Your search keyword '"Le, Jia"' showing total 3 results

1. Determination of strength distribution of quasibrittle structures from mean size effect analysis.

Author

Le, Jia-Liang, Cannone Falchetto, Augusto, and Marasteanu, Mihai O.

Subjects

*STRENGTH of materials, *DISTRIBUTION (Probability theory), *MATERIALS at low temperatures, *HISTOGRAMS, *ASPHALT, *MIXTURES

Abstract

Highlights: [•] We present an indirect method to determine the strength distribution of quasibrittle structures. [•] The method is verified by a set of experiments on asphalt mixture at a low temperature. [•] The finite weakest link model agrees well with the measured strength histograms of specimens of different sizes. [ABSTRACT FROM AUTHOR]

Published

2013

2. Size effect on strength and lifetime probability distributions of quasibrittle structures.

Author

BAŽANT, ZDENĚK and LE, JIA-LIANG

Subjects

*STRENGTH of materials, *SIZE effects in metallic films, *SERVICE life, *DISTRIBUTION (Probability theory), *STRUCTURAL analysis (Engineering), *MICROELECTROMECHANICAL systems, *INTEGRATED circuits, *SCALING (Fouling)

Abstract

Engineering structures such as aircraft, bridges, dams, nuclear containments and ships, as well as computer circuits, chips and MEMS, should be designed for failure probability < 10-10 per lifetime. The safety factors required to ensure it are still determined empirically, even though they represent much larger and much more uncertain corrections to deterministic calculations than do the typical errors of modern computer analysis of structures. The empirical approach is sufficient for perfectly brittle and perfectly ductile structures since the cumulative distribution function (cdf) of random strength is known, making it possible to extrapolate to the tail from the mean and variance. However, the empirical approach does not apply to structures consisting of quasibrittle materials, which are brittle materials with inhomogeneities that are not negligible compared to structure size. This paper presents a refined theory on the strength distribution of quasibrittle structures, which is based on the fracture mechanics of nanocracks propagating by activation energy controlled small jumps through the atomic lattice and an analytical model for the multi-scale transition of strength statistics. Based on the power law for creep crack growth rate and the cdf of material strength, the lifetime distribution of quasibrittle structures under constant load is derived. Both the strength and lifetime cdf's are shown to be size- and geometry-dependent. The theory predicts intricate size effects on both the mean structural strength and lifetime, the latter being much stronger. The theory is shown to match the experimentally observed systematic deviations of strength and lifetime histograms of industrial ceramics from the Weibull distribution. [ABSTRACT FROM AUTHOR]

Published

2012

3. Unified nano-mechanics based probabilistic theory of quasibrittle and brittle structures: I. Strength, static crack growth, lifetime and scaling

Author

Le, Jia-Liang, Bažant, Zdeněk P., and Bazant, Martin Z.

Subjects

*BRITTLENESS, *MICROMECHANICS, *NANOTECHNOLOGY, *DISTRIBUTION (Probability theory), *STRENGTH of materials, *STRUCTURAL engineering, *FRACTURE mechanics, *ACTIVATION (Chemistry)

Abstract

Abstract: Engineering structures must be designed for an extremely low failure probability such as 10−6, which is beyond the means of direct verification by histogram testing. This is not a problem for brittle or ductile materials because the type of probability distribution of structural strength is fixed and known, making it possible to predict the tail probabilities from the mean and variance. It is a problem, though, for quasibrittle materials for which the type of strength distribution transitions from Gaussian to Weibullian as the structure size increases. These are heterogeneous materials with brittle constituents, characterized by material inhomogeneities that are not negligible compared to the structure size. Examples include concrete, fiber composites, coarse-grained or toughened ceramics, rocks, sea ice, rigid foams and bone, as well as many materials used in nano- and microscale devices. This study presents a unified theory of strength and lifetime for such materials, based on activation energy controlled random jumps of the nano-crack front, and on the nano-macro multiscale transition of tail probabilities. Part I of this study deals with the case of monotonic and sustained (or creep) loading, and Part II with fatigue (or cyclic) loading. On the scale of the representative volume element of material, the probability distribution of strength has a Gaussian core onto which a remote Weibull tail is grafted at failure probability of the order of 10−3. With increasing structure size, the Weibull tail penetrates into the Gaussian core. The probability distribution of static (creep) lifetime is related to the strength distribution by the power law for the static crack growth rate, for which a physical justification is given. The present theory yields a simple relation between the exponent of this law and the Weibull moduli for strength and lifetime. The benefit is that the lifetime distribution can be predicted from short-time tests of the mean size effect on strength and tests of the power law for the crack growth rate. The theory is shown to match closely numerous test data on strength and static lifetime of ceramics and concrete, and explains why their histograms deviate systematically from the straight line in Weibull scale. Although the present unified theory is built on several previous advances, new contributions are here made to address: (i) a crack in a disordered nano-structure (such as that of hydrated Portland cement), (ii) tail probability of a fiber bundle (or parallel coupling) model with softening elements, (iii) convergence of this model to the Gaussian distribution, (iv) the stress-life curve under constant load, and (v) a detailed random walk analysis of crack front jumps in an atomic lattice. The nonlocal behavior is captured in the present theory through the finiteness of the number of links in the weakest-link model, which explains why the mean size effect coincides with that of the previously formulated nonlocal Weibull theory. Brittle structures correspond to the large-size limit of the present theory. An important practical conclusion is that the safety factors for strength and tolerable minimum lifetime for large quasibrittle structures (e.g., concrete structures and composite airframes or ship hulls, as well as various micro-devices) should be calculated as a function of structure size and geometry. [Copyright &y& Elsevier]

Published

2011