Intelligent toolpath for extrusion‐based LM process-Reference-Cited by-同舟云学术

Intelligent toolpath for extrusion‐based LM process

Published:2001-03-01 Issue:1 Volume:7 Page:18-24
ISSN:1355-2546
Container-title:Rapid Prototyping Journal
language:en
Short-container-title:

Author:

Qiu Dan,Langrana Noshir A.,Danforth Stephen C.,Safari Ahmad,Jafari Mohsen

Abstract

To fabricate high quality parts, and to make the development generic yet compatible with the in‐house hardware, a virtual simulation system has been developed, and an in‐house intelligent multi‐material toolpath generation system has been under development. This new development includes the issues such as multiple fill‐toolpaths for the same material, interface mismatch between adjacent materials and the intelligent toolpath features for machine control. After the multi‐material toolpath file generated by the in‐house software, the existing virtual graphical simulation as well as well selected part fabrication experiments were used to validate it. Based on the authors’ ongoing research about multi‐material layered manufacturing, it was determined that the build characteristic was heavily dependent on the material being used. Therefore, it was important to develop the hardware/software that will accommodate this requirement.

Publisher

Emerald

Subject

Industrial and Manufacturing Engineering,Mechanical Engineering

Reference12 articles.

1. Agarwala, M., Bandyopadhyay, A., van Weeren, R., Jamalabad, V., Whalen, P., Langrana, N.A., Safari,A. and Danforth, S.C. (1996), “Fused deposition of ceramics’’, Journal of Rapid Prototyping, Vol. 2 No.4, pp. 4‐19.

2. Aubin, R.F. (1994), “A world wide assessment of rapid prototyping technologies”, United Technologies Center, East Hartford, CT.

3. Bossett, E., Rivera, L., Qiu, D., McCuiston, R., Langrana, N., Rangarajan, S., Venkataraman, N., Danforth,S.C. and Safari, A. (1998), “Real time video microscopy for the fused deposition method”, Proceedings of the Solid Freeform Fabrication Symposium, The University of Texas at Austin, TX, pp. 113‐20.

4. Cesarano III, J., King, B.H. and Denham, H.B. (1998), “Recent developments in robocasting ceramics and multi‐material deposition”, Proceedings of the Solid Freeform Fabrication Symposium, The University of Texas at Austin, TX, pp. 697‐703.

5. Clancy, P., Jamalabad, V., Whalen, P., Bhargavap, P., Dai,C., Qi, G., Rangarajan, S., Wu, S., Danforth, S., Langrana, N. and Safari, A. (1997), “Fused deposition of ceramics: progress towards a robust and controlled process for commercialization”, Proceedings of the Solid Freeform Fabrication Symposium, The University of Texas at Austin, TX, pp. 185‐93.

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