Araştırma Makalesi
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Yıl 2018, Sayı: 4, 246 - 255, 04.12.2018

Öz

Kaynakça

  • References and citations should be prepared in the latest APA (http://owl.english.purdue.edu/owl/resource/560/02/) format. References have to be cited in article text. See the references examples below.
  • ASTM Standard C634, 2013, “Standard Terminology Relating to Building and Environmental Acoustics,” ASTM International, West Conshohocken, PA, 2013, https://www.astm.org/Standards/C634.htm ASTM Standard C423, 2017, “Standard Test Method for Sound Absorption and Sound Absorption Coefficients by the Reverberation Room Method,” ASTM International, West Conshohocken, PA, 2017, https://www.astm.org/Standards/C423.htm Bentur, A. and Ackers, S. A. (1989). The microstructure and ageing of cellulose fibre reinforced cement composites cured in normal environment. The International Journal of Cement Composites and Lightweight Concrete 11(2), 99-110. Chen, T.Y. and Hwang, S.R. (1988). Effect of wood species on the properties of cement-bonded wood particleboard. in Adhesive Technology and bonded tropical Wood Products, ed C.Y. Hse, S.J. Branham, and C. Chow, Taiwan Forestry Research Institute (TFRI) Extension Series No. 96, pp554-564. Dinwoodie, J.M. and Paxton, B.H. (1989). A technical assessment of cement-wood particleboard, in Proceedings 1st Inorganic Bonded Fiber Composites Symposium, Ed A.A. Moslemi, Forest Products Research Society 1989. pp 115-124. Dinwoodie, J.M. and Paxton, B.H. 1991. The long term performance of cement bonded wood particleboard, in Proceedings 2nd Inorganic Bonded Fiber Composites Symposium, Ed A.A. Moslemi, Forest Products Research Society 1991. pp 45-54. Goodell, B., Daniel, G., Liu, J., Mott, L. and Frank, R. (1997). Decay resistance and microscopic analysis of wood-cement composites. Forest Products Journal 47(11/12), 75-80. INDOT, Indinana Department of Transportaion, 2018, “Noise Barriers”, INDOT Office of Public Involvement, IN 46204, pdf report, publicinvolvement@indot.in.gov. Ledhem, A., Dheilly R.M., Benmalek, M.L. and Queneudec, M. (2000). Properties of wood-based composites formulated with aggregate industry waste. Construction and Building Materials 14, 341-350. Oyagade, A.O., Badejo, S.O. and Omole, O.A. (1995). A preliminary evaluation of the flexural properties of wood veneer laminated cement-bonded particleboard from tropical hardwood species. Journal of the Timber Development Association of India 41(3), 25-29. Ramirez-Coretti, A., Eckelman, C.A. and Wolfe, R.W. (1998). Inorganic-bonded composite wood panel systems for low cost housing: A Central American perspective. Forest Products Journal 48(4), 62-68. Semple, K.E. and Evans P.D. (2004). Wood-cement composites – Suitability of Western Australian mallee eucalypt, blue gum and melaleucas. A report for the RIRDC / Land and Water Australia / FWPRDC / MDBC. RIRDC Publication No 04 / 101. Sound Figter Systems, 2018, A breakdown of the science behind absorptive and reflective materialshttps://www.soundfighter.com/our-technology/ URL 1. https://svetlanaroit.files.wordpress.com/2009/11/visual_values2.pdf . Access Date: 27/09/2018. Wolfe, R.W. and Gjinolli, A. (1997). Cement-bonded wood composites as an engineering material, in The Use of Recycled Wood and Paper in Building Applications. USDA Forest Service and Products Society Proceedings No. 7286, pp 84-91. Wolfe, R.W. and Gjinolli, A. (1999). Durability and strength of cement-bonded wood particle composites made from construction waste. Forest Products Journal 49(2), 24-31. Van Elten, G.J. (2000). Production, properties and world wide application of various wood-cement products, in Proceedings 34th International Particleboard and Composite Materials Symposium, eds M.P. Wolcott, R.J. Tichy and D.A. Bender, Washington State University, pp. 169-174.

Effects of using Cement-Bonded Particle Boards with a Composite Component in Terms of Acoustic Performance in Outdoor Noise Barriers

Yıl 2018, Sayı: 4, 246 - 255, 04.12.2018

Öz

Wood-cement
composites are widely utilized in many countries for both interior and exterior
applications because of their strength properties for building materials (e.g.,
siding, roofing, cladding, fencing and sub-flooring) and for acoustic
properties such as in highway sound barriers. These composites have unique
advantages over other conventional materials. Generally, these products combine
the good qualities of cement (relatively high resistance to water, fire fungus,
and termite infestation coupled with good sound insulation) with those of wood
(high strength to weight ratio and workability).
While
reflective products like concrete have been the traditional material for
outdoor noise barrier walls & enclosures, the advanced sound-absorptive
materials found in Cement-bonded particle board products present a much more
effective abatement option. Products like concrete or brick simply bounce sound
waves off their surface in different directions. Cement-bonded particle board
products actually absorb or completely eliminate the sound waves that hit them,
significantly reducing overall noise. In this paper, acoustic performance of
Cement-Bonded Particle Boards for applications will be discusses in different
construction models.
In this paper, sound transmission loss performance of
Cement-Bonded Particle Board panels for especially noise barrier applications will
be discusses in different construction models.
In this research, the
general form of the composite sound barrier panel is a sandwich panel type,
there is one board at the front and one at the back and in between there is an
insulation layer. Thickness of the cement-bonded particle boards and insulation
layer were chosen according to model design.
The analysis results show that the
material derivative, density and layer thickness of the insulation layer to be
preferred in the sound barrier composite panel application are among the main
factors directly affecting the Sound Reduction Index (Rw) performance of the
model design.

