- Email: [email protected]
Reinforced plastics prevail on the waterfront
Reinforced plastics prevail on the waterfront Few materials can withstand the onslaught infrastructure
needs regular maintenance.
durable replacement
of the sea for long and marine Reinforced plastics can provide a more
for the wood, steel and concrete materials traditionally
used.
George Marsh reports. then
poison
ability
of
marine exploiting
life, the unsustainrainforest
woods - species like teak being
ere sea meets land is a zone of strife and unruly forces. Few materials can long survive the unrelenting onslaught of sea waves, wash and impact from vessels, corrosive salts, sand and pebble erosion, high atmospheric humidity, inter-tidal wetting and drying, sun and marine borers exacerbated by the immense forces of tempest and storm. Marine infrastructure constantly has to be buttressed and renewed. One class of materials that is helping it to last longer is reinforced plastics, To contribute in this harsh environment, fibre reinforced plastics (FRPs) have to substitute for or augment one or more of the traditional marine infrastructural materials - wood, steel and concrete. Drivers for replacing the most ubiquitous, wood, include the rapid deterioration of most woods, the leaching out of preservatives like creosote and chromated
30
copper arsenate
REiNFORCEDplastics
(CCA) which Ju n e 2 0 0 2
ate post-war
years, Disposing
the best
vative-treated
wood accounts
of preserfor a signifi-
wood burns. Steel spalls and corrodes away whilst even concrete, though it will never be displaced as a key material, can break up and eventually disintegrate.
cant proportion of this and the Navy wants any replacement to be environmentally benign as well as strong and cost effective. A multidisciplinary research team led by the Naval Research Laboratory but also involving the Naval Facilities
Wood
Service Centre, the United States Forestry Service, the Universities of Washington
According to one informed estimate, over US$l billion needs to be spent on piers in New York alone, where old wooden structures are falling prey to general marine wear and tear plus the depravations of
State, Maine and Honeywell Inc and been investigating plastic composites. University’s Wood
marine borers, particularly Teredo worm which devour woods from the inside by
eering Laboratory (WMEL), for instance, brings its acknowledged expertise in inno-
eating along the grain. Perversely, these organisms are thriving as a result of water clean-up programmes. With several piers
vative structural systems utilising the collaboration.
for resisting aggressive waterfront tions - and the readiness with
Railings at Niagara Falls, produced by the pultrusion process. (Picture courtesy of Owens Corning: www.owenscoorning.com.)
date back to World War II or the immedi-
hardcondiwhich
in Brooklyn, for instance, almost completely consumed by borers, agencies have been looking to alternative materials like recycled plastic and FRP as a remedy. Steel and concrete are too damaging for boats coming alongside but, like wood, pliable polymer materials yield momentarily to contact. Authorities in New York and around the world are keeping a close eye on US Navy efforts to reduce maintenance costs for its large amounts of waterfront infrastructure, which includes everything from isolated piers and jetties to full harbour installations. The Navy currently spends $40-50 million annually on replacing treated wood structures, many of which
Pennsylvania State; Strandex Corp have a number of woodWashington State Materials and Engin-
wood to
The US Navy currently spends $40-50
million
annually on replacing treated wood structures. One approach being investigated is to recycle ground wood and plastic materials into synthetic deckings, facings and pier support ‘timbers’. In some composites of wood with plastics like PE and polyvinyl lose/lignin
chloride (PVC), wood structure
the celluconstitutes
the fibrous reinforcement while in others man-made fibres are added. Resistance of
0034-36 17fO2/$ - see front matter 0 2002 Nsevier Science Ltd. Ail rights reserved.
