strengthening of steel structures with fiber reinforced polymers

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MANUFACTURING AND STRENGTHING OF STEEL STRUCTURES WITH FIBER REINFORCED POLYMER COMPOSITES

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Page 1: strengthening of steel structures with fiber reinforced polymers

MANUFACTURING AND STRENGTHING OF STEEL STRUCTURES WITH FIBER REINFORCED POLYMER COMPOSITES

Page 2: strengthening of steel structures with fiber reinforced polymers

Definition of composite

• Two or more chemically distinct materials which when combined have improved properties over the individual materials. composites could be natural or synthetic.

• Composites are combinations of two materials in which one of the material is called the reinforcing phase, is in the form of fibers, sheets, or particles, and is embedded in the other material called the matrix phase.

• The reinforcing phase consist of fibers which provide strengthand stiffness.

• The common type of fibers are carbon, glass, aramid, basalt etc..

• The matrix protects and transfer the load between fibers. The polymer matrix composite consist of Resin. The common type of resins are thermosetting materials such as polyester, epoxy's and thermo plastic materials such as polyvinyl, polyethylene.

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• Carbon type FRP: Glass type FRP:

• Aramid type FRP: Basalt type FRP:

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• FRP composite materials have experienced a continuous increase of use in structural strengthening and repair applications around the world in the last decade. Because,

• The main advantages of FRP:

Light weight- easy to handle and transport.

high strength to weight ratio.

Corrosion resistant-will not corrode.

Non magnetic.

impervious to pests and woodpecker attack.

material properties in different directions can be tailored for a particular application.

Environmentally safe- no leaching of toxic chemicals in to soil.

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• MANUFACTURING PROCESS:

Forming processes for Thermosetting matrix composites:

wet/Hand lay up and spray up techniques.

Pultrusion.

filament winding.

Autoclave moulding.

Resin transfer moulding.

Forming processes for Thermoplastic matrix composites:

Injection moulding.

Film stacking.

Diaphragm forming.

Thermo plastic tape laying.

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• SPRAY UP PROCESSES:

in spray up process liquid resin matrix and chopped reinforcing fibers are sprayed on to the mold surface. The fibers are chopped in to fibers of 25-50mm length and then sprayed by an air jet at a predetermined ratio between the reinforcing and matrix phase. The spray up method permits rapid formation of uniform composite coating, however mechanical properties of the material are moderate since the method is unable to use continuous reinforcing fibers.

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• FILAMENT WINDING:

• Filament winding method involves a continuous filament of reinforcing material wound on to a rotating mandrill in layers at different layers. If a liquid thermosetting resin is applied on the filament prior to winding, the process is called the Wet Filament winding. If the resin is sprayed on to the mandrel with wound filament ,the process is called Dry Filament Winding.

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• PULTRUSION:

Pultrusion is a process where composite parts are manufactured by

pulling layers of fibers impregnated with resin, through a heated

die, thus forming the desired cross sectional shape with no part

length limitation.

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INJECTION MOULDING:

• It is a closed mold process in which molten polymer mixed with

very short reinforcing fibers under high pressure in to a mold

cavity through an opening.

• Polymer fiber mixture in the form of pellets is fed in to an

injection molding machine through a hopper. The material is

then conveyed forward by a feeding screw and forced in to a

split mold.

• Screw of injection molding machine is called reciprocating

screw since it not only rotates but also moves forward and

backward according to the steps of the molding cycle.

• The polymer is held in the mold until solidification and then the

mold opens and the part is removed from the mold by ejector

pins.

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STRENGTHENING OF STEEL STRUCTURES WITH FIBER REINFORCED POLYMER COMPOSITES

• More recently, the use of FRP composites in combination with steel, particularly in the strengthening of steel structures, has received much attention.

This shows typical stress-strain responses of FRP composites in contrast with that of mild steel, where it is clearly seen that FRP composites exhibit a linear elastic stress-strain behavior before brittle failure by rupture.

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Appropriate use of FRP in the strengthening of steel structures

• Since steel is also a material of high elastic modulus and

strength. The main advantage of FRP over steel in the

strengthening of steel structures is its high strength to weight

ratio. Another advantage of FRP, which applies only to FRP

laminates to follow curved and irregular surfaces of a structure.

This is difficult to achieve using steel plates. Material properties

in different directions can be tailored for a particular application.

As a result of these advantages fibers oriented in circumferential

direction can be used to confine steel tubes/shells or concrete

filled steel tubes to delay or eliminate local buckling problems

in steel tubes there by enhancing the strength and seismic

resistant of such structures.

• Steel plates can also be attached by welding to strengthen

existing steel structures, but the bonding of FRP laminates is

superior to the welding of steel plates in the following

situations.

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bonding of FRP laminates for enhanced fatigue resistance has the advantage that the strengthening process does not introduce new residual stresses.

in certain applications(oil storage tanks, chemical plants) where the risk must be minimized, welding needs to be avoided when strengthening a structure; bonding of FRP laminates is then a very attractive alternative;

high strength steels suffer significant local strength reductions in heat affected zones of welds, so bonded FRP laminates offer an local strength compensation method.

BOND BEHAVIOUR BETWEEN FRP AND STEEL:

In all bond critical applications , the interfacial behavior between FRP and steel is of critical importance in determining when failure occurs and how effectively the FRP is utilized.

