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Lifeboats benefit from reinforcement
applications news
New future for wind generated A COMPOSITE disc joint which
are able
is said to enhance
electricity.
of wind
the viability
generated
electrical
power has been developed
by
to generate 1.5 MW of
“This disc is a product
of
our work in the use of compos-
UK firm GKN Technology. The company has exploited
ites for car components,” says GKN’s Dr Andrew Pollard. “Our
the
breakthrough
properties
of fibre
forced composites shaft coupling to
reduce
rein-
in a drive-
that is claimed
cost,
weight
and
materials
usage and
operating
efficiency. The cou-
pling is manufactured press moulding
improve by hot
of a glass/epoxy
preform which has controlled fibre
orientations
to provide
was to
design
a coupling which remains cool even when transmitting
1.5 MW
of power. It is this unique property
which
has
overcome
a
major obstacle in the design of very
large,
efficient
turbines
which are critical to the future of this energy source.” The automotive
version
of
the desired properties.
the coupling
The disc joint is a critical component in constructing larger and more efficient wind
used in motor sports and is under evaluation by car manufacturers. The joint is also
turbines which are more than 90 m high with rotor blades of 70 m in diameter. The turbines
being considered for other applications, including cooling and marine towers, pumps
can be sited far out to sea and
propulsion.
Lifeboats
electricity
has already been
GKN’s composite disc joint i: of more efficient wind turbines.
benefit from reinforcement
FENDERS for lifeboats, currently being built in Sweden, are being constructed from a composite of carbon fibre reinforced
polyurethane, supplied by Hyperlast Ltd. Using novel construction techniques in the hull and fender areas the designers
at the Swedish Sea Rescue Institution (SSRI) have enhanced the stability of the vessels. As a permanent fixture on the vessel the design required the fender to be solid and puncture proof, properties provided
ing of woven glass fibre layered
by Hyperplast’s reinforced polyurethane, recommended to SSRI by Danish firm PUR Teknik. The fender is constructed with a ‘D-section’ design on the hull
with epoxy vinyl ester. “We have been sweating
with layers of foam cut to shape and covered with coatings of carbon fibre reinforcement and sprayable polyurethane elastomer.
Slightly
narrow
at the
bow and the front quarter
of
REINFORCEDplastics
Jan
uary 19 99
to overcome processing problems with the use of carbon fibre for the woven reinforcement in the polyurethane elastomer fenders,” says Stein Neilson a director of PUR Skovgaard in Teknik of Denmark. “We have found that allows the technique our
the stern the fender increases in depth to a maximum of approx-
Hyperlast polyurethane and reinforcement to work together, enhancing the tear and penetration resistance of the final
imately 700 mm.
composite.”
the boat the fender gradually widens along the sides. Towards
4
The vessel’s hull, deck, tanks, motorbeds, bulkheads and inner stiffening ribs are constructed from a sandwich structure consisting of polyvinyl chloride (PVC) foam with an outer coat-
New future for wind generated A COMPOSITE disc joint which
are able
is said to enhance
electricity.
of wind
the viability
generated
electrical
power has been developed
by
to generate 1.5 MW of
“This disc is a product
of
our work in the use of compos-
UK firm GKN Technology. The company has exploited
ites for car components,” says GKN’s Dr Andrew Pollard. “Our
the
breakthrough
properties
of fibre
forced composites shaft coupling to
reduce
rein-
in a drive-
that is claimed
cost,
weight
and
materials
usage and
operating
efficiency. The cou-
pling is manufactured press moulding
improve by hot
of a glass/epoxy
preform which has controlled fibre
orientations
to provide
was to
design
a coupling which remains cool even when transmitting
1.5 MW
of power. It is this unique property
which
has
overcome
a
major obstacle in the design of very
large,
efficient
turbines
which are critical to the future of this energy source.” The automotive
version
of
the desired properties.
the coupling
The disc joint is a critical component in constructing larger and more efficient wind
used in motor sports and is under evaluation by car manufacturers. The joint is also
turbines which are more than 90 m high with rotor blades of 70 m in diameter. The turbines
being considered for other applications, including cooling and marine towers, pumps
can be sited far out to sea and
propulsion.
Lifeboats
electricity
has already been
GKN’s composite disc joint i: of more efficient wind turbines.
benefit from reinforcement
FENDERS for lifeboats, currently being built in Sweden, are being constructed from a composite of carbon fibre reinforced
polyurethane, supplied by Hyperlast Ltd. Using novel construction techniques in the hull and fender areas the designers
at the Swedish Sea Rescue Institution (SSRI) have enhanced the stability of the vessels. As a permanent fixture on the vessel the design required the fender to be solid and puncture proof, properties provided
ing of woven glass fibre layered
by Hyperplast’s reinforced polyurethane, recommended to SSRI by Danish firm PUR Teknik. The fender is constructed with a ‘D-section’ design on the hull
with epoxy vinyl ester. “We have been sweating
with layers of foam cut to shape and covered with coatings of carbon fibre reinforcement and sprayable polyurethane elastomer.
Slightly
narrow
at the
bow and the front quarter
of
REINFORCEDplastics
Jan
uary 19 99
to overcome processing problems with the use of carbon fibre for the woven reinforcement in the polyurethane elastomer fenders,” says Stein Neilson a director of PUR Skovgaard in Teknik of Denmark. “We have found that allows the technique our
the stern the fender increases in depth to a maximum of approx-
Hyperlast polyurethane and reinforcement to work together, enhancing the tear and penetration resistance of the final
imately 700 mm.
composite.”
the boat the fender gradually widens along the sides. Towards
4
The vessel’s hull, deck, tanks, motorbeds, bulkheads and inner stiffening ribs are constructed from a sandwich structure consisting of polyvinyl chloride (PVC) foam with an outer coat-