Reinforced
such
composites
moisture,
to biological
fire, chemicals
attack,
and other haz-
ards can be impressive
while an advan-
tage of several reinforced
thermoplastics
is that they can be extruded. One company using recyclate sively
is
Virginia-based
International and
Inc
whose
SEAPILE products
recycled
polyester
exten-
matrix
a 100% reinforced
with glass fibre. This GRP system,
said
to offer good abrasion resistance and with ultraviolet (UV) inhibitors incorporated, tropical
is offered wood
as a substitute
for
and timbers
and
pilings
has been used for protecting
bridge and
dock piers. Another
company
active in replacing
maritime wood infrastructure is Hardcore Composites. As an example, it produced composite piles used in reconstructing historic New Castle pier in Delaware. Composite tubular piles of 12 and 18 inch (30 and 45 ?m) diameter designed to carry a new main timber deck were driven in over the remains of the original wood piling and then filled with concrete. Hardcore produced the piles using an adaptation of vacuum-assisted resin transfer moulding (VARTM) and points out that they will not rust or spall, or be affected by the water, weather or marine borers. They should serve, according to the company, for 30-40 years without major repair or replacement, and do not require resurfacing or painting. Similar advantages apply to a replacement for a sheet-metal protected timber pile dolphin that Hardcore produced for the end of another pier, at Lewes, Delaware. diameter
Forty four composite
18 inch piles
(45 cm) installed
together and filled with concrete form a reaction block capable of absorbing the forces generated by 2100-ton ferries moving at three knots. The company has also developed monopiles, an impressive example being a single 80 ft (24 m) long, 5 ft (1.5 m) diameter pile used to replace a cluster of almost a dozen timber piles at Cape May, New Jersey. This can absorb more energy from berthing ships than the previous timber cluster, deflecting
(79 cm)
under
a force
on the waterfront
of
240 000 lbs (110 000 kg). In what was claimed ever use of hybrid piling,
Seaward SEATIMBER
utilize
31 inches
plastics prevail
composites
this company
ed cradle supports beaches,
using
composites. lation,
to be the first
for major outfalls near
E-glass and carbon
Benefits include
fewer supports, outfall
ricated using
finishing
maintenance.
produced
Army Corps of Engineers and glass-carbon
fibre
rapid instal-
minimal
work and low ongoing stormwater
for marine
has also construct-
A
for the US
has 168 glass
pilings which were fab-
with a vacuum Dow Derakane
infusion vinyl
process
ester
resin
and Johns Manville polyisocyanurate foam in a sandwich construction. Stringent
performance
requirements,
driven by anticipated wave loads, were met by using heavy quadraxial glass and hybrid fabrics from Brunswick Technology Inc. Carbon (Zoltek) was used to confer the stiffness needed to minimize deflection in long spans. Piles were finished with a sand-loaded epoxy coating to promote frictional adhesion with sand and underlying soil. Although composite components for this multimillion dollar project cost nearly three times more than standard timber and concrete equivalents would have done, estimates suggest that reduced installation and associated expenses brought total project cost down to 65% less than for a standard installation. There are signs of progress in Europe too. In UK, for instance, a study by HR Hydraulics at Wallingford, UK, called ‘Use of Timber in Coastal and Fluvial Engineering’ is embracing consideration of potential alternatives. A spokesman indicated a number of early uses for FRP wood substitutes in fendering and the meeting faces of dock gates - an example of the latter being in use at Shoreham, a port on England’s south coast. In France, a project in which wooden lock gates have been substituted more completely was the construction of major GRP parts for Voies Navigable de France as part of its restoration of the French canal system. DCN Lorient laid up the woven glass-reinforced isopolyester components
Seapile composite marine piling installed as a replacement to a traditional wood fender pile at a large oil tanker terminal.
by hand in open moulds to create solid laminate gate sections which were then mounted in stainless steel frames. The resulting gates weighed 50% less than conventional units, facilitating their handling, mounting and control in use. Around the world, builders of marina pontoons could be willing prospects for any economically and functionally viable replacement that might emerge for wood decking, which degrades, and concrete which degrades more slowly but is less ‘user friendly’. One such, France’s Poralu Marine, is a leader in composite decking and recently won a contract to supply its product for the Commonwealth Games.
Metal Sea walls are often of metal, generally steel though aluminium has been used too. American designer of aluminium sea walls for more than two decades, Barry Hansen, has more recently engineered
June 2002
REINFORCEDplastics
31
Reinforced
plastics prevail
on the waterfront
other
materials
different
sites,” Hansen there
to the
two
distinctly
corrosive environments comments.
is the saline
tures built in or close to sea water, includ-
environment
of sea-
panels
have
been
driven
muck.”
forcing
intended
pre-stressing
for waterfront
bar (rebar),
applica-
of a suitable along
with
reindesign
track record,
swimming
as
part
of
Strengthening
-
pools
its
Mbrace
Composites
System.
Design using composite rebar requires some adaptation, a fact that has so far inhibited
most designers
instead preferred
to remain
who have
with familiar
creates prospects for a major niche market accounting for many tons of rein-
steel reinforcement.
forced plastic material.