Kaynakça

  • References and citations should be prepared in the latest APA (http://owl.english.purdue.edu/owl/resource/560/02/) format. References have to be cited in article text. See the references examples below.
  • ASTM Standard C634, 2013, “Standard Terminology Relating to Building and Environmental Acoustics,” ASTM International, West Conshohocken, PA, 2013, https://www.astm.org/Standards/C634.htm ASTM Standard C423, 2017, “Standard Test Method for Sound Absorption and Sound Absorption Coefficients by the Reverberation Room Method,” ASTM International, West Conshohocken, PA, 2017, https://www.astm.org/Standards/C423.htm Bentur, A. and Ackers, S. A. (1989). The microstructure and ageing of cellulose fibre reinforced cement composites cured in normal environment. The International Journal of Cement Composites and Lightweight Concrete 11(2), 99-110. Chen, T.Y. and Hwang, S.R. (1988). Effect of wood species on the properties of cement-bonded wood particleboard. in Adhesive Technology and bonded tropical Wood Products, ed C.Y. Hse, S.J. Branham, and C. Chow, Taiwan Forestry Research Institute (TFRI) Extension Series No. 96, pp554-564. Dinwoodie, J.M. and Paxton, B.H. (1989). A technical assessment of cement-wood particleboard, in Proceedings 1st Inorganic Bonded Fiber Composites Symposium, Ed A.A. Moslemi, Forest Products Research Society 1989. pp 115-124. Dinwoodie, J.M. and Paxton, B.H. 1991. The long term performance of cement bonded wood particleboard, in Proceedings 2nd Inorganic Bonded Fiber Composites Symposium, Ed A.A. Moslemi, Forest Products Research Society 1991. pp 45-54. Goodell, B., Daniel, G., Liu, J., Mott, L. and Frank, R. (1997). Decay resistance and microscopic analysis of wood-cement composites. Forest Products Journal 47(11/12), 75-80. INDOT, Indinana Department of Transportaion, 2018, “Noise Barriers”, INDOT Office of Public Involvement, IN 46204, pdf report, publicinvolvement@indot.in.gov. Ledhem, A., Dheilly R.M., Benmalek, M.L. and Queneudec, M. (2000). Properties of wood-based composites formulated with aggregate industry waste. Construction and Building Materials 14, 341-350. Oyagade, A.O., Badejo, S.O. and Omole, O.A. (1995). A preliminary evaluation of the flexural properties of wood veneer laminated cement-bonded particleboard from tropical hardwood species. Journal of the Timber Development Association of India 41(3), 25-29. Ramirez-Coretti, A., Eckelman, C.A. and Wolfe, R.W. (1998). Inorganic-bonded composite wood panel systems for low cost housing: A Central American perspective. Forest Products Journal 48(4), 62-68. Semple, K.E. and Evans P.D. (2004). Wood-cement composites – Suitability of Western Australian mallee eucalypt, blue gum and melaleucas. A report for the RIRDC / Land and Water Australia / FWPRDC / MDBC. RIRDC Publication No 04 / 101. Sound Figter Systems, 2018, A breakdown of the science behind absorptive and reflective materialshttps://www.soundfighter.com/our-technology/ URL 1. https://svetlanaroit.files.wordpress.com/2009/11/visual_values2.pdf . Access Date: 27/09/2018. Wolfe, R.W. and Gjinolli, A. (1997). Cement-bonded wood composites as an engineering material, in The Use of Recycled Wood and Paper in Building Applications. USDA Forest Service and Products Society Proceedings No. 7286, pp 84-91. Wolfe, R.W. and Gjinolli, A. (1999). Durability and strength of cement-bonded wood particle composites made from construction waste. Forest Products Journal 49(2), 24-31. Van Elten, G.J. (2000). Production, properties and world wide application of various wood-cement products, in Proceedings 34th International Particleboard and Composite Materials Symposium, eds M.P. Wolcott, R.J. Tichy and D.A. Bender, Washington State University, pp. 169-174.
Toplam 2 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Mühendislik
Bölüm Makaleler
Yazarlar

Lutfullah Gunduz

Sevket Onur Kalkan

A. Munir Isker

Yayımlanma Tarihi 4 Aralık 2018
Yayımlandığı Sayı Yıl 2018Sayı: 4

Kaynak Göster

APA Gunduz, L., Kalkan, S. O., & Isker, A. M. (2018). Effects of using Cement-Bonded Particle Boards with a Composite Component in Terms of Acoustic Performance in Outdoor Noise Barriers. The Eurasia Proceedings of Science Technology Engineering and Mathematics(4), 246-255.