Manufacturability of Fine-Celled Cellular Structures in Rotational Foam Molding-Reference-Cited by-同舟云学术

Manufacturability of Fine-Celled Cellular Structures in Rotational Foam Molding

Published:2004-01 Issue:1 Volume:40 Page:13-25
ISSN:0021-955X
Container-title:Journal of Cellular Plastics
language:en
Short-container-title:Journal of Cellular Plastics

Author:

Pop-Iliev Remon¹,Xu Donglai,Park Chul B.²

Affiliation:

1. School of Manufacturing Engineering University of Ontario, Institute of Technology Oshawa, Ontario, Canada, LIH 7K4

2. Microcellular Plastics Manufacturing Laboratory Department of Mechanical & Industrial Engineering University of Toronto, Toronto, Ontario, Canada M5S 3G8

Abstract

Any closed-cell polyolefin foam production tends to achieve the highest possible cell size distribution uniformity, cell size reduction, and cell density augmentation. However, the control of the cell size of rotationally foam-molded cellular structures formed on the base of a chemical blowing agent (CBA) might be often aggravated by some inherent limitations that are unique to the rotational molding process, which results in coarser-celled final cellular structures. Although a fine-celled morphology (cell size<100 [mm] and cell density > 106 [cells/cm3]) in rotationally molded foams has been closely approached, it has not been actually achieved yet, nor has it been ever clarified whether it is actually achievable in rotational foam molding or not. This study attempts to provide an answer to this fundamental question by focusing on the understanding of the mechanisms governing the formation, growth, shrinkage, and collapse of CBA-blown bubbles in nonpressurized polymer melts originating from extrusion melt compounded foamable resins in a pellet form.

Publisher

SAGE Publications

Subject

Materials Chemistry,Polymers and Plastics,General Chemistry

Link

http://journals.sagepub.com/doi/pdf/10.1177/0021955X04039215

Reference11 articles.

1. 3. Pop-Iliev, R., Rizvi, G.M. and Park, C.B. (2001). SPE , ANTEC, Technical Papers, 47: 1598-1598 .

2. 4. Throne, J.L. (2000). SPE ANTEC, Tech. Papers, 46: 1304-1304 .

3. 7. Pop-Iliev, R., Park, C.B., Liu, G. and Liu, F. (2000). SPE, ANTEC, Technical Papers, 46: 1896-1896 .

4. 10. Bellehumeur, C.T. and Tiang, J.S. (2000). SPE ANTEC, Technical Papers, 46: 1356-1356 .

5. Melting and densification of thermoplastic powders

Cited by 19 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Foaming‐structural relationship of rotational molded nanocomposite foams: Box–Behnken response surface methodology implementation;Polymers for Advanced Technologies;2024-07

2. Improved Rotational Foam Molding Properties of Tailored Polyethylene Blends with Higher Crystallization Temperature and Viscosity-Temperature Sensitivity;Polymers;2022-08-25

3. Foam 3D Printing of Thermoplastics: A Symbiosis of Additive Manufacturing and Foaming Technology;Advanced Science;2022-02-20

4. Foam manufacturing technologies;Foamability of Thermoplastic Polymeric Materials;2022

5. Morphological, thermal and mechanical properties of recycled HDPE foams via rotational molding;Journal of Cellular Plastics;2021-04-29