likely to take over from corrosion
Composite
bar is
creep, rupture
Mechanisms
or concrete
such as
crushing
are
as the
immune to the destructive moisture and salt attack which can corrode conventional steel bar, causing it to swell and crack the concrete around it. Experience shows that sometimes even epoxycoated steel rebar is not an adequate
primary failure mechanisms. Fortunately design codes are emerging. The American Concrete Institute’s ‘Guide for and Construction of the Design Concrete Reinforced with FRP Bars’ (ACL 440 lR-01) can be helpful as can
answer while stainless steel, which could be, is too expensive. A representative product which answers the need is C-BARTM from Marshall Industries of Lima, Ohio. Marshall’s patented process combines pultrusion and compression moulding of
‘Eurocrete Modifications to NS3473 When Using FRP Reinforcement’ in
GRP, the resulting rod core being given an outer skin of a urethane-modified vinyl ester which has high resistance to moisture and chemicals, including the alkaline According
surroundings of concrete. to Marshal Industries, C-BAR
has twice the tensile
J u n e 2 0 02
floating
roads and buildings
also offshore platforms,
uses for com-
and
codes and with a growing
REINFORCEDplastics
canals,
and aquariums. Another product is Mbar CFRP rebar rod offered by Master Builders
is reinforcing
concrete
32
walls, piers, jetties,
structures,
the
tion. The development
residential property on a river island. “Composites have better resistance than
retaining
soil that
One of the most promising
composite panels produced by Creative Pultrusions and Alum Bank, Gator has constructed a number of sea walls including one to stop shoreline erosion near a pumping station and another to protect
ing quays,
caissons, decks, piles, bulkheads,
posites
Gator Using
as C-BAR,
“At the first
Concrete
GRP sea walls for his employer, Dock and Marine Inc of Florida.
resistance advantages
this product is said to be suitable for struc-
water and salt air, and at the second, the into is an acidic, organic
Composite piling being used for CIdock installation in Rotterdam. (~icrure courtesyof SeawardInternational/PC Jansen Marine Agencies.)
corrosion
at these
strength
of conven-
Europe and ‘Construction of Concrete Structures Using Continuous Fibre Reinforcing Materials’ in Japan. The USbased Rebar Manufacturers Council offers advice and support for end users. Canada, too, is actively developing the use of FRP substitute for steel reinforcement, which is now seriously corroded in a wide range of concrete infrastructure older than about 30 years. One manifestation of this is the appointment of Professor Brahim Benmokrane, an
tional epoxy-coated steel rebar, at only a quarter the weight. In addition, the composite’s coefficient of thermal expansion is closer to concrete than that of steel. As a bonus, the rebar has a low dielectric constant, making it suitable for applications requiring magnetic transparency, such as foundations for magnetic resonance imaging facilitation, aircraft compass calibration pads, and computer and laser testing facilities. Addressing the same need is ISOROD@ from Pultrall Inc and marketed by Concrete Protection Products Inc of Dallas. With the same weight and
Seapile composite marine piling being installed at US Naval Station in San Diego, California.
Reinforced
plastics
prevail
on the
waterfront
Piles for Pier 12 were made eight
lengths
of cable into
by laying the casting
frame for each pile. These lengths secured
were
at their ends in steel bulkheads
and pre-tensioned after which concrete
with hydraulic
jacks,
was poured into the
frames and allowed to cure. advantage
carries
over glass that it is
impervious
to the alkaline
of concrete.
Dr George Warren, who was
operational
loads
from vehicles and truck-mounted in service. A similar
preferred
over
strengthener rods
accept
attaching
CFRP
out-of-plane
and are buried,
adopted
cranes, solution, sheet
to the deck surface because loads
including
base.
FRP strips and plates less, increasingly
more
has since been
for other installations
a Trident submarine
surroundings
lead engineer for the Pier 12 upgrade, points out that glass fibres, even when
heavy
remained
readily
Carbon, despite its higher cost, has the important
which
used
range
of deteriorating
tures,
as has been
are, neverthefor repairing concrete
reported
a
struc-
previously
protectively coated, tend to lose strength when exposed to an alkaline environment
in Reinforced Plastics. Light composites
and that carbon will therefore be the natu-
need
ral choice
equipment
for pre-stressing
applications.
can be placed by hand, for
bulky that
eliminating
materials might
the
handling
otherwise
pre-
Glass composites, though, will have a major role in piling (albeit sometimes in a hybrid with carbon) and for ancillary items such as gratings and hand rails. The Pier 12 piles are expected to last
vent ship docking and other operations while remedial work is in progress. Downtime is minimal, composites
international specialist in composite materials for infrastructure, as holder of a
50 years, whereas steel cables begin to corrode in less than ten. A report entitled
new industrial research chair at the University of Sherbrooke in Quebec. His mandate is to study FRP composite rein-
‘Demonstration of Advanced Composite Cables for Pre-stressing Applications in Concrete Waterfront Structures’ issued by
in hours. Low weight repairs are also in earthquake zones advantageous where any extra loading on supporting
forcement for concrete infrastructure, and to incorporate monitoring intelligence. As a researcher on the Canadian Intelligent Sensing for Innovative Structures (ISIS)
the US Army Corps of Engineers which collaborated on the project, concluded
Navy
pier structure
made using pultrusion.
