Digital Image Correlation

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Presentation transcript:

Digital Image Correlation Egil Fagerholt 25 August 2015

DIC – Basic Principle DIC Reference image No deformation Disp. X Strain Current image At deformed stage Disp. Y DIC – Basic Principle Example: Uniaxial tension test Load cell Random speckle pattern Linear transducer DIC Camera Optical axis normal to specimen surface (2D-DIC)

DIC – 2D vs. 3D setup 3D 2D Two cameras Stereovision Single camera Requirements: Optical axis normal to specimen surface Specimen surface is plane during experiment Limitations: Only in-plane displacements are measured Benefits: Simple setup Limited camera calibration 2D Single camera Target coordinates Requirements: Full camera calibration Benefits: Specimen may have an arbitrary shape Both in-plane and out-of-plane displacements are measured General limitations (both 2D and 3D): No through-thickness deformation is measured

DIC versus traditional measurement techniques Extensometer Strain gauges 2D-DIC Full-field displacement/strain measurements Elongations extracted during post-processing Elongation over a fixed distance Strain in a small area 3D-DIC Laser Deflection of plate

DIC – Measurement uncertainty Measurement uncertainties are mainly due to grayscale noise in the recorded images, which varies from camera to camera. Typical resolution in displacements are less than: 0.1 pixel 5MP (2448 x 2050 pixels) Specimen length: 200 mm Specimen width: 12.5 mm Example: Uniaxial tension test Strain resolution is typically down to Local strains as high as 200% can be measured (e.g. polymers)

DIC - Measurement uncertainty Small elements -> better description of disp. field Large elements -> Less suceptible to grayscale noise Compromize

Software eCorr Graphical Interface Main Functionalities Recording of image series Camera calibration for 3D-DIC Mesh generation/modification 2D/3D-DIC Analysis Visualization and export of data DIC Core

Range of applications Examples Material tests Component Tests Crack propagation Pipeline Impact Blast loading of plates Point Tracking

Material model validation DIC-FEM coupling Strains measured by DIC Calculated stress fields Material model Material model parameters Cross section Computed force from DIC and material model Experimental force from load cell

Validation of 3D-DIC SIMLab Shocktube

Validation of 3D-DIC Camera Calibration

Validation of 3D-DIC Initial Results Steel 0.8mm 75 bar Aluminium 0.8 mm 2.5 bar Avvik ~ 1/100 mm

Validation of 3D-DIC Frame tracking Steel 0.8mm 40 bar

Validation of 3D-DIC

Validation of 3D-DIC