X-ray Fractographic Study on TiAl Alloys with Various Types of Microstructures

1994 ◽  
Vol 38 ◽  
pp. 427-434
Author(s):  
Hiroyuki Tabata ◽  
Zenjiro Yajima ◽  
Yukio Hirose
Keyword(s):  
Fracture Toughness ◽  
Residual Stress ◽  
Plastic Zone ◽  
Plastic Zone Size ◽  
Fracture Toughness Test ◽  
Zone Size ◽  
Two Phase ◽  
Tial Alloys ◽  
X Ray ◽  
Fracture Surfaces

Abstract The fracture toughness test was conducted on γ + α2 two-phase TiAl alloys with lamellar, duplex and near-y structures. The x-ray fractographic technique was applied to the fracture, surfaces. The plastic zone size my was determined on the basis of the distributions of the residual stress and the half-value breadth beneath the fracture surfaces. Although the fracture mode shows microstructure dependence, ωγ is related to the fracture toughness value KIC and the yield stress σY as: ωy=α(KIC/σY) where α is 0.13.

X-Ray Fractography Evaluation of the Plastic Zones of Dynamic Fracture

1992 ◽  
Vol 36 ◽  
pp. 551-560
Author(s):  
Kazuyuki Matsui ◽  
Osamu Nakada ◽  
Yukio Hirose ◽  
Keisuke Tanaka
Keyword(s):  
Stress Intensity Factor ◽  
Plastic Zone ◽  
Dynamic Fracture ◽  
Dynamic Stress ◽  
Dynamic Stress Intensity Factor ◽  
Plastic Zone Size ◽  
Zone Size ◽  
X Ray Diffraction ◽  
X Ray ◽  
Plastic Zones

AbstractTo evaluate the plastic zones of dynamic fracture, instrumented Charpy impact tests of high carbon bearing steels are conducted. The amount of plastic zone size left on the fracture surface is evaluated from the X-ray diffraction profiles. An analysis is presented of the relationship between the X-ray diffraction profiles and fracture mechanics parameters. The results are discussed in correlations between dynamic stress intensity factor and absorbed energy values. A good correlation exists between the plastic zone size and the dynamic stress intensity factor.The fraction of retained austenite is determined from X-ray diffraction profiles at surfaces of fractures and also beneath the surfaces of fractures.It shows the work hardening is introduced by the strain energy in the plastic zones. The values of the proportionality constant, α, determined for various kinds of dynamic fracture are related to half-value breadth by the functionwhere B0 and BF are average of half-value breadth which are given by core of material and plastic zone of dynamic fracture.

X-Ray Residual Stress Measurement on Stress Corrosion Fracture Surfaces

1992 ◽  
Vol 36 ◽  
pp. 543-549
Author(s):  
Masaaki Tsuda ◽  
Yukio Hirose ◽  
Zenjiro Yajima ◽  
Keisuke Tanaka
Keyword(s):  
Fracture Toughness ◽  
Residual Stress ◽  
Fracture Surface ◽  
Stress Corrosion ◽  
Stress Measurement ◽  
High Strength Steels ◽  
High Strength ◽  
X Ray Diffraction ◽  
X Ray ◽  
Fracture Surfaces

X-ray fractography is a new method utilizing the X-ray diffraction technique to observe the fracture surface for the analysis of the micromechanisms and mechanics of fracture. X-ray residual stress has been confirmed to be a particularly useful parameter when studying the fracture surfaces of high strength steels. The method has been applied to the fracture surface of fracture toughness and fatigue specimens.

Influence of Core on Face/Core Debond Toughness

2000 ◽  
Author(s):  
Gilmer M. Viana Camps ◽  
Leif A. Carlsson ◽  
Xiaoming Li
Keyword(s):  
Fracture Toughness ◽  
Plastic Zone ◽  
Fracture Resistance ◽  
Plastic Zone Size ◽  
Foam Core ◽  
Zone Size ◽  
Anisotropic Behavior ◽  
Mode Mixity ◽  
The Core ◽  
The Difference

Abstract The influence of mechanical properties and fracture toughness of the core on debond fracture toughness of foam core sandwich has been examined. It was found that the fracture toughness for debonding was larger than the core toughness. The observed difference between core fracture toughness and face/core debonding toughness was analyzed using plastic zone size and mode mixity arguments. The difference in toughness can not be explained by plastic zone size and mode mixity effects. It is possible that the core displays a gradient in properties and fracture resistance, and anisotropic behavior which might explain the difference in toughness.