(Picture courtesy of Owens Corning:
www.mvensc*rn-
ing.com.)
project Benmokrane, working with industrial partners, embedded fibre-optic sen-
that it had ‘clearly demonstrated the viability, practicality and potential cost-
sors within composite materials used to repair Sherbrooke’s Joffre Bridge. This
effectiveness of using fibre-reinforced composite cables in pre-stressed concrete structures subject to corrosive environments.’ The report included guidelines
enabled strains and other forces to be monitored remotely in real-time, an innovation that the Professor expects will
for the design and construction of composite products, but acknowledged what is still a drawback for composites - the
become important in future composite/concrete programmes. In the USA the armed services have been as proactive as any organization in bringing composites and concrete together. Using glass and carbon fibre
lack of long-term performance industry-wide standards.
hybrid cables to pre-stress concrete is a technique that has been evaluated at the waterfront testbed facility of the US Naval Facilities Engineering Service Center at Port Hueneme, California. In one trial carbon fibre cables were used to internally reinforce 60 ft (18 m) piles
wharf in Pearl Harbour, Hawaii. Epoxy encapsulent was poured into slots cut in the concrete deck, without disturbing underlying steel rebar. The composite rods were then laid and rolled into the
supporting a 1200 ft (365 m), 55 year old pier in the Navy shipyard in San Diego.
34
REINFORCEDplastics
Ju n e 2 0 0 2
being bonded to concrete with epoxies which can reach design strengths with-
data and
Repair and upgrade Similar CFRP rods were Restoration of California
used by ACE to upgrade a
epoxy, which subsequently cured. The slots were topped off with a layer of sand in epoxy binder. It proved possible to carry out the work while the wharf,
Navy pier application: waterfront test site. Structure made by pultrusion. (picture cowtesy of Owens Corning: I
www.owenrcorning.com.) 1
Reinforced
members
can
precipitate
failure
at
times of seismic stress. Another of composites
repair exploiting
the virtues
is the bonding
of pultrud-
ed glass or carbon
fibre
reinforced
provided
is highly
and was given the task of building
resistant
to fatigue and can be
economic
repair,
beams below pier decks. Such beams typ-
tium
ically weigh less than a third the weight
GRP profile
of steel equivalents
replace
and can be lifted into
offers
a European
that
reinforced
concrete.
jacks. A repair of this sort was made as
four
years
part of the Pier 12 experiments
Fiberline
mentioned,
workmen
in
without
conjunction
CFRP tow sheet bonded
glass, carbon
confinement
jackets
Diego)
are used
strength
and
hybrid
Tomorrow’s
at San
be made
with
complex
geometric
and
bridge
the
shear
project
manufactured
over by
AS of Denmark
Infrastructure),
profiles
large cross sections
ASSET was developed
supports,
shapes.
Spain’s IETCC and a work site;
and KTH in Sweden for material ty testing and academic advice.
HIM the
proper-
Looking further ahead, the US Navy faced
with
having
to replace
60% of its pier infrastructure
entirely over the
next decade or two - is considering large (730-740 m long by 30-40 m wide) double-deck
other waterfront structures too. UK’s Mouchel, as leader of the EU project, designed the system. Other partners included Skanska, Sweden, which
a first
deck surface material; providing test facilities
than be supported
for the
solution
England; developing
can
Although
primarily
physical
bridge in Oxfordshire, from the Netherlands,
and
rapid replacement of bridge decks it can, according to Fiberline proprietor Henrik Thorning, be used for jetties and
especially in seismic zones such as in California and Japan. Mitsubishi Chemical Corporation, for instance, targets its REPLARKTMCFRP sheet system at the seismic repair and upgrade market. Elastic modulus is said to be 70% that of steel (105%‘if prepreg is used) but weight
VACUUM
and
Composites
it can
Developed
Reichhold ASSET using resins, (Advanced Structural System for
with
the deck.
(also tried
to increase
of piles
already also
under
Additionally,
using
extruded
is so strong
an EU Brite-Euram
by
consor-
a revolutionary
under
position
are beyond
the overall
on the waterfront
is only a fifth that of steel. The material applied to complex shapes. Finally, for decks that
‘I’
plastics prevail
Navy wants century
and
piers that
will float rather
on piles. Because the
a service life of well over a maintenance
80%
lower
than with conventional piers, advanced composites are likely to figure strongly in the ’21st Century Pier’ being developed under the Navy’s Hybrid Waterfront Structure programme. But this aspect of waterfront engineering must, for the time being, remain another story. n
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RElNFOR@Dplastics
35
needs regular maintenance.
durable replacement
of the sea for long and marine Reinforced plastics can provide a more
for the wood, steel and concrete materials traditionally
used.
