Sustainable Insulation Materials for Green Strategy in Construction
Lutfu Sagbansua, Figen Balo "Sustainable Insulation Materials for Green Strategy in Construction". International Journal of Computer Trends and Technology (IJCTT) V42(2):66-71, December 2016. ISSN:2231-2803. www.ijcttjournal.org. Published by Seventh Sense Research Group.
Abstract -
In the twentyfirst century, there has been remarkable achievements in green material technology by the development of building insulation materials. Using the plant-based materials, waste materials are not only a potential response to the lack of fossil sources in certain regions but also a way of contributing to the environmental protection. This study was performed to investigate whether the technological wastes manufactured by thermal power station and MCO as renewable material can be used in building insulation material production. The study is significant with regard to the environmental requirement of using wastes that would be dangerous otherwise.
References
1. Akak?n, T., 2001. Betonun Mühendislik Özellikleri, pp. 32-40. Akman, M.S. and Ta?demir, M.A., 1977. Perlite concrete as a structural material Ankara, Turkey, 1st National Perlite Congres.
2. ASHRAE, 1990.
3. Ayberk, M., 1995. The use of perlite as a construction material and its impact on construction cost. Industrial Raw Materials Symposium. Izmir. pp. 203-206.
4. Balo, F., 2008-June. Us?ng Plant O?ls in Obta?n?ng Of Compos?te Mater?als, PhD. Thesis, FÜ Fen Bilimleri Enstitüsü. Elaz??, Turkey.
5. Balo, F., 2011. Castor o?l-based bu?ld?ng mater?als re?nforced w?th fly ash, clay, expanded perl?te and pum?ce powder. Ceramics Silikaty. 55(3), pp. 280- 293.
6. Balo, F., April 2015. Characterization of green building materials manufactured from canola oil and natural zeolite. Journal of material cycles and waste management. 17, pp. 336–349.
7. Balo, F., Biçer Y., Yucel, H.L., 2010-3. The Eng?neer?ng Propert?es of Ol?ve O?l-Based Mater?als. Journal of the Ceramic Society of Japan. 118, No. 1380. November, 118(8), pp. 1- 8.
8. Balo, F., January 2015. Feasibility study of ?green? insulation materials including tall oil: environmental, MCOnomical and thermal properties. Energy and Buildings. 86, pp. 161-175.
9. Balo, F., Yucel, H.L., 2007. Availability of Plant Oils in Biocomposite Materials, I. Ulusal ya?l? tohumlu bitkiler ve biodizel sempozyumu, Samsun, Turkey. pp. 43-52.
10. Balo, F., Yucel, H.L., 2008-October. Using plant sources on obtaining of biocomposite material, IV. Ulusal biyomekanik kongresi, Erzurum, Turkey. 340- 351.
11. Balo, F., Yucel, H.L., Ucar, A., 2010. Physical and mechanical properties of materials prepared using class C fly ash and soybean oil. Journal of Porous Material. 17(5), pp. 553- 564.
12. Balo, F., Yucel, H.L., Ucar, A., 2010-1. Development of the insulation materials from coal fly ash, perlite, clay and linseed oil. Ceramics Silikaty. 54(2), pp. 182-191.
13. Balo, F., Yucel, H.L., Ucar, A., 2010-2. Determ?nat?on of the thermal and mechan?cal propert?es for mater?als conta?n?ng palm o?l, clay and fly ash. International Journal of Sustainable Engineering. 31, pp. 47-57.
14. Balo, F., Yücel, H.L., September 2013. Assessment of thermal performance of green building materials manufactured with plant oils, International Journal of Material Science (IJMSCI) 3(3). pp. 118-129.
15. Bist, S., Tao, B.Y., Mohtar, S.A., 2007. Method for Preparation, Use and Separation of Fatty Acid Esters. US Patent 2007-0251141.
16. Blanco, F. and Garcia, P. and Mateos, P. and Ayala, J., 2000. Characteristics and properties of lightweight concrete manufactured with cenospheres. Cement and Concrete Research. 30, pp. 1715–1722.
17. Bouguerra A, Laurent JP, Goual MS, Queneudec M. The measurement of the thermal conductivity of solid aggregates using the transient plane source technique. J Appl Phys 1997; 30:2900–4.
18. Can, E., Kusefoglu, S., Wool, R.P., 2001. Rigid thermosetting liquid molding resins from renewable resources: 1 copolymers of soyoil monoglycerides with maleic anhydride. Journal of Applied Polymer Science. 81, pp. 133-143.
19. Cébron, A., Beguiristain, T., Bongoua-Devisme, J., Denonfoux, J., Faure, P., Lorgeoux, C., Ouvrard, S., Parisot, N., Peyret, P., Leyval, C., 2015. Impact of clay mineral, wood sawdust or root organic matter on the bacterial and fungal community structures in two aged PAH contaminated soils. Environ. Sci. Pollut. R. pp. 1- 15.
