REFERENCES
Abdel Hakim, A. A., Nassar, M., Emam, A., & Sultan, M. (2011). Preparation and
characterization of rigid polyurethane foam prepared from sugar-cane bagasse
polyol. Materials Chemistry and Physics, 129(1–2), 301–307.
Akil, H. M., Omar, M. F., Mazuki, A. A. M., Safiee, S., Ishak, Z. A. M., & Abu Bakar, A.
(2011). Kenaf fiber reinforced composites: A review. Materials and Design, 32(8–
9), 4107–4121.
Akindoyo, J. O., Beg, M. D. H., Ghazali, S., Islam, M. R., Jeyaratnam, N., & Yuvaraj, A.
R. (2016). Polyurethane types, synthesis and applications-a review. RSC Advances,
6(115), 114453–114482.
Choe, H., Sung, G., & Kim, J. H. (2018). Chemical treatment of wood fibers to enhance
the sound absorption coefficient of flexible polyurethane composite foams.
Composites Science and Technology, 156, 19–27.
Choudhary, O. P., & ka, P. (2017). Scanning Electron Microscope: Advantages and
Disadvantages in Imaging Components. International Journal of Current
Microbiology and Applied Sciences, 6(5), 1877–1882.
Co, E., & Kyoto, E. (2013). Thermal insulation materials Polyurethane (PUR) and
Polyisocyanurate (PIR) foam.
Collet, Å. S. A., & Kallman, M. (2017). Pipe Vibrations Measurement.
36
de Mello, D., Pezzin, S. H., & Amico, S. C. (2009). The effect of post-consumer PET
particles on the performance of flexible polyurethane foams. Polymer Testing, 28(7),
702–708.
Deshmukh, G., Birwal, P., Datir, R., & Patel, S. (2017). Thermal Insulation Materials: A
Tool for Energy Conservation. Journal of Food Processing & Technology, 08(04),
8–11.
Evi et al., 2008. (2008). Synthesis and Structure Properties of Rigid Polyurethane Foam
from Palm Oil Based Polyol. Indonesian Journal of Materials Science, (January),
31–36.
Fariza, a. R., Zuraida, a., & Sopyan, I. (2010). Application of Low Cost Polyurethane (PU)
Foam for Fabricating Porous Tri-Calcium Phosphate (TCP). Journal of Biomimetics,
Biomaterials, and Tissue Engineering, 8(January 2014), 1–7.
Gu, R., & Sain, M. M. (2014). Effects of Wood Fiber and Microclay on the Performance
of Soy Based Effects of Wood Fiber and Microclay on the Performance of Soy Based
Polyurethane Foams, (June).
Harrison, M. R., & Gamboa, R. R. (2004). Pipe insulation, 315–338.
Islam, S., Islam, S., Islam, N., Huque, M., Hasan, M., & Haque, M. (2010).
Physicomechanical properties of chemically treated palm fiber reinforced
polypropylene composites. Journal of Reinforced Plastics and Composites, 29(11),
1734–1742.
Kabir, M. M., Wang, H., Lau, K. T., & Cardona, F. (2012). Chemical treatments on plantbased natural fibre reinforced polymer composites: An overview. Composites Part
B: Engineering, 43(7), 2883–2892.
Kamath, S. S., Sampathkumar, D., & Bennehalli, B. (2017). A review on natural areca
fibre reinforced polymer composite materials. Ciencia e Tecnologia Dos Materiais,
29(3), 106–128.
37
Kirpluks, M., Cabulis, U., Zeltins, V., Stiebra, L., & Avots, A. (2014). Rigid polyurethane
foam thermal insulation protected with mineral intumescent mat. Autex Research
Journal, 14(4), 259–269.
Latinwo, G., Aribike, D., Oyekunle, L., Susu, A., & Kareen, S. (2010). Effects of Calcium
Carbonate of Different Composition and Particle Size Distributions on the
Mechanical Properties of Flexible Polyurethane Foam. Nature and Science, 8(9), 92–
101.
Mat Hassan, N. N., & M.Rus, A. Z. (2014). 1, 1 2 1., 3(62), 197–206.
Mohamed, M., Anandan, S., Huo, Z., Birman, V., Volz, J., & Chandrashekhara, K. (2015).
Manufacturing and characterization of polyurethane based sandwich composite
structures. Composite Structures, 123, 169–179.