George Marsh reports. then
poison
ability
of
marine exploiting
life, the unsustainrainforest
woods - species like teak being
ere sea meets land is a zone of strife and unruly forces. Few materials can long survive the unrelenting onslaught of sea waves, wash and impact from vessels, corrosive salts, sand and pebble erosion, high atmospheric humidity, inter-tidal wetting and drying, sun and marine borers exacerbated by the immense forces of tempest and storm. Marine infrastructure constantly has to be buttressed and renewed. One class of materials that is helping it to last longer is reinforced plastics, To contribute in this harsh environment, fibre reinforced plastics (FRPs) have to substitute for or augment one or more of the traditional marine infrastructural materials - wood, steel and concrete. Drivers for replacing the most ubiquitous, wood, include the rapid deterioration of most woods, the leaching out of preservatives like creosote and chromated
30
copper arsenate
REiNFORCEDplastics
(CCA) which Ju n e 2 0 0 2
ate post-war
years, Disposing
the best
vative-treated
wood accounts
of preserfor a signifi-
wood burns. Steel spalls and corrodes away whilst even concrete, though it will never be displaced as a key material, can break up and eventually disintegrate.
cant proportion of this and the Navy wants any replacement to be environmentally benign as well as strong and cost effective. A multidisciplinary research team led by the Naval Research Laboratory but also involving the Naval Facilities
Wood
Service Centre, the United States Forestry Service, the Universities of Washington
According to one informed estimate, over US$l billion needs to be spent on piers in New York alone, where old wooden structures are falling prey to general marine wear and tear plus the depravations of
State, Maine and Honeywell Inc and been investigating plastic composites. University’s Wood
marine borers, particularly Teredo worm which devour woods from the inside by
eering Laboratory (WMEL), for instance, brings its acknowledged expertise in inno-
eating along the grain. Perversely, these organisms are thriving as a result of water clean-up programmes. With several piers
vative structural systems utilising the collaboration.
for resisting aggressive waterfront tions - and the readiness with
Railings at Niagara Falls, produced by the pultrusion process. (Picture courtesy of Owens Corning: www.owenscoorning.com.)
date back to World War II or the immedi-
hardcondiwhich
in Brooklyn, for instance, almost completely consumed by borers, agencies have been looking to alternative materials like recycled plastic and FRP as a remedy. Steel and concrete are too damaging for boats coming alongside but, like wood, pliable polymer materials yield momentarily to contact. Authorities in New York and around the world are keeping a close eye on US Navy efforts to reduce maintenance costs for its large amounts of waterfront infrastructure, which includes everything from isolated piers and jetties to full harbour installations. The Navy currently spends $40-50 million annually on replacing treated wood structures, many of which
Pennsylvania State; Strandex Corp have a number of woodWashington State Materials and Engin-
wood to
The US Navy currently spends $40-50
million
annually on replacing treated wood structures. One approach being investigated is to recycle ground wood and plastic materials into synthetic deckings, facings and pier support ‘timbers’. In some composites of wood with plastics like PE and polyvinyl lose/lignin
chloride (PVC), wood structure
the celluconstitutes
the fibrous reinforcement while in others man-made fibres are added. Resistance of
0034-36 17fO2/$ - see front matter 0 2002 Nsevier Science Ltd. Ail rights reserved.