20. Ceylan, A., Ebeo?lugil, F., 2002. The Investigation of the Use of Clay and Expanded Perlite in the Production of Lightweight and Heat Insulation Enhanced Construction Bricks. Dumlupinar University Science and Technology Journal. The 10th anniversary Special Issue, pp. 33-38.
21. Chandra, S., Berntsson, L., 2002. Lightweight aggregate concrete-science, technology, and applications. NY: William Andrew Publishing/ Noyes.
22. Çavu?o?lu, I., 2008. Potential use of fly ash as a backfill material a case study Çay?rhan, Madencilik. 473, pp. 3 - 13.
23. Çelik, A.G., 2015. Investigation on characteristic properties of potassium borate and sodium borate blended perlite bricks. Journal of Cleaner Production. 102, pp. 88-95.
24. Çobanli, M.R., 1993. Production of High Heat Resistant Lightweight Construction Materials (MSc. dissertation). Osmangazi University, Graduate School of Science, Turkey.
25. Daire, W.R. and A. Downs, 1980. The hot wire test—a critical review and comparision with B 1902 panel test. Transections of British Ceramic Society. 79, pp.44-49.
26. Demirboga, R., Örüng, I., Gul, R., 2001. Effects of expanded perlite aggregate and mineral admixtures on the compressive strength of low-density concretes. Cem Concr Res. 31(11), pp. 1627–1632.
27. Demirbo?a R., 2003. Influence of mineral admixtures on thermal conductivity and compressive strength of mortar. Energy and Buildings. 35, pp. 189–92.
28. Denko, S., 1981. Shotherm Operation Manual No: 125- 2.K.K. Instrument Products Department. 13-9 Shiba Daimon. Tokyo. Japan. 105.
29. Eckey, E.W., 1954. Plant fats and oils, the ACS monograph series, New York: Reinhold Publishing Co. 30. Ellerbrock, H.G and Mathiak, H., 1994. Comminution technology and energy management. ZKG, 479, pp. 524–533.
31. Guner, F.S., Yagc?, Y., Erciyes, A.T., 2006. Polymers from triglyceride oils. Prog. Polym.Sci. 31, pp. 633– 670.
32. Hasegeva, N., Kawasumi, M., Kato, M., Usuki, A., Okada, A., 2006. Preparation and mechanical properties of polypropylene-clay hybrids using a maleic anhydride-modified polypropylene oligomer. Journal of applied polymer science. 67(1), pp. 87-92.
33. Horszczaruk, E., 2005. Abrasion resistance of highstrength concrete in hydraulic structures. Wear. 2591, pp. 62–69.
34. Hosein, A., Hoseini, G., Dahlan, N.D., Berardi U., Hoseini, A.G., Makaremi, N., Hoseini, M.G., 2013. Sustainable energy performances of gren buildings: A review of current theories, implementations and challenges. Renewable and Sustainable Energy Reviews. 25, pp. 1–17.
35. Ilic, M. Cheeseman, C. and Sollars, C. and Knight, J., 2003. Mineralogy and microstructure of sintered lignite coal fly ash. Fuel. 82, pp. 331–336.
36. Imai, N., Kageyama, H., Uyama, H., 2007. Highperformance nanofiber-reinforeced composite from all bio-based materials. Chem Lett. 36, pp. 698-699.
37. Kaplan, D.L., 1998. Biopolymers from renewable resources, New York: Springer.
38. Li, F., Hasjim, J., Larock, R.C., 2003. Synthesis, structure, and thermophysical and mechanical properties of new polymers prepared by the cationic copolymerization of corn oil, styrene, and divinylbenzene. J. Appl. Polym. Sci. 90, pp. 1830–1838.
39. Li, J., Cao, W., Chen G., 2015. The heat transfer coefficient of new construction e Brick masonry with fly ash blocks. Energy. 86, pp. 240-246.
40. Li, Z., Erhan, Z.S., Xu, J., 2005. Preparation, characterization and mechanical properties of epoxidized soybean oil/clay nanocomposites. Polymer. 46, pp. 10119–10127.
41. Little M.R., Adell V., Boccaccini, A.R., Cheeseman C.R., 2008. Production of novel ceramic materials from coal fly ash and metal finishing wastes. Resources, Conservation and Recycling. 52, pp. 1329–1335.
42. London, A.G., 1979. The International Journal of Lightweight Concrete. 12, pp. 71–85.
43. Lu-shu, K. and Man-qing, S. and Xing-Sheng S. and Yun-xiu, L., 1980. Research on several physicomechanical properties of lightweight aggregate concrete. The International Journal of Lightweight Concrete. 24, pp. 185–191.