Mohomed, K. (2016). Thermogravimetric Analysis (TGA) - Theory and Applications. TA
Instruments
-
Waters
LLC,
235
slides.
Retrieved
from
file:///C:/Users/Soray/Downloads/CA-2016-TGA.pdf
Nayak, S., & Mohanty, J. R. (2018). Study of Mechanical, Thermal, and Rheological
Properties of Areca Fiber-Reinforced Polyvinyl Alcohol Composite Study of
Mechanical, Thermal, and Rheological Properties of Areca. Journal of Natural
Fibers, 00(00), 1–14.
P, P., MS, I., S, S., HP, N., & AMS, C. (2016). Mechanical and Thermal Properties of
Short Arecanut Leaf Sheath Fiber Reinforced Polypropyline Composites: TGA, DSC
and SEM Analysis. Journal of Material Science & Engineering, 5(5).
Padmaraj, N. H., Kini, M. V., Pai, B. R., & Shenoy, B. S. (2013). Development of short
areca fiber reinforced biodegradable composite material. Procedia Engineering, 64,
966–972.
Park, D. Y., Chung, H. J., Park, S. C., Kim, J. W., Yoon, J. H., Lee, J. G., … Cho, H. J.
(2018). Surgical outcomes of overlapping lateral pharyngoplasty with or without
38
coblator tongue base resection for obstructive sleep apnea. European Archives of
Oto-Rhino-Laryngology, 275(5), 1189–1196.
Peng, L. (2016). Sound absorption and insulation functional composites. Advanced High
Strength Natural Fibre Composites in Construction. Elsevier Ltd.
Placet, V. (2010). Characterization of the thermo-mechanical behaviour of Hemp fibres
intended.
Punyamurthy, R. (2015). Areca Fiber Reinforced Epoxy Composites: Effect of Chemical
Treatments on Impact Strength Areca Fiber Reinforced Epoxy Composites: Effect of
Chemical Treatments on Impact Strength, (June).
Sa e Sant’Anna, S., de Souza, D. A., de Araujo, D. M., Carvalho, C. de F., & Yoshida, M.
I. (2008). Physico-chemical Analysis of Flexible Polyurethane Foams Containing
Commercial Calcium Carbonate. Materials Research-Ibero-American Journal of
Materials, 11(4), 433–438.
Sasso, M., Antonelli, M. G., Mancini, E., Radoni, M., & Amodio, D. (2017). Experimental
and numerical characterization of a polymeric Hopkinson bar by DTMA.
International Journal of Impact Engineering, 103, 50–63.
Srinivasa, C. V., Arifulla, A., Goutham, N., Santhosh, T., Jaeethendra, H. J., Ravikumar,
R. B., … Ashish, J. (2011). Static bending and impact behaviour of areca fibers
composites. Materials and Design, 32(4), 2469–2475.
Standard, I. (1998). ISO 10534-2, 1998.
Thakur, V. K., Thakur, M. K., & Gupta, R. (2014). Review: Raw Natural Fiber – Based
Polymer Composites International Journal of Polymer Analysis and Characterization
Review: Raw Natural Fiber – Based Polymer Composites, (March).
Tiuc, A. E., Vermeşan, H., Gabor, T., & Vasile, O. (2016). Improved Sound Absorption
Properties of Polyurethane Foam Mixed with Textile Waste. Energy Procedia,
85(November 2015), 559–565.
39
Verdejo, R., Stämpfli, R., Alvarez-Lainez, M., Mourad, S., Rodriguez-Perez, M. A.,
Brühwiler, P. A., & Shaffer, M. (2009). Enhanced acoustic damping in flexible
polyurethane foams filled with carbon nanotubes. Composites Science and
Technology, 69(10), 1564–1569.
Yusriah, L., Sapuan, S. M., Zainudin, E. S., & Mariatti, M. (2012). Exploring the Potential
of Betel Nut Husk Fiber as Reinforcement in Polymer Composites: Effect of Fiber
Maturity. Procedia Chemistry, 4, 87–94.
Yuvaraj, L., Vijay, G., & Jeyanthi, S. (2016). Study of Sound Absorption Properties on
Rigid Polyurethane Foams using FEA, 9(September).
Zhang, L. (2008). Structure-Property Relationship of Polyurethane Flexible Foam Made
from Natural Oil Polyols, 1–208.