Propriedades de fadiga de soldas de alta resistência e baixa liga com diferentes composições microestruturais. / Fatigue properties of high strength low alloy steel weld metals with different microstructural composition.

Braz, Maria Heloisa Pereira

17 March 1999

Foram estudadas as propriedades de fadiga em dois grupos de soldas de alta resistência e baixa liga com diferentes composições microestruturais. As soldas do grupo A apresentaram microestruturas compostas de ferrita acicular, ferrita alotriomórfica e ferrita de Widmanstätten, com limite de escoamento de aproximadamente 460 MPa, enquanto que as soldas do grupo B apresentaram microestruturas compostas de martensita de baixo carbono, bainita e ferrita acicular, com limite de escoamento de aproximadamente 850 MPa. A partir do ensaio de trincas longas, foi obtida a taxa de crescimento por ciclos de carregamento, da/dN, de da/dN=1,18·10-12·DeltaK2,91 e da/dN=1,34·10-11·DeltaK2,64, respectivamente para as soldas dos grupos A e B. Como pode ser observado a partir destas equações, a taxa de crescimento foi mais alta para o grupo B. Da análise do fechamento da trinca pode ser concluído que o principal fator determinante de uma menor taxa de propagação para as soldas do grupo A foi a plasticidade desenvolvida pela estrutura. Dos ensaios de trincas curtas foi observado que no caso das soldas do grupo A, uma vez nucleada a trinca, esta se propagava até o colapso do corpo de prova. Para as soldas do grupo B foi observado que não bastava a existência de uma trinca para que esta se propagasse até a fratura total do corpo de prova e que o fator controlador foi a granulomentria associada a uma determinada composição microestrutural. / The fatigue properties of two groups of high strength low alloy steel weld metals with different microstructural composition were studied. Weld metals from group A presented microstructures composed of acicular ferrite, Widmanstätten ferrite and allotriomorphic ferrite, with yield strength of 460 MPa. Weld metals from group B exhibited a microstructural composition of low carbon martensite, bainite and acicular ferrite, with a yield strength of 850 MPa. The fatigue crack growth per cycle of loading, da/dN, for weld metals from groups A and B is obtained from the relationships, da/dN=1,18·10-12·DeltaK2,91 and da/dN=1,34·10-11·DeltaK2,64, respectively. As can be seen from these equations, the crack growth rate was higher for group B. From the crack growth closure analysis, it may be concluded that the lower crack growth rate obtained for weld metals from group A was mainly due to the higher crack tip plasticity developed in this type of microstructure. From the short crack fatigue tests, it was observed for weld metals from group A, that once a crack was nucleated, it propagated until the testpiece plastic collapsed. For weld metals from group B, it was observed that the existence of a crack was not sufficient to cause the complete testpiece failure, and the association of the grain size with the local microstructure was the main factor controlling the failure process.

crack propagation

HSLA weld

nucleação de trincas curtas por fadiga

propagação de trincas

short crack fatigue

soldas ARBL

Propriedades de fadiga de soldas de alta resistência e baixa liga com diferentes composições microestruturais. / Fatigue properties of high strength low alloy steel weld metals with different microstructural composition.

