EXPERIMENTAL INVESTIGATION OF AXIAL COMPRESSIVE STRENGTH OF LIGHTWEIGHT FOAMED CONCRETE WITH DIFFERENT ADDITIVES

Authors

  • M. A. Othuman Mydin School of Housing, Building and Planning, Universiti Sains Malaysia, 11800, Penang, Malaysia

DOI:

https://doi.org/10.11113/jt.v78.8354

Keywords:

Foamed concrete, compressive strength, additives, pozzolanic material

Abstract

This paper focuses on experimental study to investigate the effects of different additives on axial compressive strength of lightweight foamed concrete (LFC). The additives used are pulverized fuel ash, wood ash, silica fume, palm oil fuel ash, polypropylene fibre, coconut fibre and steel fibre. These additives have different abilities that contribute positive outcomes to the properties of LFC. Pozzolanic materials and fibres were used as additives to be associated with plain LFC mixtures to improve its mechanical properties. Coir fibre recorded the highest compressive strength in 7 days compared to other additives and the control sample. Coir fibre of 0.4% (CF 0.4) reached highest strength in 180 days without allowing other additives to overcome its strength. The more the inclusion of fibres, the higher the strength obtained due to its low cellulose content, and high percentage and large diameter of lignin. The short length fibres hold the particles stronger.

References

Demirbog, R., Gul, R. 2003. The Effects of Expanded Perlite Aggregate, Silica Fume and Fly Ash on the Thermal Conductivity of Lightweight Concrete. Cement and Concrete Research Journal. 33(5): 723-727.

Awang, H., M. A. Othuman Mydin, A. F. Roslan. 2012. Microstructural Investigation of Lightweight Foamed Concrete Incorporating Various Additives. International Journal of Academic Research. 4(2): 197-201.

Othuman Mydin, M. A., Y. C. Wang. 2012. Mechanical Properties of Foamed Concrete Exposed to High Temperatures. Journal of Construction and Building Materials. 26(1): 638-654.

Soleimanzadeh, S., M. A. Othuman Mydin. 2013. Influence of High Temperatures on Flexural Strength of Foamed Concrete Containing Fly Ash and Polypropylene Fiber. International Journal of Engineering. 26(1): 365-374.

Othuman Mydin, M. A. 2011. Thin-walled Steel Enclosed Lightweight Foamed Concrete: A Novel Approach to Fabricate Sandwich Composite. Australian Journal of Basic and Applied Sciences. 5(12): 1727-1733.

Roslan, A. H., H. Awang, M. A. Othuman Mydin. 2013. Effects of Various Additives on Drying Shrinkage, Compressive and Flexural Strength of Lightweight Foamed Concrete (LFC). Advanced Materials Research Journal. 626: 594-604.

Othuman Mydin, M. A., Y. C. Wang. 2012. Thermal and Mechanical Properties of Lightweight Foamed Concrete (LFC) at Elevated Temperatures. Magazine of Concrete Research. 64(3): 213-224.

Mustaffa, W. E. S. B., Mehilef, S., Saidur, R., Safari, A. 2011. Biomass Energy in Malaysia: Current State and Prospects. Renewable & Sustainable Energy Review. 15(7): 3360-3370.

Sahu, J. N., Abnisa, F., Daud, W. M. A, Husin, W. M. W. 2011. Utilization Possibilities of Palm Shell as a Source of Biomass Energy in Malaysia by Producing Bio-oil in Pyrolysis Process. Biomass and Bioenergy. 35(5): 1863-1872.

Johnson Alengaram, U., Al Muhit, B. A., Jumaat, M. Z., Michael, L. Y. J. 2013. A Comparison of the Thermal Conductivity of Oil Palm Shell Foamed Concrete With Conventional Materials. Materials & Design. 51: 522-529.

Othuman Mydin, M. A., 2013. Modeling of Transient Heat Transfer in Foamed Concrete Slab. Journal of Engineering Science and Technology. 8(3): 331-349.

Othuman Mydin, M. A. 2013. An Experimental Investigation on Thermal Conductivity of Lightweight Foamed concrete for Thermal Insulation. Jurnal Teknologi. 63(1): 43-49.

Othuman Mydin, M. A., Y. C. Wang, 2011. Elevated-Temperature Thermal Properties of Lightweight Foamed Concrete. Journal of Construction & Building Materials. 25(2): 705-716.

Bouguerra, A., Laurent, J. P., Goual, M. S., Queneudec, M. 1997. The Measurement of the Thermal Conductivity of Solid Aggregate Using the Transient Plane Source Technique. Journal of Physics D: Applied Physics. 30: 2900-2904.

Khan, M. I. 2002. Factor Affecting the Thermal Properties of Concrete and Applicability of Its Prediction Models. Building and Environment Journal. 37(6): 607-614.

Newman, J. B. 1993. Structural lightweight aggregate concrete, Chapter 2: Properties of Structural Lightweight Aggregate Concrete. Chapman & Hall.

Okpala, D. C. 1990. Palm Kernel Shell as Lightweight Aggregate in Concrete. Building and Environment Journal. 25(4): 291-296.

Downloads

Published

2016-04-18

Issue

Section

Science and Engineering

How to Cite

EXPERIMENTAL INVESTIGATION OF AXIAL COMPRESSIVE STRENGTH OF LIGHTWEIGHT FOAMED CONCRETE WITH DIFFERENT ADDITIVES. (2016). Jurnal Teknologi (Sciences & Engineering), 78(5). https://doi.org/10.11113/jt.v78.8354