Reinforced
such
composites
moisture,
to biological
fire, chemicals
attack,
and other haz-
ards can be impressive
while an advan-
tage of several reinforced
thermoplastics
is that they can be extruded. One company using recyclate sively
is
Virginia-based
International and
Inc
whose
SEAPILE products
recycled
polyester
exten-
matrix
a 100% reinforced
with glass fibre. This GRP system,
said
to offer good abrasion resistance and with ultraviolet (UV) inhibitors incorporated, tropical
is offered wood
as a substitute
for
and timbers
and
pilings
has been used for protecting
bridge and
dock piers. Another
company
active in replacing
maritime wood infrastructure is Hardcore Composites. As an example, it produced composite piles used in reconstructing historic New Castle pier in Delaware. Composite tubular piles of 12 and 18 inch (30 and 45 ?m) diameter designed to carry a new main timber deck were driven in over the remains of the original wood piling and then filled with concrete. Hardcore produced the piles using an adaptation of vacuum-assisted resin transfer moulding (VARTM) and points out that they will not rust or spall, or be affected by the water, weather or marine borers. They should serve, according to the company, for 30-40 years without major repair or replacement, and do not require resurfacing or painting. Similar advantages apply to a replacement for a sheet-metal protected timber pile dolphin that Hardcore produced for the end of another pier, at Lewes, Delaware. diameter
Forty four composite
18 inch piles
(45 cm) installed
together and filled with concrete form a reaction block capable of absorbing the forces generated by 2100-ton ferries moving at three knots. The company has also developed monopiles, an impressive example being a single 80 ft (24 m) long, 5 ft (1.5 m) diameter pile used to replace a cluster of almost a dozen timber piles at Cape May, New Jersey. This can absorb more energy from berthing ships than the previous timber cluster, deflecting
(79 cm)
under
a force
on the waterfront
of
240 000 lbs (110 000 kg). In what was claimed ever use of hybrid piling,
Seaward SEATIMBER
utilize
31 inches
plastics prevail
composites
this company
ed cradle supports beaches,
using
composites. lation,
to be the first
for major outfalls near
E-glass and carbon
Benefits include
fewer supports, outfall
ricated using
finishing
maintenance.
produced
Army Corps of Engineers and glass-carbon
fibre
rapid instal-
minimal
work and low ongoing stormwater
for marine
has also construct-
A
for the US
has 168 glass
pilings which were fab-
with a vacuum Dow Derakane
infusion vinyl
process
ester
resin
and Johns Manville polyisocyanurate foam in a sandwich construction. Stringent
performance
requirements,
driven by anticipated wave loads, were met by using heavy quadraxial glass and hybrid fabrics from Brunswick Technology Inc. Carbon (Zoltek) was used to confer the stiffness needed to minimize deflection in long spans. Piles were finished with a sand-loaded epoxy coating to promote frictional adhesion with sand and underlying soil. Although composite components for this multimillion dollar project cost nearly three times more than standard timber and concrete equivalents would have done, estimates suggest that reduced installation and associated expenses brought total project cost down to 65% less than for a standard installation. There are signs of progress in Europe too. In UK, for instance, a study by HR Hydraulics at Wallingford, UK, called ‘Use of Timber in Coastal and Fluvial Engineering’ is embracing consideration of potential alternatives. A spokesman indicated a number of early uses for FRP wood substitutes in fendering and the meeting faces of dock gates - an example of the latter being in use at Shoreham, a port on England’s south coast. In France, a project in which wooden lock gates have been substituted more completely was the construction of major GRP parts for Voies Navigable de France as part of its restoration of the French canal system. DCN Lorient laid up the woven glass-reinforced isopolyester components
Seapile composite marine piling installed as a replacement to a traditional wood fender pile at a large oil tanker terminal.
by hand in open moulds to create solid laminate gate sections which were then mounted in stainless steel frames. The resulting gates weighed 50% less than conventional units, facilitating their handling, mounting and control in use. Around the world, builders of marina pontoons could be willing prospects for any economically and functionally viable replacement that might emerge for wood decking, which degrades, and concrete which degrades more slowly but is less ‘user friendly’. One such, France’s Poralu Marine, is a leader in composite decking and recently won a contract to supply its product for the Commonwealth Games.
Metal Sea walls are often of metal, generally steel though aluminium has been used too. American designer of aluminium sea walls for more than two decades, Barry Hansen, has more recently engineered
June 2002
REINFORCEDplastics
31
Reinforced
plastics prevail
on the waterfront
other
materials
different
sites,” Hansen there
to the
two
distinctly
corrosive environments comments.
is the saline
tures built in or close to sea water, includ-
environment
of sea-
panels
have
been
driven
muck.”
forcing
intended
pre-stressing
for waterfront
bar (rebar),
applica-
of a suitable along
with
reindesign
track record,
swimming
as
part
of
Strengthening
-
pools
its
Mbrace
Composites
System.
Design using composite rebar requires some adaptation, a fact that has so far inhibited
most designers
instead preferred
to remain
who have
with familiar
creates prospects for a major niche market accounting for many tons of rein-
steel reinforcement.
forced plastic material.
