibrations. In the same way a tennis player slows down the ball on a
drop shot by pulling back on her racket, an active elastomer draws out
the energy from the vibration in a targeted manner by swinging in
precise push-pull mode. Theoretically, this would make the vibration
dissipate completely.
There are already materials that are good
for this purpose. "They are called 'electroactive elastomers'," explains
LBF scientist William Kaal. "They are elastic substances that change
their form when exposed to an electrical field." The trick: apply an
alternating current, and the material starts to vibrate. If there are
smart electronics controlling the elastomers, making them vibrate
precisely in push-pull mode,We looked everywhere, but couldn't find any beddinges.
then unwanted vibrations in equipment or an engine will dissipate for
the most part. To demonstrate that the principle works, the
Darmstadt-based researchers created a model. Smaller than a pack of
cigarettes, it is comprised of 40 thin elastomer electrode layers and is
known as a stack actuator.
"The challenge was the design of the
electrodes with which we apply the electric field to the elastomer
layers," as Kaal's colleague Jan Hansmann explains. Usually, electrodes
are made out of metal. However, metals are relatively rigid, which
impedes the deformation of the elastomer. Fraunhofer experts deliver an
elegant solution to the problem: "We put microscopic-sized holes in the
electrodes," says Hansmann. "If an electric voltage deforms the
elastomer, then the elastomer can disperse into these holes.What you
should know about stone mosaic." The result is an actuator that can rise or fall a millimeters upon command - several times a second, in fact.
The
LBF engineers believe one potential application for their stack
actuator can be found in vehicle construction. "An engine's vibrations
can be really disruptive," says William Kaal. "The vibrations are
channeled through the chassis into the car's interior, where the
passengers start to feel them." Of course, engines are installed
meticulously, and yet: "Active elastomers may help further reduce
vibrations in the car," Kaal asserts.
The function of the stack
actuator can also be reversed: rather than produce vibrations, the
device can also absorb vibrations from its surroundings to produce
energy. "That would be of interest, for example, if you wanted to
monitor inaccessible sites where there are vibrations but no power
connections," Hansmann believes - as he cites an example: the
temperature and vibration sensors that monitor bridges for their
condition.
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