Investigation of the Compression Recovery Properties of Polyamide-6 Cellular Solid over the Temperature Range of -5°C to 90°C

V.G. Izzard; C.H. Bradsell; H. Hadavinia; V.J. Morris; P.J.S. Foot; N. Witten

doi:10.4028/www.scientific.net/KEM.417-418.933

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HomeKey Engineering MaterialsKey Engineering Materials Vols. 417-418Investigation of the Compression Recovery...

Investigation of the Compression Recovery Properties of Polyamide-6 Cellular Solid over the Temperature Range of -5°C to 90°C

Abstract:

It is a fundamental response of any polymeric foam material to undergo non-recoverable deformation following the application of a defined compressive strain, exacerbated by temperature and humidity. This process is commonly referred to as compression set. The ability to predict recovery after the application of a compressive strain is crucial to both the manufacturers and end users of foam materials. Specific compression set test procedures have been established to quantify the extent of non-recoverable deformation in specific foam types but to date no general predictive approach exists. In this work, compression set (fixed strain) tests were undertaken on a cellular polyamide-6 material at various temperatures (-5°C to 90°C) and the foam recovery monitored over time periods in excess of those dictated by standard methods (ISO 1856 [1]). An empirical formula has been proposed to allow the prediction of recovery after compressive strain, covering recovery periods from 10 minutes to 24 hours (up to 168 hours at 23°C).

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Periodical:

Key Engineering Materials (Volumes 417-418)

Pages:

933-936

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.417-418.933

Citation:

Cite this paper

Online since:

October 2009

Authors:

V.G. Izzard, C.H. Bradsell, H. Hadavinia, V.J. Morris, P.J.S. Foot, N. Witten

Keywords:

Cellular Solid, Compression Set, Nylon, Polyamide Foam, Polymer Physics

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References

[1] BS EN ISO 1856: 2001 Incorporating amendments no 1: Flexible Cellular Polymeric Materials - Determination of Compression Set.

Google Scholar

[2] K.W. Park, G.H. Kim and S.R. Chowdhury: Improvement of Compression Set Property of Ethylene Vinyl Acetate Copolymer/Ethylene-1-Butene Copolymer/Organoclay (anocomposite Foams (June 2008) Polymer Engineering and Science p.1183.

DOI: 10.1002/pen.21073

Google Scholar

[3] T.D. Sreeja and S.K.N. Kutty: Studies on Acrylonitrile Butadiene Rubber/Reclaimed Rubber Blends (April 2002) Journal of Elastomers and Plastics Vol. 34 p.45.

DOI: 10.1106/009524402024278

Google Scholar

[4] I.S. Jhlham and I.J. Maita: Testing and Evaluation of Rubber-base Composites Reinforced with Silica Sand (2006) Journal of Composite Materials, Vol. 40 p. (2099).

DOI: 10.1177/0021998306061322

Google Scholar

[5] N.C. Nayak and D.K. Tripathy: Studies on Composites Based on Acrylonitrile Butadiene Rubber and High Styrene Resin (July 2001) Journal of Elastomers and Plastics Vol. 33 p.179.

DOI: 10.1106/h0hf-pxgn-rm67-722f

Google Scholar

[6] D. Bacci, R Marchini and M.T. Scrivani: Peroxide Crosslinking of Ziegler (atta Thermoplastic Polyolefins: (January 2004) Polymer Engineering and Science Vol. 44 p.131.

DOI: 10.1002/pen.20012

Google Scholar

[7] J.E. Coons, M.D. McKay and M.S. Hamada: A Bayesian Analysis of The Compression Set and Stress-Strain Behaviour in a thermally aged Silicone Foam (2006) Polymer Degradation and Stability p.1824.

DOI: 10.1016/j.polymdegradstab.2005.11.009

Google Scholar

[8] R.A. Neff and T.M. Marsalko: Roles of Convention Polyol and Isocyanate in humid Aging and Durability of Molded Seating Foam (Nov. 1999) Journal of Cellular Plastics Vol. 35 p.492.

DOI: 10.1177/0021955x9903500602

Google Scholar

[9] BS EN ISO 1923: 1995 Cellular Plastics and Rubbers-Determination of Linear Dimensions.

Google Scholar

[10] BS EN ISO 845: 1995 Incorporating amendments no. 1 Cellular Plastics and RubbersDetermination of Apparent (Bulk) Density.

Google Scholar