Evaluation of Strength Properties of Laguncularia racemosa  (White Mangroves) from the  Central and Western Regions of  Ghana for Efficient Use

Francis Kofi Bih; Benjamin Wilberforce Eshun; Eric Donkor Marfo

Full Article - PDF Review History

Published: 2023-01-12

Page: 24-32

Issue: 2023 - Volume 6 [Issue 1]

Evaluation of Strength Properties of Laguncularia racemosa (White Mangroves) from the Central and Western Regions of Ghana for Efficient Use

Full Article - PDF Review History

Published: 2023-01-12

Page: 24-32

Issue: 2023 - Volume 6 [Issue 1]

Francis Kofi Bih

Department of Construction and Wood Technology Education, AAMUSTED, Kumasi, Ghana.

Benjamin Wilberforce Eshun

Department of Furniture, Cape Coast Technical Institute, Cape Coast, Ghana.

Eric Donkor Marfo *

Department of Interior Design and Technology, Takoradi Technical University, Takoradi, Ghana.

*Author to whom correspondence should be addressed.

Abstract

For a better use of wood as an engineering material, knowledge of its strength properties is important. In building projects, strength properties of wood and wood-based components are crucial. The research was to investigate some mechanical properties of white mangrove (Laguncularia racemosa) in two coastal regions of Ghana, Western and Central regions, to optimise their use. The results showed that, the mean modulus of rupture values of trees from the Central region was between 52.82 and 63.21 Nmm^-2 while the mean modulus of rupture values of trees from the Western region was between 51.23 and 56.84 Nmm^-2. The mean modulus of elasticity values of trees from Central region was in the range of 6827.24 and 7711.07 Nmm^-2with that from Western in the range of 5852.73 and 7157.55 Nmm^-2. The compressive strength parallel to the grain of trees from the central region ranged from 27.05 to 30.73 Nmm^-2with that from Western ranged from 24.57 and 28.33 Nmm^-2. The study concluded that, Laguncularia racemosa exhibited low strength properties and is therefore not recommended for structural applications where strength is required.

Keywords: Strength properties, modulus of elasticity, modulus of rupture, compressive strength, white mangrove

How to Cite

Bih, Francis Kofi, Benjamin Wilberforce Eshun, and Eric Donkor Marfo. 2023. “Evaluation of Strength Properties of Laguncularia Racemosa (White Mangroves) from the Central and Western Regions of Ghana for Efficient Use”. Journal of Materials Science Research and Reviews 6 (1):24-32. https://www.journaljmsrr.com/index.php/JMSRR/article/view/223.

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References

Saenger P. Mangrove Ecology, Silviculture and Conservation. Kluwe Academic Publishers, Dordrecht. 2002:11-18.

Available: htpps://dx.org/10.1007/978-94-015-9962-7

Tomlinson PB. The Botany of Mangroves: Cambridge Tropical Biology Series, Cambridge University Press; 1995.

Rabinowitz D. Early growth of mangrove seedlings in Panama, and a hypothesis concerning the relationship of dispersal and zonation. J Biogeogr. 1978;5:113-133.

Ishengoma RC, Gillah PR, Amartey SA, Kitojo DH. Physical, mechanical and natural decay resistance properties of lesser known and lesser utilized Diospyros mespiliformis, Tyrachylobium verrucosum and Newtoniapaucijuga timber species from Tanzania. Holz Roh Werkst. 2004;62:387-389.

Simpson W, TenWolde A. Physical properties and moisture relations of wood. Wood handbook: wood as an engineering material. Madison, WI: USDA Forest Service, Forest Products Laboratory. General technical report FPL. 1999; GTR-113: 3.1 – 3.24

Chowdhury MQ, Rashid AZMM, Newaz MS, Alam M. Effects of height on physical properties of wood of jhau (Casuarina equisetifolia). Australian Forestry. 2007;70(1):33-36.

