Determination of Dynamic Fracture Toughness Using Strain Measurement

Kim, Duck Hoi; Moon, Soon Il; Kim, Jae-Hoon

doi:10.4028/www.scientific.net/kem.261-263.313

Cited by 3 publications

(1 citation statement)

References 5 publications

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“…Also, a number of strain gages were attached at various positions. (If you need the test theory and techniques for dynamic fracture toughness test using strain measurement, see references [5,6]) Five specimens for each test condition were used.…”

Section: Methodsmentioning

confidence: 99%

An Evaluation of Fracture Toughness of Glass-Filled Ceramic Using Notched Specimen

Kim

Rho

et al. 2006

KEM

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The objective of this study is to evaluate the mechanical properties of static, quasidynamic and dynamic fracture toughness of glass-filled ceramic as promising structural material for a dome port cover of a ramjet engine system. Static and quasi-dynamic tests were carried out using SEPB (Single Edge Pre-cracked Beam) specimens. Static and dynamic fracture toughness tests were also performed using ASTM and strain gage methods with SENB (Single Edge Notched Beam) specimens machined with various notch radii. The critical notch radius was evaluated. Below the critical notch radius, the static fracture toughness of the SENB specimen well agreed with that of the SEPB specimen.

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Section: Methodsmentioning

confidence: 99%

An Evaluation of Fracture Toughness of Glass-Filled Ceramic Using Notched Specimen

Kim

Rho

et al. 2006

KEM

Self Cite

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Experimental data-driven uncertainty quantification for the dynamic fracture toughness of particulate polymer composites

Sharma

Mukhopadhyay

Kushvaha

2022

Engineering Fracture Mechanics

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Hopkinson Bar Loaded Fracture Experimental Technique: A Critical Review of Dynamic Fracture Toughness Tests

Jiang

Vecchio

2009

Applied Mechanics Reviews

155

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Hopkinson bar experimental techniques have been extensively employed to investigate the mechanical response and fracture behavior of engineering materials under high rate loading. Among these applications, the study of the dynamic fracture behavior of materials at stress-wave loading conditions (corresponding stress-intensity factor rate ∼106 MPam/s) has been an active research area in recent years. Various Hopkinson bar loading configurations and corresponding experimental methods have been proposed to date for measuring dynamic fracture toughness and investigating fracture mechanisms of engineering materials. In this paper, advances in Hopkinson bar loaded dynamic fracture techniques over the past 30 years, focused on dynamic fracture toughness measurement, are presented. Various aspects of Hopkinson bar fracture testing are reviewed, including (a) the analysis of advantages and disadvantages of loading systems and sample configurations; (b) a discussion of operating principles for determining dynamic load and sample displacement in different loading configurations; (c) a comparison of various methods used for determining dynamic fracture parameters (load, displacement, fracture time, and fracture toughness), such as theoretical formula, optical gauges, and strain gauges; and (d) an update of modeling and simulation of loading configurations. Fundamental issues associated with stress-wave loading, such as stress-wave propagation along the elastic bars and in the sample, stress-state equilibrium validation, incident pulse-shaping effect, and the “loss-of-contact” phenomenon are also addressed in this review.

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Determination of Dynamic Fracture Toughness Using Strain Measurement

Cited by 3 publications

References 5 publications

An Evaluation of Fracture Toughness of Glass-Filled Ceramic Using Notched Specimen

An Evaluation of Fracture Toughness of Glass-Filled Ceramic Using Notched Specimen

Experimental data-driven uncertainty quantification for the dynamic fracture toughness of particulate polymer composites

Hopkinson Bar Loaded Fracture Experimental Technique: A Critical Review of Dynamic Fracture Toughness Tests

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