44. O’Brien, R.D., 2004. Fats and oils—formulating and processing for applications. 2nd ed. Boca Raton FL, USA: CRC Press.
45. Onaran, K., 1993. Materials Science Malzeme Bilimi, Istanbul, Turkey, 174.
46. Petrovic, Z.S., Guo, A., Zhang, W., 2000. Structure and properties of polyurethanes based on halogenated and nonhalogenated soy-polyols. J Polym Sci. Part A: Polym Chem, 38, pp. 4062–4069.
47. Ping H, Zhang X., Peng X., Wu J., Jianga X., 2016. Effect of fly ash composition on the retention of mercury in coal-combustion flue gas. Fuel Processing Technology. 142, pp. 6–12.
48. Queralt, I. and Querol, X. and López-Soler A. and Plana, F., 1997. Use of coal fly ash for ceramics: a case study for a large Spanish power station. Fuel. 76, pp. 787–791.
49. Richard, C., Larock, R.C., Paul, W., 2007. Gallagher Development of Soy/Corn Oil Plastic Composites. IMBA Project 2006- 2. Project period: 7/1/2005-6/30.
50. Salunkhe, D.K, Chavan, J.K., Adsule R.N., Kadam S.S., 1991. World oilseeds: Chemistry, technology and utilization. New York: Van Nostrand Reinhold.
51. Sengupta K., Das R., G. Banerjee, 1992. Measurement of thermal conductivity of refractory bricks by the nonsteady state hot-wire method using differential platinum resistanse thermometry. Journal of Testing and Evaluation. JTEVA. 29(6), pp. 455–459.
52. Siddique, R., 2003. Effect of fine aggregate replacement with class F fly ash on the abrasion resistance of concrete. Cement and Concrete Research. 33(11), pp. 1877–1881.
53. Siddique, R., 2010. Utilization of coal combustion byproducts in sustainable construction materials. Resources, Conservation and Recycling. 54, pp. 1060– 1066.
54. Teffera, F., Forrester, M. J., Cochran, E.W., 2016. Plant Oil-Based Polyether. Bio-Based Plant Oil polymers and Composites. pp. 87-98.
55. Topcu, I.B., Is?kdag, B., 2008. Effect of expanded perlite aggregate on the properties of lightweight concrete. J. Mater. Process. Technol. 204, pp. 34-38.
56. Topcuo?lu, I.B., Is?kdag, B., 2007. Manufacture of high heat conductivity resistant clay bricks containing perlite, Building and Environment 42, pp. 3540–3546.
57. TS 699, 2001. Tabii yapi ta?lari muayene ve deney metotlar?, (Eight five years development program on use of industrial materials such as pumice, perlite, vermiculite phosphogypsum and expanding clays) Turkish State Planning Organization, Ankara.
58. TS EN 771-3, 2005 (The standart of the brick made of using natural or artifical light or dense aggregates for walls.) Turkish State Planning Organization, Ankara. 59. TSPO, 2001. Turkey.
60. Tsujimoto, T., Imai, N., Kageyama, H., Uyama, H., Funaoka, M., 2008. Network polymers from epoxidized soybean oil and bio-based phenolic polymers. J Net Polym Jpn. 29, pp. 192-197.
61. Tsujimoto, T., Uyama, H., Kobayashi S., 2010. Synthesis of high-performance green nanocomposites from renewable natural oils. Polymer Degradation and Stability. 95, pp. 1399-1405.
62. Turkish Earthquake Code (TEC): Specification for structures to be built in disaster areas, Government of Republic of Turkey, Ministry of Public Works and Settlement, Ankara, 2007.
63. Uysal, H. and Demirbo?a R. and ?ahin R. and Gul, R., 2004. The effects of different cement dosages, slumps, and pumice aggregate ratios on the thermal conductivity and density of concrete. Cement Concrete Research. 34, pp. 845–848.
64. Wang, C., and Erhan, S., 1999. J Am Oil Chem Soc., 76, pp. 1211–1216.
65. Wang, X.Y., Park, K.B., Analysis of compressive strength development of concrete containing high volume fly ash, Construction and Building Materials 98 (2015), pp. 810–819.
66. Willshee, J.C., 1980. Comparision of thermal conductivity methods. Proceedings of British Ceramic Society. 29, pp. 153-160.
67. Yuksel, Ö. and Bilir, T., 2006. Use of granulated blastfurnace slag in concrete as fine aggregate. ACI Materials Journal. 1033, pp. 203–208.
Keywords
Modified corn oil, fly ash, thermomechanical characteristics, insulation material, thermal conductivity, green building.