Available:https://doi.org/10.1080/00049158.2007.10676260

Tsoumis G. Science and Technology of Wood: Structure, Properties and Utilization. Van Nostrand Reinhold New York. 1991;160-174

Green DW, Winandy JE, Kretschmann DE. Mechanical properties of wood. Wood handbook: wood as an engineering material. Madison, WI: USDA Forest Service, Forest Products Laboratory. General technical report FPL. 1999;GTR-113:4.1-4.45

Pereira H, Graca J, Rodrigues JC. Wood chemistry in relation to quality. In: Wood quality and its biological basis (Barnett J, Jeronimidis G eds). John Wiley and Sons. Blackwell, Oxford, UK, 2003;53-86.

Jozsa LA, Middleton GR. A discussion of wood quality attributes and their practical implications. SP-34. Pacific Forestry Centre. Canada-British Columbia Partnership Agreement on Forest Resource Development: FRDA II; 1994.

British Standard Methods of Testing Small Clear Specimens of Lumber, BS 373.. British Standard Institution, London; 1957.

Hoyle RJ. Wood Technology in the Design of Structures, Missoula Montana. Mounting Press Publishing Company; 1978.

Rowell MR. Handbook of Wood Chemistry and Wood Composite. CRC Press. Retrieved from www.crcpress.com. (Accessed: 17/02/14). Saenger P. (2002). Mangrove Ecology, Silviculture and Conservation. Kluwer Academic Publishers, Dordrecth. 2005;11 -18.

Hoadley RB. Understanding wood: A Craftsman’s Guide to Wood Technology. The Taunton Press, Newtown, Connecticut, USA; 2000.

Stöd R, Verkasalo E, Heinonen J. Quality and Bending Properties of Sawn Timber from Commerical Thinnings of Scot pine (Sylvestrish L.). Baltic Forestry. 2016; 22(1):148 – 162.

Zelalem G, Pradeep P, Omprakash S. The Influence of Physical and Mechanical properties on Quality of wood produced from Pinus Patula Tree Grown at Arsi Forest. Advanced Research Journal of Plant and Animal Sciences, Spring Journals: ISN-2360-7947: 2014;2(4): 032-041

Farmer RH. Handbook of Hardwood. Second Edition. 2, 49-50 London, Her Majesty’s Stationary Office; 1972.

Ofori J, Appiah JK. Some drying characteristics of five Ghanaian lesser-known wood species. Ghana Journal of Forestry. 1998;6:19-27.

Kumar S. Genetic parameter estimates for wood stiffness, strength, internal checking, and resin bleeding for radiata pine. Can. J. For. Res. 2004;34(12):2601-2610.

Schneider MH, Sebestian LP, Seepersad JBending strength and stiffness of Caribbean pine from Trinad and Tobago. Wood and Fiber Science. 1991;23(4): 468 – 471.

Barnett JR, Jeronimidis G. (Eds). Wood Quality and its Biological Basis. Blackwell Publishing Ltd. Oxford; 2003.

Bowyer JL, Shmulsky R, Haygreen JG. Forest Products and Wood Science: An Introduction. Ames, Iowa State Press; 2003.

Gnanaharan R, Dhamodaran TK. Mechanical properties of rubberwood from a 35-year-old plantation in central Kerala, India. Journal of Tropical Forest Science. 1992;6(2):136-140.

Yang JL, Evans R. Prediction of MOE of eucalypt wood from microfibril angle and density. Holz als Roh-und Werkstoff. 2003;61:449-452.

Zziwa A, Kaboggoza JRS, Mwakali JA, Banana AY, Kyeyune RK. Physical and mechanical properties of some less utilised tropical timber tree species growing in Uganda. Uganda Journal of Agricultural Sciences. 2006;12 (1):29-37

Upton DAJ, Attah A. Commercial timbers of Ghana – The potential for lesser used species. Forestry Commission of Ghana, Accra. 2003;58

Timber Export Development Board (TEDB). The Tropical Timbers of Ghana. Timber Export Development Board, Takoradi. 1994;5-6:40

Shmulsky R, Jones PD. Forest products and wood science, an introduction (6th ed). West Susses: Willey Blackwell; 2011.

Available: https://dx. doi.org/10.1002/9780470960035

Ayarkwa J. Timber Technology for Researchers, Polytechnics and university students’. 2-7. Kumasi, Classic Graphics Print; 2009.