Application of Microbeam X-Ray Technique to the Evaluation of the Plastic Zone Size of Fatigued Steels

1978 ◽  
Vol 22 ◽  
pp. 221-226 ◽  
Author(s):  
Akimasa Izumiyama ◽  
Yasuo Yoshioka ◽  
Masao Terasawa
Keyword(s):  
Plastic Zone ◽  
Low Carbon Steel ◽  
Plastic Zone Size ◽  
Fracture Analysis ◽  
Low Carbon ◽  
Zone Size ◽  
X Ray Diffraction ◽  
Fatigue Fracture Surface ◽  
X Ray ◽  
Cyclic Plastic Zone

The microbeam X-ray diffraction technique was used for the evaluation of fracture analysis on the fatigued low carbon steel specimens.It is possible to evaluate both monotonic and cyclic plastic zone sizes beneath fatigue fracture surface. Thus the stress intensity factor can be estimated.

Fracture toughness, critical crack length and plastic zone size in bone

1978 ◽  
Vol 11 (8-9) ◽  
pp. 359-364 ◽  
Author(s):  
Diane Margel Robertson ◽  
David Robertson ◽  
Craig R Barrett
Keyword(s):  
Fracture Toughness ◽  
Plastic Zone ◽  
Crack Length ◽  
Plastic Zone Size ◽  
Zone Size ◽  
Critical Crack ◽  
Critical Crack Length

Estimation of Welding-Induced Plastic Zone Size and Residual Stress Levels: Linear Heat Input Approximation

2021 ◽  
Author(s):  
Sachin Bhardwaj ◽  
R. M. Chandima Ratnayake
Keyword(s):  
Residual Stress ◽  
Finite Element ◽  
Plastic Zone ◽  
Heat Input ◽  
Plastic Zone Size ◽  
Zone Size ◽  
Linear Heat ◽  
Highly Nonlinear ◽  
Stress Levels

Abstract Welding is a highly nonlinear temperature distribution process, where the presence of high-temperature gradients leads to the development of significantly high residual stress levels, up to and/or beyond the material yield strength magnitude and localized plastic deformation. To achieve the desired dimensional accuracy, determination of plastic zone size, shape, and location is critically important in reducing or controlling final distortions, decreasing the residual stress according to length scale, and defining the optimum sequence of the welding process. The plastic zone caused by welding has been found to be directly proportional to linear heat input, defined in (J/mm). The use of actual linear heat input in the estimation of welding-induced residual stress in finite element models often results in an overestimation of heat transferred to the fusion zone of the metal. This manuscript highlights the importance of estimating plastic zone, developed during thermal processes like welding, and its role in mitigating final distortion by using a 3-bar model for the determination of final residual stresses. In the second part, previously developed analytical linear heat input solution for 2D residual stress models is discussed and further demonstrated using examples from open literature. Lastly, a sequentially uncoupled thermal and thermo-mechanical finite element analysis (FEA) is performed, using a generalized plane strain element, and concluded by validation of the numerically developed plastic zone size with analytically developed solutions.

An Analytical Method for Estimating Welding-Induced Plastic Zone Size for Residual Stress Profile Development

2015 ◽  
Author(s):  
Xianjun Pei ◽  
Shaopin Song ◽  
Pingsha Dong
Keyword(s):  
Heat Transfer ◽  
Residual Stress ◽  
Finite Element ◽  
Plastic Zone ◽  
Analytical Method ◽  
Plastic Zone Size ◽  
Stress Profile ◽  
Zone Size ◽  
Residual Stress Profile ◽  
Residual Stress Analysis

As demonstrated in a recent comprehensive study on construction of full-field residual stress profiles for fitness-for-service assessment of pressure vessel and piping components, a reasonable estimate of welding-induced plastic zone size is necessary for introducing a shell theory based solution form (Song et al, 2015 [1–2]). This paper presents an analytical method for estimating plastic zone size by first solving an equivalent one dimensional heat transfer problem in which weld zone is represented by a line segment with initial temperature at melting. Thermoplasticity conditions are then imposed by assuming elastic perfectly plastic behaviors. Finally, an analytical expression is obtained to relate plastic zone boundary to maximum temperature field distribution experienced by material points within the whole domain over the entire heating and cooling history. The solution can be further expressed by a rather simple form with the identification of a characteristic length parameter that signifies inflection point of temperature distribution. So estimated plastic zone sizes for various welded joint types have been compared with finite element residual stress analysis results in which sequentially coupled welding heat transfer and thermo-mechanical analysis procedures are used. A good agreement has been achieved for all cases analyzed. Compared with conventional finite element residual stress analysis procedures, this method offers significant simplicity and efficiency, while being reasonably accurate, particularly for applications in residual stress profile estimation and in evaluation of welding induced distortions in complex structures.

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