likely to take over from corrosion
Composite
bar is
creep, rupture
Mechanisms
or concrete
such as
crushing
are
as the
immune to the destructive moisture and salt attack which can corrode conventional steel bar, causing it to swell and crack the concrete around it. Experience shows that sometimes even epoxycoated steel rebar is not an adequate
primary failure mechanisms. Fortunately design codes are emerging. The American Concrete Institute’s ‘Guide for and Construction of the Design Concrete Reinforced with FRP Bars’ (ACL 440 lR-01) can be helpful as can
answer while stainless steel, which could be, is too expensive. A representative product which answers the need is C-BARTM from Marshall Industries of Lima, Ohio. Marshall’s patented process combines pultrusion and compression moulding of
‘Eurocrete Modifications to NS3473 When Using FRP Reinforcement’ in
GRP, the resulting rod core being given an outer skin of a urethane-modified vinyl ester which has high resistance to moisture and chemicals, including the alkaline According
surroundings of concrete. to Marshal Industries, C-BAR
has twice the tensile
J u n e 2 0 02
floating
roads and buildings
also offshore platforms,
uses for com-
and
codes and with a growing
REINFORCEDplastics
canals,
and aquariums. Another product is Mbar CFRP rebar rod offered by Master Builders
is reinforcing
concrete
32
walls, piers, jetties,
structures,
the
tion. The development
residential property on a river island. “Composites have better resistance than
retaining
soil that
One of the most promising
composite panels produced by Creative Pultrusions and Alum Bank, Gator has constructed a number of sea walls including one to stop shoreline erosion near a pumping station and another to protect
ing quays,
caissons, decks, piles, bulkheads,
posites
Gator Using
as C-BAR,
“At the first
Concrete
GRP sea walls for his employer, Dock and Marine Inc of Florida.
resistance advantages
this product is said to be suitable for struc-
water and salt air, and at the second, the into is an acidic, organic
Composite piling being used for CIdock installation in Rotterdam. (~icrure courtesyof SeawardInternational/PC Jansen Marine Agencies.)
corrosion
at these
strength
of conven-
Europe and ‘Construction of Concrete Structures Using Continuous Fibre Reinforcing Materials’ in Japan. The USbased Rebar Manufacturers Council offers advice and support for end users. Canada, too, is actively developing the use of FRP substitute for steel reinforcement, which is now seriously corroded in a wide range of concrete infrastructure older than about 30 years. One manifestation of this is the appointment of Professor Brahim Benmokrane, an
tional epoxy-coated steel rebar, at only a quarter the weight. In addition, the composite’s coefficient of thermal expansion is closer to concrete than that of steel. As a bonus, the rebar has a low dielectric constant, making it suitable for applications requiring magnetic transparency, such as foundations for magnetic resonance imaging facilitation, aircraft compass calibration pads, and computer and laser testing facilities. Addressing the same need is ISOROD@ from Pultrall Inc and marketed by Concrete Protection Products Inc of Dallas. With the same weight and
Seapile composite marine piling being installed at US Naval Station in San Diego, California.
Reinforced
plastics
prevail
on the
waterfront
Piles for Pier 12 were made eight
lengths
of cable into
by laying the casting
frame for each pile. These lengths secured
were
at their ends in steel bulkheads
and pre-tensioned after which concrete
with hydraulic
jacks,
was poured into the
frames and allowed to cure. advantage
carries
over glass that it is
impervious
to the alkaline
of concrete.
Dr George Warren, who was
operational
loads
from vehicles and truck-mounted in service. A similar
preferred
over
strengthener rods
accept
attaching
CFRP
out-of-plane
and are buried,
adopted
cranes, solution, sheet
to the deck surface because loads
including
base.
FRP strips and plates less, increasingly
more
has since been
for other installations
a Trident submarine
surroundings
lead engineer for the Pier 12 upgrade, points out that glass fibres, even when
heavy
remained
readily
Carbon, despite its higher cost, has the important
which
used
range
of deteriorating
tures,
as has been
are, neverthefor repairing concrete
reported
a
struc-
previously
protectively coated, tend to lose strength when exposed to an alkaline environment
in Reinforced Plastics. Light composites
and that carbon will therefore be the natu-
need
ral choice
equipment
for pre-stressing
applications.
can be placed by hand, for
bulky that
eliminating
materials might
the
handling
otherwise
pre-
Glass composites, though, will have a major role in piling (albeit sometimes in a hybrid with carbon) and for ancillary items such as gratings and hand rails. The Pier 12 piles are expected to last
vent ship docking and other operations while remedial work is in progress. Downtime is minimal, composites
international specialist in composite materials for infrastructure, as holder of a
50 years, whereas steel cables begin to corrode in less than ten. A report entitled
new industrial research chair at the University of Sherbrooke in Quebec. His mandate is to study FRP composite rein-
‘Demonstration of Advanced Composite Cables for Pre-stressing Applications in Concrete Waterfront Structures’ issued by
in hours. Low weight repairs are also in earthquake zones advantageous where any extra loading on supporting
forcement for concrete infrastructure, and to incorporate monitoring intelligence. As a researcher on the Canadian Intelligent Sensing for Innovative Structures (ISIS)
the US Army Corps of Engineers which collaborated on the project, concluded
Navy
pier structure
made using pultrusion.
