Effect of Power Signal Waveform on Shape Accuracy in Electrochemical Drilling

Additive manufacturing processes offer high geometric flexibility and allow the use of new alloy concepts due to high cooling rates. For each new material, parameter studies have to be performed to find process parameters that minimize microstructural defects such as pores or cracks. In this paper, we present a system developed in Python for accelerated image analysis of optical microscopy images. Batch processing can be used to quickly analyze large image sets with respect to pore size distribution, defect type, contribution of defect type to total porosity, and shape accuracy of printed samples. The open-source software is independent of the microscope used and is freely available for use. This framework allows us to perform such an analysis on a circular area with a diameter of 5 mm within 10 s, allowing detailed process maps to be obtained for new materials within minutes after preparation.

Download Full-text

Influence of a closed-loop controlled laser metal wire deposition process of S Al 5356 on the quality of manufactured parts before and after subsequent machining

Production Engineering ◽

10.1007/s11740-021-01030-w ◽

2021 ◽

Author(s):

Dina Becker ◽

Steffen Boley ◽

Rocco Eisseler ◽

Thomas Stehle ◽

Hans-Christian Möhring ◽

...

Keyword(s):

Wall Thickness ◽

Closed Loop ◽

Deposition Process ◽

Metal Wire ◽

Machining Process ◽

Machining Processes ◽

Initial State ◽

Additive Process ◽

Shape Accuracy ◽

Loop Control

AbstractThis paper describes the interdependence of additive and subtractive manufacturing processes using the production of test components made from S Al 5356. To achieve the best possible part accuracy and a preferably small wall thickness already within the additive process, a closed loop process control was developed and applied. Subsequent machining processes were nonetheless required to give the components their final shape, but the amount of material in need of removal was minimised. The effort of minimising material removal strongly depended on the initial state of the component (wall thickness, wall thickness constancy, microstructure of the material and others) which was determined by the additive process. For this reason, knowledge of the correlations between generative parameters and component properties, as well as of the interdependency between the additive process and the subsequent machining process to tune the former to the latter was essential. To ascertain this behaviour, a suitable test part was designed to perform both additive processes using laser metal wire deposition with a closed loop control of the track height and subtractive processes using external and internal longitudinal turning with varied parameters. The so manufactured test parts were then used to qualify the material deposition and turning process by criteria like shape accuracy and surface quality.

Download Full-text

Shape accuracy of fiber optic sensing for medical devices characterized in bench experiments

Medical Physics ◽

10.1002/mp.14881 ◽

2021 ◽

Author(s):

Mischa Megens ◽

Merel D. Leistikow ◽

Anneke van Dusschoten ◽

Martin B. van der Mark ◽

Jeroen J.L. Horikx ◽

...

Keyword(s):

Medical Devices ◽

Fiber Optic ◽

Shape Accuracy ◽

Fiber Optic Sensing

Download Full-text

An Investigation into the Effect of Rolling Reduction on 3D Curved Parts Rolling Process

Metals ◽

10.3390/met11081209 ◽

2021 ◽

Vol 11 (8) ◽

pp. 1209

Author(s):

Xiang Chang ◽

Wenzhi Fu ◽

Mingzhe Li ◽

Xintong Wang ◽

Weifeng Yang ◽

...

Keyword(s):

Element Model ◽

Rolling Process ◽

Rolling Reduction ◽

Shape Accuracy ◽

Bending Deformation ◽

Good Shape ◽

Longitudinal Bending ◽

Gap Height ◽

Roll Gap ◽

Forming Tools

Rolling technology based on arc-shaped rollers is a novel method for rapid manufacturing of 3D curved parts. The method uses a pair of arc-shaped rollers (a convex roller and a concave roller) as forming tools, forming an unevenly distributed roll gap. The sheet metal has both transverse bending and longitudinal uneven extension during rolling, so that surface parts with double curvature are processed. The curvature of the formed surface part can be changed by changing the rolling reduction. Changing the vertical distance between the rollers will cause the overall change of the roll gap height, which will inevitably have a great impact on the forming effect of formed 3D curved parts. In this paper, a finite element model and experiment with different rolling reductions was designed; the influence of rolling reduction on the bending deformation and shape accuracy of formed 3D curved parts was studied. The results show that, with the slight increase of rolling reduction (from 0.04 to 0.12 mm), the longitudinal bending deformation of the formed 3D curved part increases significantly, but its transversal bending is almost not affected. When the maximum rolling reduction is 0.04 and 0.06 mm (the corresponding minimum rolling reduction is less than or equal to zero), the shape accuracy of the formed 3D curved parts is not good enough; when the maximum rolling reduction is greater than 0.06 mm (the corresponding minimum rolling reduction is greater than zero), the shape accuracy of the formed 3D curved parts is significantly better. This indicates that, for the rolling of 3D curved parts based on arc-shaped rollers, ensuring that the minimum rolling reduction is greater than zero is the key to ensuring good shape accuracy of the formed 3D curved parts.

Download Full-text