Maria Heloisa Pereira Braz

17 March 1999

Foram estudadas as propriedades de fadiga em dois grupos de soldas de alta resistência e baixa liga com diferentes composições microestruturais. As soldas do grupo A apresentaram microestruturas compostas de ferrita acicular, ferrita alotriomórfica e ferrita de Widmanstätten, com limite de escoamento de aproximadamente 460 MPa, enquanto que as soldas do grupo B apresentaram microestruturas compostas de martensita de baixo carbono, bainita e ferrita acicular, com limite de escoamento de aproximadamente 850 MPa. A partir do ensaio de trincas longas, foi obtida a taxa de crescimento por ciclos de carregamento, da/dN, de da/dN=1,18·10-12·DeltaK2,91 e da/dN=1,34·10-11·DeltaK2,64, respectivamente para as soldas dos grupos A e B. Como pode ser observado a partir destas equações, a taxa de crescimento foi mais alta para o grupo B. Da análise do fechamento da trinca pode ser concluído que o principal fator determinante de uma menor taxa de propagação para as soldas do grupo A foi a plasticidade desenvolvida pela estrutura. Dos ensaios de trincas curtas foi observado que no caso das soldas do grupo A, uma vez nucleada a trinca, esta se propagava até o colapso do corpo de prova. Para as soldas do grupo B foi observado que não bastava a existência de uma trinca para que esta se propagasse até a fratura total do corpo de prova e que o fator controlador foi a granulomentria associada a uma determinada composição microestrutural. / The fatigue properties of two groups of high strength low alloy steel weld metals with different microstructural composition were studied. Weld metals from group A presented microstructures composed of acicular ferrite, Widmanstätten ferrite and allotriomorphic ferrite, with yield strength of 460 MPa. Weld metals from group B exhibited a microstructural composition of low carbon martensite, bainite and acicular ferrite, with a yield strength of 850 MPa. The fatigue crack growth per cycle of loading, da/dN, for weld metals from groups A and B is obtained from the relationships, da/dN=1,18·10-12·DeltaK2,91 and da/dN=1,34·10-11·DeltaK2,64, respectively. As can be seen from these equations, the crack growth rate was higher for group B. From the crack growth closure analysis, it may be concluded that the lower crack growth rate obtained for weld metals from group A was mainly due to the higher crack tip plasticity developed in this type of microstructure. From the short crack fatigue tests, it was observed for weld metals from group A, that once a crack was nucleated, it propagated until the testpiece plastic collapsed. For weld metals from group B, it was observed that the existence of a crack was not sufficient to cause the complete testpiece failure, and the association of the grain size with the local microstructure was the main factor controlling the failure process.

nucleação de trincas curtas por fadiga

propagação de trincas

soldas ARBL

crack propagation

HSLA weld

short crack fatigue

Experimental and modelling studies of corrosion fatigue damage in a linepipe steel

Fatoba, Olusegun Oludare

January 2016

The work is concerned with the development of a multi-stage corrosion fatigue lifetime model, with emphasis on pitting as a precursor to cracking. The model is based upon the quantitative evaluation of damage during the overall corrosion fatigue process. The fatigue response of as-received API 5L X65 linepipe steel has been investigated in terms of the evolution of damage during pit development, pit-to-crack transition and crack propagation. Micro-potentiostatic polarisation was conducted to evaluate role of stress on pit development. Crack growth rate measurements were conducted on pre-pitted specimens, which were tested in air and brine, to evaluate the initiation and propagation behaviour of cracks emanating from artificial pits. Finite element analysis was undertaken to evaluate the stress and strain distribution associated with the pits. A cellular automata finite element model was also developed for predicting corrosion fatigue damage. Pit growth rate was enhanced under stress. It was considered that the strain localisation effect of the pit facilitated strain-assisted dissolution. In air, cracks initiated predominantly from the pit mouth. FEA results indicated that this was due to localisation of strain towards the pit mouth. In corrosion fatigue, cracks tended to initiate at the pit base at low stress and at the pit mouth at higher stresses. Crack initiation lifetimes were shorter in the aggressive environment compared to air and the effect of the environment on crack initiation lifetime was lower at higher stress levels. Crack initiation lifetime for double pits generally decreased with decreasing pit-to-pit separation distance. The microstructure was observed to influence crack growth behaviour in air particularly in the early stages when cracks were short. The acceleration and retardation in crack growth were attributed to the resistance of grain boundaries to crack advance. Cracks sometimes arrested at these barriers and became non-propagating. Introduction of the environment for a short period appear to eliminate the resistance of the microstructural barriers thus promoting re-propagation of the previously arrested crack. The continued crack propagation after the removal of the environment suggests that the influence of the environment is more important in the early stages of crack growth. Crack growth rates were higher in the aggressive environment than in air. The degree of environmental enhancement of crack growth was found to be greater at lower stress levels and at short crack lengths. Oxide-induced crack closure and crack coalescence were two mechanisms that also affected crack growth behaviour.2-D cellular automata finite element simulation results, with and without stress, show good agreement agreed with experiments i.e. pit depth and pit aspect ratio increase with time. Results from 3-D cellular automata simulations of pits are also consistent with experiments. Fatigue lifetimes were significantly shorter (i) in the brine environment than in air and (ii) for specimens with double pits compared to single pits of similar depth. Fatigue strength in air was found to decrease with increasing pit depth. Corrosion fatigue lifetimes predicted based upon the developed model showed good agreement with the experimental lifetimes.

620.1