(Picture courtesy of Owens Corning:
www.mvensc*rn-
ing.com.)
project Benmokrane, working with industrial partners, embedded fibre-optic sen-
that it had ‘clearly demonstrated the viability, practicality and potential cost-
sors within composite materials used to repair Sherbrooke’s Joffre Bridge. This
effectiveness of using fibre-reinforced composite cables in pre-stressed concrete structures subject to corrosive environments.’ The report included guidelines
enabled strains and other forces to be monitored remotely in real-time, an innovation that the Professor expects will
for the design and construction of composite products, but acknowledged what is still a drawback for composites - the
become important in future composite/concrete programmes. In the USA the armed services have been as proactive as any organization in bringing composites and concrete together. Using glass and carbon fibre
lack of long-term performance industry-wide standards.
hybrid cables to pre-stress concrete is a technique that has been evaluated at the waterfront testbed facility of the US Naval Facilities Engineering Service Center at Port Hueneme, California. In one trial carbon fibre cables were used to internally reinforce 60 ft (18 m) piles
wharf in Pearl Harbour, Hawaii. Epoxy encapsulent was poured into slots cut in the concrete deck, without disturbing underlying steel rebar. The composite rods were then laid and rolled into the
supporting a 1200 ft (365 m), 55 year old pier in the Navy shipyard in San Diego.
34
REINFORCEDplastics
Ju n e 2 0 0 2
being bonded to concrete with epoxies which can reach design strengths with-
data and
Repair and upgrade Similar CFRP rods were Restoration of California
used by ACE to upgrade a
epoxy, which subsequently cured. The slots were topped off with a layer of sand in epoxy binder. It proved possible to carry out the work while the wharf,
Navy pier application: waterfront test site. Structure made by pultrusion. (picture cowtesy of Owens Corning: I
www.owenrcorning.com.) 1
Reinforced
members
can
precipitate
failure
at
times of seismic stress. Another of composites
repair exploiting
the virtues
is the bonding
of pultrud-
ed glass or carbon
fibre
reinforced
provided
is highly
and was given the task of building
resistant
to fatigue and can be
economic
repair,
beams below pier decks. Such beams typ-
tium
ically weigh less than a third the weight
GRP profile
of steel equivalents
replace
and can be lifted into
offers
a European
that
reinforced
concrete.
jacks. A repair of this sort was made as
four
years
part of the Pier 12 experiments
Fiberline
mentioned,
workmen
in
without
conjunction
CFRP tow sheet bonded
glass, carbon
confinement
jackets
Diego)
are used
strength
and
hybrid
Tomorrow’s
at San
be made
with
complex
geometric
and
bridge
the
shear
project
manufactured
over by
AS of Denmark
Infrastructure),
profiles
large cross sections
ASSET was developed
supports,
shapes.
Spain’s IETCC and a work site;
and KTH in Sweden for material ty testing and academic advice.
HIM the
proper-
Looking further ahead, the US Navy faced
with
having
to replace
60% of its pier infrastructure
entirely over the
next decade or two - is considering large (730-740 m long by 30-40 m wide) double-deck
other waterfront structures too. UK’s Mouchel, as leader of the EU project, designed the system. Other partners included Skanska, Sweden, which
a first
deck surface material; providing test facilities
than be supported
for the
solution
England; developing
can
Although
primarily
physical
bridge in Oxfordshire, from the Netherlands,
and
rapid replacement of bridge decks it can, according to Fiberline proprietor Henrik Thorning, be used for jetties and
especially in seismic zones such as in California and Japan. Mitsubishi Chemical Corporation, for instance, targets its REPLARKTMCFRP sheet system at the seismic repair and upgrade market. Elastic modulus is said to be 70% that of steel (105%‘if prepreg is used) but weight
VACUUM
and
Composites
it can
Developed
Reichhold ASSET using resins, (Advanced Structural System for
with
the deck.
(also tried
to increase
of piles
already also
under
Additionally,
using
extruded
is so strong
an EU Brite-Euram
by
consor-
a revolutionary
under
position
are beyond
the overall
on the waterfront
is only a fifth that of steel. The material applied to complex shapes. Finally, for decks that
‘I’
plastics prevail
Navy wants century
and
piers that
will float rather
on piles. Because the
a service life of well over a maintenance
80%
lower
than with conventional piers, advanced composites are likely to figure strongly in the ’21st Century Pier’ being developed under the Navy’s Hybrid Waterfront Structure programme. But this aspect of waterfront engineering must, for the time being, remain another story. n
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