Methods for the prediction of fatigue delamination growth in composites and adhesive bonds – A critical review

Abstract: An overview is given of the development of methods for the prediction of fatigue driven delamination growth over the past 40 years. Four categories of methods are identified: stress/strain-based models, fracture mechanics based models, cohesive-zone models, and models using the extended finite element method. It is highlighted that most models are phenomenological, based on the observed macro-scale behaviour of test specimens. It is suggested that a more physics based approach, focusing on elucidating the mech… Show more

“…This phenomenon, i.e. that when plotting da/dN as a function of ∆(K 2 ) tests at low R ratios appear to be more severe than tests at high R ratios, also follows from the crack growth data presented in [67] and, as previously remarked is also seen from plotting delamination growth as a function of ∆G, see [17,18,43]. Therefore, it is best to follow the natural extension of the original Paris hypothesis [22,24] and relate da/dN to ∆√G (or �G max ), rather than to ∆G or G max or alternatively, as first suggested in [61,62] to Δ√W rather than by ΔW.…”

“…Here it should be recalled that, when originally formulating the equations for crack growth, Paris argued that, since Irwin [20,21] had shown that the stress-intensity factor, K, uniquely characterises the near tip stress field, then the rate of FCG should be a function of ΔK and K max [22,23]. In [24] [2,[41][42][43][44][45][46][47][48][49][50][51][52][53][54][55]. (Where ∆√G is given by (�G max -�G min ); and G min is the minimum value of the energy release-rate in a fatigue cycle.…”

“…The use of Mode I DCB tests is the most common approach employed to characterise delamination growth as a function of the energy release-rate, G [2,4,5,19,26,[38][39][40][41][42][43][44][45][46][47][48][49][50][51][52][53][54][55][76][77][78]. However, a major problem with this method is the large retardation that can develop due to fibres bridging the delamination [4,5,13,14,36,42,49].…”

“…However, the logical extension of Paris' growth law to composites is to express da/dN as a function of �G max and/or ∆√G. Indeed, as shown in [17,43] expressing da/dN as a function of ∆G often leads to the anomalous conclusion that, for a given ∆G, increasing the mean stress level reduces the delamination growth rate. This anomaly is removed if da/dN is expressed as a function of ∆√G, see [17,43].…”

“…Indeed, as shown in [17,43] expressing da/dN as a function of ∆G often leads to the anomalous conclusion that, for a given ∆G, increasing the mean stress level reduces the delamination growth rate. This anomaly is removed if da/dN is expressed as a function of ∆√G, see [17,43]. A further illustration of how expressing da/dN as a function of ∆G conflicts with the original Paris formulation is given in the Appendix.…”

Delamination growth in polymer-matrix fibre composites and the use of fracture mechanics data for material characterisation and life prediction

“…This phenomenon, i.e. that when plotting da/dN as a function of ∆(K 2 ) tests at low R ratios appear to be more severe than tests at high R ratios, also follows from the crack growth data presented in [67] and, as previously remarked is also seen from plotting delamination growth as a function of ∆G, see [17,18,43]. Therefore, it is best to follow the natural extension of the original Paris hypothesis [22,24] and relate da/dN to ∆√G (or �G max ), rather than to ∆G or G max or alternatively, as first suggested in [61,62] to Δ√W rather than by ΔW.…”

“…Here it should be recalled that, when originally formulating the equations for crack growth, Paris argued that, since Irwin [20,21] had shown that the stress-intensity factor, K, uniquely characterises the near tip stress field, then the rate of FCG should be a function of ΔK and K max [22,23]. In [24] [2,[41][42][43][44][45][46][47][48][49][50][51][52][53][54][55]. (Where ∆√G is given by (�G max -�G min ); and G min is the minimum value of the energy release-rate in a fatigue cycle.…”

“…The use of Mode I DCB tests is the most common approach employed to characterise delamination growth as a function of the energy release-rate, G [2,4,5,19,26,[38][39][40][41][42][43][44][45][46][47][48][49][50][51][52][53][54][55][76][77][78]. However, a major problem with this method is the large retardation that can develop due to fibres bridging the delamination [4,5,13,14,36,42,49].…”

“…However, the logical extension of Paris' growth law to composites is to express da/dN as a function of �G max and/or ∆√G. Indeed, as shown in [17,43] expressing da/dN as a function of ∆G often leads to the anomalous conclusion that, for a given ∆G, increasing the mean stress level reduces the delamination growth rate. This anomaly is removed if da/dN is expressed as a function of ∆√G, see [17,43].…”

“…Indeed, as shown in [17,43] expressing da/dN as a function of ∆G often leads to the anomalous conclusion that, for a given ∆G, increasing the mean stress level reduces the delamination growth rate. This anomaly is removed if da/dN is expressed as a function of ∆√G, see [17,43]. A further illustration of how expressing da/dN as a function of ∆G conflicts with the original Paris formulation is given in the Appendix.…”

Delamination growth in polymer-matrix fibre composites and the use of fracture mechanics data for material characterisation and life prediction

Phenomenological Failure Criteria of Composites

Micromechanical Failure Criteria of Composites