An Inverse Modeling Method for Acoustic Emission Source of Cracking

Li Li; Ji Li

doi:10.4028/www.scientific.net/AMM.333-335.1742

Paper Titles

Analysis of the Coral Reef Evolution Based on Satellite Remote Sensing Images
p.1719

Characteristics of the Spatial and Temporal Variations of Ambient PM_2.5 Concentration at Kaohsiung City
p.1724

Portable Fault Diagnostic System Based on Network and PDA
p.1731

Anti-Collision Distance Prediction Model Based on Spherical Wave Propagation Theory
p.1736

An Inverse Modeling Method for Acoustic Emission Source of Cracking
p.1742

Application of Classified Hierarchical Model to Fault Diagnosis of Electrical System
p.1746

Knowledge-Based Fault Diagnostic System Using Binary Fault Tree
p.1752

The Neural Network Prediction to the Wear and Tear Fault of Thrust Bearing in Air Compressor
p.1758

Design and Realization of Control Module Fault Analysis System Based on Fault Tree
p.1762

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 333-335An Inverse Modeling Method for Acoustic Emission...

An Inverse Modeling Method for Acoustic Emission Source of Cracking

Abstract:

Crack formation is a severe problem concerning steel structures under service loading. Understanding of the mechanism of crack initiation and propagation is therefore critical to structure safety design and maintenance. Although many efforts were put into crack mechanism studying, and some progress has been made in the aspect of crack propagation, the problem of crack initiation i.e. cracking remains left unsolved. In this paper, an inverse modeling method for acoustic emission (AE) source of cracking was proposed for the mechanism revelation. In the method, AE signal was related to crack stress based on the theory of elasto-dynamics; the crack stress was inversely modeled from AE signal by half-space Greens function and procedure of de-convolution. In an application to the AE testing for steel structure cracking, AE source function representing the time history of crack stress was obtained. The crack stress was found to be a step-like function with a pulse, and with it the mechanism of cracking was recovered. The results indicated that, the modeling method is effective for the study on mechanism of cracking.