The Failure Characterization of Composite Pinned Joints

Aluko, Olanrewaju; Moore, Brian S.

doi:10.1080/15376494.2012.708821

Cited by 5 publications

(2 citation statements)

References 14 publications

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“…Moreover, it is rarely possible to produce a construction without joints because of limitations on material size, convenience in manufacture or transportation and the need for access. But these joints are susceptible to high stress concentrations which occur around and in the vicinity of the hole and are often the cause of unexpected failure in composite structures . The high stress concentrations reduce the efficiency of the joint along with the redistribution of stresses near the discontinuities .…”

Section: Introductionmentioning

confidence: 99%

Investigation on failure modes for pin joints made from unidirectional glass–epoxy nanoclay laminates

Singh

Saini

Bhunia

2015

Fatigue Fract Eng Mat Struct

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A B S T R A C T In the present work the effect of the nanoclay on the bearing strength and failure mode of the pin joints was investigated both experimentally and numerically. Geometric parameters, i.e. the distance from the free edge of specimen to the diameter of the first hole (E/D) ratio and width of the specimen to the diameter of the holes (W/D) ratio were investigated. The E/D and W/D ratios were varied from 1 to 5. Tsai-Wu failure criterion with characteristic curve method and progressive damage analysis was used for the prediction of failure modes. Results showed that bearing strength and failure mode were considerable affected by the wt% of nanoclay and the geometric parameters. A good agreement was obtained between experimental and numerical predictions.Keywords characteristic curve; failure analysis; glass reinforced; nanoclay; pin joint; progressive damage failure. N O M E N C L A T U R Es = shear failure strength t = thickness of the specimen B = bearing failure mode D = diameter of the hole E = distance from the free edge of specimen E F = flexural modulus E 1 = longitudinal tensile modulus E 2 = transverse tensile modulus G 12 = shear modulus N = net-tension failure mode R c , R ot , R oc = characteristic curve parameters S = shearing failure mode v 12 = Poisson ratio W = width of the specimen X c = longitudinal compressive strength X t = longitudinal tensile strength Y c = transverse compressive strength Y t = transverse tensile strength ε F = strain to failure θ = failure angle σ b = bearing stress σ F = flexural strength I N T R O D U C T I O NIn the last decade, composite materials are being commonly used in structures that demand a high level of mechanical performance. Their high strength to weight and stiffness to weight ratios has facilitated the development of lighter structures, which often replace conventional metal structures. Fibre-reinforced composites offer the most reliable engineering materials in automotive, marine and aircraft industrial engineering applications because of their outstanding mechanical properties like impact resistance, high durability, low coefficient of friction and thermal expansion, ability to provide higher

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Section: Introductionmentioning

confidence: 99%

Investigation on failure modes for pin joints made from unidirectional glass–epoxy nanoclay laminates

Singh

Saini

Bhunia

2015

Fatigue Fract Eng Mat Struct

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“…Mechanically fastened joints included bolted, riveted, and pinned joints. These joints are susceptible to high stress concentrations which occur around and in the vicinity of the hole and are often the cause unexpected failure in composite structures containing joints [1,2,3,4,5,6,7,10]. Therefore, adequate design of mechanical joint requires correct determination of the stresses, bearing strength and mode of failures of the joint.…”

Section: Introductionmentioning

confidence: 99%

Stress-Distribution around Pin-Loaded Hole for Orthotropic Laminates

Hidayat

Hadi

Syamsudin

et al. 2016

AMM

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Stresses were calculated for orthotropic laminate plate loaded by a frictionless pin in a circular hole of the same diameter. These calculations were based on finite-element analysis for five laminates; 00, [±450]s, [00/900]s,[00/±450]s, and quasi-isotropic [00/±450/900]s. stress distribution, based on nominal bearing stress, were determined for wide ranges of the ratios of width to diameter and edge distance to diameter. Orthotropic had a significant influence on both the magnitude and location of the maximum tensile stress concentration on the boundary of the hole. The laminates with 00 plies developed the peak tensile stress near the ends of the pin-hole contact arc. But the ±450 laminates had peaks where ply fiber were tangent to the hole. The finite width and edge distances strongly influenced the tensile stress concentration. In contrast, the finite widths and edge distances had little effect on bearing stress concentration. For the practical range w/d = 2, the peak tensile stresses were as much as 50 percent larger than the infinite-laminate value. For e/d=1, these stresses were greater 60 percent than infinite-laminate value. In contrast, the finite width and edge distance had little effect on bearing stress concentrations.

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Analytical modeling for stress distribution around interference fit holes on pinned composite plates under tensile load

Zhang

Cheng

et al. 2016

Composites Part B: Engineering

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The Failure Characterization of Composite Pinned Joints

Cited by 5 publications

References 14 publications

Investigation on failure modes for pin joints made from unidirectional glass–epoxy nanoclay laminates

Investigation on failure modes for pin joints made from unidirectional glass–epoxy nanoclay laminates

Stress-Distribution around Pin-Loaded Hole for Orthotropic Laminates

Analytical modeling for stress distribution around interference fit holes on pinned composite plates under tensile load

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