Sage Journals: Discover world-class research

Abstract

The mechanical properties of ceramic microspheres (SLG) reinforced phenolic resin composites have been measured and evaluated in earlier studies. This basic but critical and important data has created interest in the relevant industry in Australia. This study is therefore carried out to measure and evaluate the dielectric and mechanical properties of the composites with a view to benefit the relevant industry. The relationship between the two properties will also be studied. The original contributions of this article are that samples post-cured in conventional ovens have higher electrical loss as well as mechanical loss than their counterparts post-cured in microwaves. The storage modulus of all samples post-cured conventionally is higher than its counterpart. This is in line with the fact that it is a softer material with lower glass transition temperature. They also have higher mechanical loss tangent as well as loss modulus. For all percentages by weight of SLG, the glass transition temperature for the microwave cured sample was higher and the composite was stiffer; the opposite was true for the conventionally cured sample.

Keywords

phenolic resin ceramic microspheres dielectric loss tangent mechanical loss tangent glass transition temperature storage modulus and microwaves.

Get full access to this article

View all access options for this article.

References

Munoz, J.-C. , Ku, H. , Cardona , F. and Rogers, D. (2008). Effects of Catalysts and Post-Curing Conditions in the Polymer Network of Epoxy and Phenolic Resins: Preliminary Results, Journal of Materials Processing Technology , 202: 486-492.

Cardona, F. , Ku, H. , Pattarachaiyakoop, N. , Rogers, D. , Trada, M. and Rogers, D. (2007). Fracture Toughness of Phenol Formaldehyde Composites Post-cured in Microwaves, Journal of Electromagnetic Waves and Applications, 21(14): 2137-2146.

Ku, H. , Rogers, D. , Davey, R. , Cardona, F. and Trada, M. (2008). Fracture Toughness of Phenol Formaldehyde Composites: Pilot Study, Journal of Materials Engineering and Performance , 17(1): 85-90.

Cardona, F. , Rogers, D. , Gurney, R. , Trada, M. and Ku, H. (2008). Flexural Tests of Phenol Formaldehyde and SLG Composites: Preliminary Results, Journal of Reinforced Plastics and Composites (accepted for publication).

Ku, H. , Cardona, F. , Pattarachaiyakoop, N. , Trada, M. and Rogers, D. (2007). Fracture Toughness of Phenol Formaldehyde Composites Reinforced with E-spheres, Journal of Materials Processing Technology (accepted for publication).

Chemwatch. (2005). Material Safety Data Sheet for Hexion Cellobond J2027L: 1-14.

Chemwatch. (2005). Material Safety Data Sheet for Hexion Phencat, 15: 1-14.

Clarke, J.L. (ed.) (1996). Structural Design of Polymer Composites, E & FN Spon , UK, pp. 59-62, 343-345, 357.

Strong, A.B. (2006). Plastics: Materials and Processing, 3rd edn, Pearson/Prentice-Hall , pp. 182-183, 304-309, 323-333, 620-621.

10.

E-spheres (undated). www.envirospheres.com.au, Envirospheres Pty Ltd., P. O. Box 497, NSW 2070, Australia.

11.

Cardona, F. , Ku, H. , Pattarachaiyakoop , N. , Rogers, D. , Trada, M. and Rogers, D. (2007). Fracture Toughness of Phenol Formaldehyde Composites Post-Cured in Microwaves , Journal of Electromagnetic Waves and Applications , 21(14): 2137-2146.

12.

Metaxas, A.C. and Meredith, R.J. (1983). Industrial Microwave Heating, Peter Peregrinus Ltd., 5-6, 28-31, 43, 211, 217, 278, 284-5.

13.

Kraus, J.D. (1992). Electromagnetics, 4th edn, McGraw-Hill, pp. 95-98, 186-189.

14.

Ball, J. and Hancock, N. (2007). Fields and Waves, USQ Studybook , 3.1-3.3.

15.

Li, L. (2000). Dynamic Mechanical Analysis (DMA), Basics and Beyond, Perkin Elmer Inc., pp. 3, 15, 17.

16.

Ku, H. , Trada, M. , Cardona, F. , Jacobson, W. and Rogers, D. (2008). Tensile Tests of Phenol Formaldehyde SLG Reinforced Composites Post-Cured in Microwaves: Preliminary Results, Journal of Composite Materials (accepted for publication).

17.

Ku, H. , Jacobson, W. , Trada, M. , Cardona, F. and Rogers, D. (2008). Tensile Tests of Phenol Formaldehyde SLG Reinforced Composites: Pilot Study, Journal of Composite Materials (accepted for publication).

18.

Callister, W.D. (2005). Fundamental of Materials Science and Engineering: An Integrated Approach, 2nd edn, Wiley International, p. 184.

19.

Wang, S. , Adanur, S. and Jang, B.Z. (1997). Mechanical and Thermo-Mechanical Failure Mechanism Analysis of Fibre/Filler Reinforced Phenolic Matrix Composite, Composites Part B, 28B: 215-231.

Relationship Between Electrical and Mechanical Loss Tangents of SLG Reinforced Phenolic Composites: Pilot Study

Abstract

Keywords

Get full access to this article

References