Stress Intensity Factor Solutions for Narrow Plates

Matthew J. Hammond; Scott A. Fawaz

doi:10.4028/www.scientific.net/AMR.891-892.784

Paper Titles

Modelling of Fatigue Crack Growth in Inconel 718 under Hold Time Conditions - Application to a Flight Spectrum
p.759

A Cohesive Zone Model to Simulate Fatigue Crack Propagation under High Pressure Gaseous Hydrogen
p.765

Rainflow-on-the-Fly Methodology: Fatigue-Crack Growth under Aircraft Spectrum Loading
p.771

Numerical Simulation of Fatigue Crack Growth Rate and Crack Retardation due to an Overload Using a Cohesive Zone Model
p.777

Stress Intensity Factor Solutions for Narrow Plates
p.784

A Probabilistic Two-Scale Approach to Predict the High Cycle Fatigue Behaviour of Ti-Al6-V4 Parts Machined by High Pressure Water Jet Assisted Turning
p.791

A Deviatoric Stress-Strain Function for Fatigue Life Analysis
p.797

Fatigue Assessment of Existing Shiploaders
p.803

Constitutive Modeling for Cyclic Behavior of AZ31B Magnesium Alloy and its Application
p.809

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 891-892Stress Intensity Factor Solutions for Narrow...

Stress Intensity Factor Solutions for Narrow Plates

Abstract:

Accurate quantification of crack tip stress intensity values is paramount in the analysis of damage tolerant structures. The present analytical investigation seeks to determine the stress intensity solutions for crack geometries outside the existing valid solution space and expand the analysts ability to capture representative crack growth behavior. The focus of this investigation is to calculate the stress intensity factors of single quarter-elliptical corner cracks emanating from centrally located holes in finite width plates under various loading conditions (remote tension, bending, and pin loading). Many of the available finite width corrections are singled valued and universally applied to all locations along the crack front. Early investigations into the validity of this application indicated that this correction procedure produces stress intensity values +/- 30% from new solutions. The crack depth to length ratio and depth to thickness ratio can also significantly influence the accuracy of historical finite width solutions and corrections. The analytical investigation utilizes the three dimensional virtual crack closure technique and well-structured, completely hexahedral, element meshes. Stress intensity values are generated for a wide range of ratios for crack depth to crack length, crack depth to sheet thickness, hole radius to sheet thickness, and sheet width to hole diameter. This effort is being executed under a US DoD Technical Corrosion Collaboration program.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 891-892)

Pages:

784-790

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.891-892.784

Citation:

Cite this paper

Online since:

March 2014

Authors:

Matthew J. Hammond*, Scott A. Fawaz

Keywords:

Finite Element Analysis (FEA), Finite Width Correction, Strain Energy Release Rate, Stress Intensity Factor (SIF), Virtual Crack Closure Technique

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] AFGROW, LexTech, Inc., http: /www. afgrow. net.

Google Scholar

[2] Cracks2000, University of Dayton Research Institute (UDRI), http: /cracks. udri. udayton. edu.

Google Scholar

[3] NASGRO, Southwest Research Institute (SwRI), http: / www. nasgro. swri. org.

Google Scholar

[4] J.C. Newman, Jr. and I.S. Raju, Stress-intensity factor equations for cracks in three-dimensional finite bodies subjected to tension and bending loads, Computation Methods in the Mechanics of Fracture, Elsevier Science Publishers B.V., 1986, pp.311-334.

DOI: 10.1520/stp37074s

Google Scholar

[5] K.N. Shivakumar, P.W. Tan and J.C. Newman, Jr., A virtual crack-closure technique for calculating stress intensity factors for cracked three dimensional bodies, International Journal of Fracture 36 (1988).

DOI: 10.1007/bf00035103

Google Scholar

[6] MATLAB, The MathWorks, Inc., http: /www. mathworks. com/products/matlab.

Google Scholar

[7] TrueGrid, XYZ Scientific Applications, Inc., http: /truegrid. com.

Google Scholar

[8] K.N. Shivakumar and J.C. Newman, Jr., ZIP3D - An elastic and elastic-plastic finite-element analysis program for cracked bodies, NASA Technical Memorandum 102753, November (1990).

Google Scholar

[9] R.C. Shah, Stress intensity factors for through and part-through cracks originating at fastener holes, Mechanics of Crack Growth, ASTM STP-590, American Society for Testing and Materials, 1976, pp.429-459.

DOI: 10.1520/stp33961s

Google Scholar

[10] S.A. Fawaz, B. Andersson, Accurate stress intensity factor solutions for corner cracks at a hole, Engineering Fracture Mechanics 71 (2004), pp.1235-1254.

DOI: 10.1016/s0013-7944(03)00207-8

Google Scholar

[11] Personal correspondence with S.A. Fawaz, November (2011).

Google Scholar