Open Access
Issue
MATEC Web of Conferences
Volume 15, 2014
Building Surveying, Facilities Management and Engineering Conference (BSFMEC 2014)
Article Number 01020
Number of page(s) 7
DOI https://doi.org/10.1051/matecconf/20141501020
Published online 19 August 2014
  1. Strokova, V.V., A.V. Cherevatova, 2013. Prospects of Application of Zero-Cement Binders of a Nonhydration Hardening Type, World Applied Sciences Journal 25 (1): 119–123
  2. 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 [CrossRef]
  3. Othuman Mydin, M.A., 2013. Modeling of Transient Heat Transfer in Foamed Concrete Slab. Journal of Engineering Science and Technology, 8 (3): 331–349
  4. Herki, B.A., J.M. Khatib, E.M. Negim, 2013. Lightweight Concrete Made from Waste Polystyrene and Fly Ash. World Applied Sciences Journal, 21 (9): 1356–1360
  5. 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 [CrossRef]
  6. Aldridge, D., T. Ansell, 2001. Foamed Concrete: Production and Equipment Design, Properties, Applications and Potential. In: Proceedings of one day seminar on foamed concrete: Properties, applications and latest technological developments, Loughborough University
  7. 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 [CrossRef]
  8. Khatib, J.M., S. Shariff, E.M. Negim, 2012. Effect of Incorporating Foamed Glass on the Flexural Behaviour of Reinforced Concrete Beams, World Applied Sciences Journal 19 (1): 47–51
  9. Norgaard, J., M.A. Othuman Mydin, 2013. Drywall Thermal Properties Exposed to High Temperatures and Fire Condition. Jurnal Teknologi, 62 (1): 63–68
  10. Othuman Mydin, M.A., 2013. An Experimental Investigation on Thermal Conductivity of Lightweight Foamcrete for Thermal Insulation. Jurnal Teknologi, 63 (1): 43–49 [CrossRef]
  11. Awang, H., M.A. Othuman Mydin, A.F. Roslan, 2012. Effects of Fibre on Drying Shrinkage, Compressive and Flextural Strength of Lightweight Foamed Concrete. Advanced Materials Research, Trans Tech Publications, Switzerland, 587: 144–149
  12. 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 [CrossRef]
  13. 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
  14. 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 [CrossRef]
  15. Herki, B.A., J.M. Khatib, E.M. Negim, 2013. Lightweight Concrete Made from Waste Polystyrene and Fly Ash. World Applied Sciences Journal, 21 (9): 1356–1360
  16. 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 [CrossRef]
  17. Othuman Mydin, M.A., 2011. Thin-walled steel enclosed lightweight foamcrete: A novel approach to fabricate sandwich composite. Australian Journal of Basic and Applied Sciences, 5 (12): 1727–1733

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