References

PROPORTIONING OF CRUSHED BRICK CONCRETE REINFORCED BY PALM FIBER


[1] ACI 211.2-92, American Concrete Institute, Farmington Hills, MI,(1994), Standard practice for selecting proportions for structural lightweight concrete, ACI Manual of Concrete Practice, Part 1: Materials and General Properties of Concrete, 1994.
http://www.concrete.org

[2] ASTM C29, C94, C127, C128, C138, C143, C173, C330, and C567, Annual book of ASTM standard, Volume 04.02, ASTM International, West Conshohocken, PA.
www.astm.org

[3] American Society of Testing Materials, Internal Curing Using Expanded Shale, Clay and Slate Lightweight Aggregate, Chapter 46-Lightweight Concrete and Aggregate, West Conshohocken, PA, 2006.

[4] C. Asasutjarit, J. J. Hirunlabh, J. Khedari, S. Charoenvai, B. Zeghmati and U. C. Shin, Development of coconut coir-based lightweight cement board, Construction and Building Materials 21 (2007), 277-288.

[5] M. A. Aziz, P. Paramasivam and S. L. Lee, Prospects for natural fiber reinforced concrete in construction, The International Journal of Cement Composite and Lightweight Concrete 2 (1981), 123-132.

[6] K. Bilba, M. A. Arsene and A. Ouensanga, Sugarcane bagasse fiber reinforced cement composites, Part I, Influence of the botanical components of bagasse on the setting of bagasse, Cement Concrete Compos. 25 (2003), 91-96.

[7] BS 1881, methods for determination of density of hardened concrete, British Standard, Part 114 (1983).

[8] BS 1881, methods for determination of compressive strength of concrete cubes, British Standard, Part 116 (1983).

[9] BS 1881, methods for determination of flexural strength, British Standard, Part 118 (1983).

[10] L. H. Do and N. T. Lien, Natural fiber concrete products, J. Ferrocement 25(25) (1995), 17-24.

[11] T. A. Holm and A. J. Valsangkar, Lightweight Soil Mechanics: Properties and Applications, Expanded Shale, Clay and Slate Institute, USA, 2001.
www.escsi.org

[12] K. M. A. Hossain, Development of volcanic pumice based lightweight concrete, Magazine of Concrete Research 56(2) (2004), 99-109.

[13] K. M. A. Hossain, Blended cement and lightweight concrete using scoria: mix design, strength, durability and heat insulation characteristics, International Journal of Physical Sciences (IJPS) 1(1) (2006), 5-16.

[14] O. Kayali, M. N. Haque and B. Zhu, Drying shrinkage of fiber reinforced lightweight aggregate concrete containing fly ash, Cement & Concrete Research 29 (1999), 1835-1840.

[15] O. Kayali, M. N. Haque and B. Zhu, Some characteristics of high strength fiber reinforced lightweight aggregate concrete, Cement & Concrete Composites 25 (2003), 207-213.

[16] J. Khedari, S. Charoenvai and J. Hirunlabh, New insulating particleboards from durian peel and coconut coir, Building & Environment 38 (2003), 245-249.

[17] Y. Mohammadi, S. P. Singh and S. K. Kaushik, Properties of steel fibrous concrete containing mixed fibers in fresh and hardened state, Construction & Building Materials 22 (2008), 956-965.

[18] NAMCA, Concrete in Practice, CIP36-Structural Lightweight Concrete.
www.nrmca.org/aboutconcrete/cips/36p.pdf

[19] A. M. Neville, Properties of Concrete, Fourth and Final Edition, 1995.

[20] K. Semple and D. Evans, Adverse effects of heartwood on the mechanical properties of wood-wool cement boards manufactured from radiate pinewood, Wood Fiber Sci. 32 (1999), 37-43.

[21] E. D. Thanon and M. Ramli, Study the effect of using palm fiber on the properties of high strength flowable mortar, CI Premier: 34th OWICs papers, Singapore 16-18 August (2009), 93-101.

[22] W. Thielemans and R. P. Wool, Butyrated kraft lignin as compatibilizing agent for natural fiber reinforced thermoset composites, Composites Part A: Applied Science and Manufacturing 35 (2004), 327-338.

[23] R. F. Toledo, K. Ghavami, G. L. England and K. Scrivener, Development of vegetable fiber-mortar composites of improved durability, Cement & Concrete Research 25(2) (2003), 169-279.