Abstract
The linear elastic analysis of cracked bodies is a Twentieth Century development, with the first papers appearing in 1907, but it was not until the introduction of the stress intensity factor concept in 1957 that widespread application to practical engineering problems became possible. Linear elastic fracture mechanics (LEFM) developed rapidly in the 1960s, with application to brittle fracture and fatigue crack growth. The first application of finite elements to the calculation of stress intensity factors for two dimensional cases was in 1969. Finite element analysis had a significant influence on the development of LEFM. Corner point singularities were investigated in the late 1970s. It was soon found that the existence of corner point effects made interpretation of calculated stress intensity factors difficult and their validity questionable. In 1998 it was shown that the assumption that crack growth is in mode I leads to geometric constraints on permissible fatigue crack paths. Current open questions are. The need for a new field parameter, probably a singularity, to describe the stresses at surfaces. How best to allow for the influence of corner point singularities in three dimensional numerical predictions of fatigue crack paths. Adequate description of fatigue crack path stability.
Highlights
The complete solution of a crack growth problem includes determination of the crack path
Geometric constraints on mode I crack paths In 1998 it was shown by Pook [37] that the assumption that crack growth is in mode I leads to geometric constraints on permissible fatigue crack paths
Finite element analysis had a significant influence on this aspect of the development of Linear elastic fracture mechanics (LEFM)
Summary
The complete solution of a crack growth problem includes determination of the crack path. This review is a brief survey of the development of ideas on the linear elastic analyis of cracked bodies that are relevant to crack path determination. It is based on the author’s personal involvement over more than 50 years. In considering practical aspects of linear elastic fracture mechanics, scales of observation need to be taken into account since the scale chosen can make a considerable difference to the appearance of an object in general, and a crack in particular [2]. A fundamental fracture mechanics concept is that of crack tip surface displacement [3]. Crack surfaces are assumed to be smooth, on a microscopic scale they are generally very irregular
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