Combined In Situ X-Ray Computed Tomography and Acoustic Emission Analysis for Composite Characterization - A Feasibility Study

Miriam Bartkowiak; Ludwig Schoettl; Peter Elsner; Kay André Weidenmann

doi:10.4028/www.scientific.net/KEM.809.604

Paper Titles

Passive Thermography for Detection of Damaging Events during Quasi-Static Tensile Testing
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Region-of-Interest X-Ray Tomography for the Non-Destructive Characterization of Local Fiber Orientation in Large Fiber Composite Parts
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Optimization of the Specimen Geometry of Unidirectional Reinforced Composites with a Fibre Orientation of 90° for Tensile, Quasi-Static and Fatigue Tests
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Model-Based Quality Control System for Error Reduction in the Thermoforming Process
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Combined In Situ X-Ray Computed Tomography and Acoustic Emission Analysis for Composite Characterization - A Feasibility Study
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Controlling Moisture Content of Natural Fibres in RTM-Process
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Mechanical and Fracture Mechanical Properties of Matrix-Reinforced Carbon Fiber Composites with Carbon Nanotubes
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Novel Approach for the Lifetime Prediction of Composite Materials under Static Loads
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Testing of Composite Material for Transport Tanks for LNG
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 809Combined In Situ X-Ray Computed Tomography and...

Combined In Situ X-Ray Computed Tomography and Acoustic Emission Analysis for Composite Characterization - A Feasibility Study

Abstract:

Fiber reinforced plastics show a wide range of different damage mechanisms such as matrix cracking, fiber breakage and interface failure. These can be observed in damaged specimens by means of volumetric images acquired by computed tomography (CT). As each failure mechanism causes a characteristic acoustic emission (AE) signal, AE analysis is a promising tool to identify damage mechanisms and offers the advantage that a real-time observation of the damage evolution during the testing period is possible. For a correlation of damage mechanisms and AE events, AE analysis was combined with in- situ CT measurements. This combined approach was validated by means of a 3-point-bending test on a discontinuous glass fiber reinforced sheet molding compound (GF-SMC) in which AE signals were acquired during loading using two high frequency piezoelectric sensors. At times of increasing AE activity, the test was interrupted in order to carry out a CT-scan of the specimen under load. AE events could subsequently be linked with the damage mechanisms observed in the CT-scans at different stages of damage to identify signal features that are characteristic for a certain mechanism. The sources of the signals could be localized and were in line with the actual location of damage.

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Periodical:

Key Engineering Materials (Volume 809)

Pages:

604-609

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.809.604

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Online since:

June 2019

Authors:

Miriam Bartkowiak*, Ludwig Schoettl, Peter Elsner, Kay André Weidenmann

Keywords:

Acoustic Emission, Damage Mechanisms, Micro Computed Tomography (μCT) Analysis, Sheet Molding Compound

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