Crack Initiation Analysis in Residual Stress Zones with Finite Element Methods

dc.contributor.authorBrew, Patrick Josephen
dc.contributor.committeechairWest, Robert L. Jr.en
dc.contributor.committeememberMirzaeifar, Rezaen
dc.contributor.committeememberDowling, Norman E.en
dc.contributor.departmentMechanical Engineeringen
dc.date.accessioned2018-08-11T08:00:15Zen
dc.date.available2018-08-11T08:00:15Zen
dc.date.issued2018-08-10en
dc.description.abstractThis research explores the nearly untapped research area of the analysis of fracture mechanics in residual stress zones. This type of research has become more prevalent in the field in recent years due to the increase in prominence of residual stress producing processes. Such processes include additive manufacturing of metals and installation procedures that lead to loads outside the anticipated standard operating load envelope. Abaqus was used to generate models that iteratively advanced toward solving this problem using the compact tensile specimen geometry. The first model developed in this study is a two-dimensional fracture model which then led to the development of an improved three-dimensional fracture model. Both models used linear elastic fracture mechanics to determine the stress intensity factor (K) value. These two models were verified using closed-form equations from linear elastic fracture mechanics. The results of these two models validate the modeling techniques used for future model iterations. The final objective of this research is to develop an elastic-plastic fracture mechanics model. The first step in the development of an elastic-plastic fracture model is a three-dimensional quasi-static model that creates the global macroscale displacement field for the entire specimen geometry. The global model was then used to create a fracture submodel. The submodel utilized the displacement field to reduce the model volume, which allowed a higher mesh density to be applied to the part. The higher mesh density allowed more elements to be allocated to accurately represent the model behavior in the area local to the singularity. The techniques used to create this model were validated either by the linear elastic models or by supplementary dog bone prototype models. The prototype models were run to test model results, such as plastic stress-strain behavior, that were unable to be tested by just the linear elastic models. The elastic-plastic fracture mechanics global quasi-static model was verified using the plastic zone estimate and the fracture submodel resulted in a J-integral value. The two-dimensional linear elastic model was validated within 6% and the three-dimensional linear elastic model was validated within 0.57% of the closed-form solution for linear elastic fracture mechanics. These results validated the modeling techniques. The elastic-plastic fracture mechanics quasi-static global model formed a residual stress zone using a Load-Unload-Reload load sequence. The quasi-static global model had a plastic zone with only a 0.02-inch variation from the analytical estimate of the plastic zone diameter. The quasi-static global model was also verified to exceed the limits of linear elastic fracture mechanics due to the size of the plastic zone in relation to the size of the compact specimen geometry. The difference between the three-dimensional linear elastic fracture model J-integral and the elastic-plastic fracture submodel initial loading J-integral was 3.75%. The J-integral for the reload step was 18% larger than the J-integral for the initial loading step in the elastic-plastic fracture submodel.en
dc.description.abstractgeneralAdditive manufacturing, sometimes referred to as 3-D printing, has become an area of rapid innovation. Additive manufacturing methods have many benefits such as the ability to produce complex geometries with a single process and a reduction in the amount of waste material. However, a problem with these processes is that very few methods have been created to analyze the initial part stresses caused by the processes used to additive manufacture. Finite element methods are computer-based analyses that can determine the behavior of parts based off prescribed properties, shape, and loading conditions. This research utilizes a standard fracture determination shape to leverage finite element methods. The models determine when a crack will form in a part that has process stresses from additive manufacturing. The model for crack initiation was first developed in two dimensions, neglecting the thickness of the part, using a basic material property definition. The same basic material property definition was next used to develop a crack initiation model in three dimensions. Then a more advanced material property definition was used to capture the impact of additive manufacturing on material properties. This material property definition was first used to establish the part properties as it relates to part weakening due to additive manufacturing. A higher accuracy model of just the crack development area was produced to determine the crack initiation properties of the additive manufactured part. Methods previously confirmed by testing were used to validate the models produced in this research. The models demonstrated that under the same loading parts with initial processes stresses were closer to fracture than parts without initial stresses.en
dc.description.degreeMaster of Scienceen
dc.format.mediumETDen
dc.identifier.othervt_gsexam:16774en
dc.identifier.urihttp://hdl.handle.net/10919/84537en
dc.publisherVirginia Techen
dc.rightsIn Copyrighten
dc.rights.urihttp://rightsstatements.org/vocab/InC/1.0/en
dc.subjectFractureen
dc.subjectCrack Initiationen
dc.subjectPlastic Residual Stress Zonesen
dc.subjectAbaqus Submodelingen
dc.subjectJ-integralen
dc.titleCrack Initiation Analysis in Residual Stress Zones with Finite Element Methodsen
dc.typeThesisen
thesis.degree.disciplineMechanical Engineeringen
thesis.degree.grantorVirginia Polytechnic Institute and State Universityen
thesis.degree.levelmastersen
thesis.degree.nameMaster of Scienceen

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