The Effect of Ultrasonic Excitation in Metal Forming Tests

S. Abdul Aziz; Margaret Lucas

doi:10.4028/www.scientific.net/AMM.24-25.311

Paper Titles

Skin Thermal Effect by FE Simulation and Experiment of Laser Ultrasonics
p.281

Biomechanics and Numerical Evaluation of Cervical Porcine Models Considering Compressive Loads Using 2-D Classic Computer Tomography CT, 3-D Scanner and 3 -D Computed Tomography
p.287

Spot Weld Strength Determination Using the Wedge Test: In Situ Observations and Coupled Simulations
p.299

Improving Fatigue Performance of Alumino-Thermic Rail Welds
p.305

The Effect of Ultrasonic Excitation in Metal Forming Tests
p.311

Modeling of Coating Stress of Plasma-Sprayed Thermal Barrier Coatings
p.317

Tensile Properties of Die-Cast Magnesium Alloy AZ91D at High Strain Rates in the Range between 300 s^-1 and 1500 s^-1
p.325

The Dynamic Buckling of Stiffened Panels –A Study Using High Speed Digital Image Correlation
p.331

Finite Element Model Updating of a Thin Wall Enclosure under Impact Excitation
p.337

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 24-25The Effect of Ultrasonic Excitation in Metal...

The Effect of Ultrasonic Excitation in Metal Forming Tests

Abstract:

The use of ultrasonic excitation of tools and dies in metal forming operations has been the subject of ongoing research for many years. However, the lack of understanding about the effects of ultrasonic vibrations on the forming process has resulted in difficulties in maximising the benefits and applications of this technology. In particular, experimental characterisations of the effects of superimposing ultrasonic oscillations have largely relied on interpretations of measurements of the mean forming load and have ignored the oscillatory forces. Previous research [1] has shown that by applying ultrasonic vibrations to the lower platen in compression tests on pure aluminium specimens, the resulting stress-strain relationship can be characterised by a temporary effective softening of the material during intervals of ultrasonic excitation. The current research investigates this effect in a series of simple forming tests using a number of different metal specimens. In this research, the forming tests are conducted using a piezoelectric force transducer to measure the oscillatory force data during ultrasonic excitation of the die. It is shown that the benefits of superimposing ultrasonic excitation of the die are highly dependent on the material being formed and that, in many cases, the maximum oscillatory force exceeds the static forming load even where the mean forming load is reduced significantly during the interval of ultrasonic excitation.

By email Full Text Pdf

You have full access to the following eBook