Thermal Properties of Oil Palm Shell Lightweight Concrete with Different Mix Designs

Authors

  • Eravan Serri School of Housing, Building and Planning, Universiti Sains Malaysia, 11800, Penang, Malaysia
  • Md Azree Othuman Mydin School of Housing, Building and Planning, Universiti Sains Malaysia, 11800, Penang, Malaysia
  • Mohd Zailan Suleiman School of Housing, Building and Planning, Universiti Sains Malaysia, 11800, Penang, Malaysia

DOI:

https://doi.org/10.11113/jt.v70.2507

Keywords:

Oil-palm shell, thermal conductivity, concrete, insulation

Abstract

Nowadays, the utilization of Oil Palm Shell (OPS) as lightweight aggregate in concrete especially in the structure application has become prevalent. As an industrial waste product, Oil Palm Shell (OPS) possibly will be the alternative material to be employed in the construction industry. With its advantage as heat resistant material, this study will focus on the potential of OPS as lightweight aggregate with regard to the optimum content of OPS for thermal insulating material. A total of 15 mixes were prepared and tested with 3 different cement/sand ratios (1.7, 1.8, 1.9) and 5 different cement contents (300, 350, 400, 450, 500 kg/m³). The result of this study show that the highest sand used will produced good workability but increased thermal conductivity of mix value. The test result indicates that the thermal conductivity and insulation criterion is substantially improved with the volume use of OPS and strong relationship between thermal conductivity and unit weight is obtained. The measured thermal conductivity value range from 0.54W/mC to 1.1 W/mC. The ideal value for semi structure insulation material establish by RILEM only  achieve for mix that used cement content 400 kg/m³ and below, which thermal conductivity is 0.75 W/mC below.  

Author Biography

  • Md Azree Othuman Mydin, School of Housing, Building and Planning, Universiti Sains Malaysia, 11800, Penang, Malaysia
    Sr Dr. Md Azree obtained his PhD in Civil Engineering at the University of Manchester, United Kingdom in 2010. This followed both a Bachelor of Science (Building Technology) and a Master of Science (Building Technology) that were earned in 2004 and 2005 respectively from Universiti Sains Malaysia, Penang, Malaysia. Before joining Universiti Sains Malaysia as a lecturer, he has worked with Penang Development Corporation Consultancy (PDCC) as a civil and structural engineer; completing numerous successful projects with PDC, PDC Properties, Techware and a few more civil engineering companies from 2005 until 2007.  His specialisation lies in the area of fire engineering, material properties, heat and mass transfer, sandwich construction, thin-walled structures and building surveying (condition survey, dilapidation survey, structural survey, dimensional survey, defect analysis on building and building maintenance). He has published his work in more than 30 indexed journals, and 15 conference proceedings in the field of engineering, building material and building surveying

References

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.

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. Thermal and Mechanical properties of Lightweight Foamed Concrete (LFC) at Elevated Temperatures. Magazine of Concrete Research. 64(3): 213–224.

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

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.

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., Y. C. Wang. 2011. Structural Performance of Lightweight Steel-foamed Concrete-Steel Composite Walling System under Compression. Journal of Thin-walled Structures. 49(1): 66–76.

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.

Sengul, O., Azizi, S., Karaosmanoglu, F., Tasdemir, M. A. 2011. Effect of Expended Perlite on the Mechanical Properties and Thermal Conductivity of Lightweight Concrete. Energy and Building Journals. 43(2–3): 671–676.

Harmathty, T. Z., Allen, L. W. 1973. Thermal Properties of Selected Masonry Concrete Units. Journal V70, American Concrete Institute. 8: 132–142.

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Published

2014-08-27

Issue

Vol. 70 No. 1: September 2014

Section

Science and Engineering

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Copyright of articles that appear in Jurnal Teknologi belongs exclusively to Penerbit Universiti Teknologi Malaysia (Penerbit UTM Press). This copyright covers the rights to reproduce the article, including reprints, electronic reproductions, or any other reproductions of similar nature.

How to Cite

Thermal Properties of Oil Palm Shell Lightweight Concrete with Different Mix Designs. (2014). Jurnal Teknologi, 70(1). https://doi.org/10.11113/jt.v70.2507