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ADHESION FAILURE:

• In an FRP-to-steel bonded joint, adhesion failure may occur at the

steel/adhesive interface or at the FRP/adhesive interface. Failure occur

between FRP/adhesive interface only when the FRP is manufactured

through wet lay up process. When a pultruded FRP strip is used such

failure can be avoided.

• The adhesion strength of steel/adhesive interface result from both

chemical bonding and mechanical bonding between the two adhereds.

• When the two adherends are in intimate contact, the strength of

chemical bonding depends mainly on the chemical composition of the

steel surface and that of the adhesive and whether they are chemically

compatible.

• The strength of mechanical bonding depends mainly on the roughness

and topography of steel surface.

• Existing approaches of steel surface treatment generally aim to enhance

the two bonding mechanisms by: (1) cleaning the surface; (2) changing

the properties of the surface. The most popular approaches include

solvent cleaning and mechanical abrasion through grit blasting.

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BOND STRENGTH:

The bond strength is the ultimate tensile force that can be resisted by the

FRP plate in a bonded joint test before the FRP plate debonds from the

substrate.

Existing studies have shown that the bond strength of an FRP-to-steel

bonded joint initially increases with the bond length, but when the bond

length reaches a threshold value, any further increase in the bond length

does not lead to a further increase in the bond strength.

FLEXURAL STRENGTHENING OF STEEL BEAMS:

• Similar to an RC beam, a steel beam can be strengthened by bonding an

FRP plate to its tension face. The bonded FRP plate can enhance not

only the ultimate load but also the stiffness of the beam. A number of

failure modes are possible for such FRP plated steel beams, include

(1)plate end debonding; (2)intermediate debonding; (3)lateral buckling;

(4) local buckling of the compression flange and web.

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FATIGUE STRENGTHING:

• One of the most important aspects of FRP strengthening of steel

structures is its capability to improve their fatigue life.

• Debonding along the FRP-to-steel plates interface is also a key issue of

concern in the fatigue strengthening of steel beams. Where both plate

end debonding and intermediate debonding are possible.

• Debonding near the crack tip can lead to significant increase in the stress

intensity factors, which is detrimental to the fatigue life of the

strengthened structure.

• The fatigue strengthening of steel structures generally aims to reduce the

stress intensity factors at a crack tip and thus increase their post-crack

fatigue life.

STRENGTHENING OF STEEL STRUCTURES AGAINST LOCAL BUCKLING:

• Under local compressive stress, due to concentrated loads local

buckling failure is likely to occur. Such failure may be prevented by

bonding FRP patches.

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• Hollow steel tubes are used in many structures. Local buckling can

occur in these tubular members when they are subjected to axial

compression alone or in combination with cyclic lateral loading.

• A typical local buckling mode of circular hollow steel tubes involves the

appearance of an outward bulge near the base and is often referred to as

ELEPHANT’S FOOT buckling. It appears after yielding and the

appearance of this inelastic local buckling mode normally signifies the

exhaustion of the load carrying capacity and the end of ductile response.

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CONCLUSION:• External bonding of FRP reinforcement has been clearly established as a

promising alternative strengthening technique for steel structures by existing research.

REFERENCES:

(1). Teng JG. and Hu YM. Suppression of local buckling in steel tubes byFRP jacketing. In: Proceedings, 2nd international conference on FRPcomposites in civil engineering, Adelaide, Australia; 8–10 December2004.(2) Nishino T. and Furukawa T. Strength and deformation capacities ofcircular hollow section steel member reinforced with carbon fiber. In:Proceedings of 7th Pacific structural steel conference, AmericanInstitute of Steel Construction; March 2004.(3) Rotter JM. Local collapse of axially compressed pressurized thin steelcylinders. J Structural Eng, ASCE 1990;116(7):1955–70.(4) Rotter JM. Chapter 2: cylindrical shells under axial compression. In:Teng JG, Rotter JM, editors. Buckling of thin metal shells. UK: SponPress; 2004. p. 42–87.

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(5) Buyukozturk O, Gunes O, Karaca E. Progress on understanding

debonding problems in reinforced concrete and steel members

strengthened using FRP composites. Construction and Building Materials

2003;18(1):9-19.

(6) Colombi P, Poggi C. Strengthening of tensile steel members and

bolted joints using adhesively bonded CFRP plates. Construction and

Building Materials 2006;20(12):22-33.

(7) Xia SH, Teng JG. Behavior of FRP-to-steel bonded joints. In: Chen

JF, Teng JG (editors). Proceedings of the international symposium on

bond behavior of FRP in structures. International Institute for FRP in

Construction. 2005.p. 419-26.

(8) Smith ST, Teng JG. Interfacial stresses in plated beams. Eng Struct

2001;23(7):857 –71.

(9) Bourban, P.E., McKnight, S.H., Shulley, S.B., Karbhari, V.M. and

Gillespie, J.W. 1994. Durability of Steel/Composites Bonds for

Rehabilitation of Structural Components, Infrastructure: New Materials

and Methods of Repair – Proc. 3rd Mat. Eng. Conf. 295-303.

(10) Strengthening of steel structures with fiber reinforced polymer

composites by J.G Teng, d. Fernando. Journal of steel research78(2012).

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