Waste Egg Shell – Cement Paste Composites For Sustainable Construction Applications

  IJETT-book-cover  International Journal of Engineering Trends and Technology (IJETT)          
  
© 2019 by IJETT Journal
Volume-67 Issue-11
Year of Publication : 2019
Authors : Cihan ÖZÇELİK, Hasan Şahan AREL
DOI :  10.14445/22315381/IJETT-V67I11P207

Citation 

MLA Style: Cihan ÖZÇELİK, Hasan Şahan AREL "Waste Egg Shell – Cement Paste Composites For Sustainable Construction Applications" International Journal of Engineering Trends and Technology 67.11 (2019):35-44.

APA Style:Cihan ÖZÇELİK, Hasan Şahan AREL. Waste Egg Shell – Cement Paste Composites For Sustainable Construction Applications International Journal of Engineering Trends and Technology, 67(11),35-44.

Abstract
Utilization of waste materials as construction material is necessary to achieve sustainable construction, and reduce CO2 emissions. This paper examined the effect of egg shell as cement replacement on properties of cement paste composites for sustainable construction. To this end, granulated egg shell (GES), egg shell dust (ESD), and egg shell dust–marble powder (MP) substited composites were produced. Fresh mixtures subjected to flow table test, while hardened composite samples subjected to compressive strength, permeable voids, and porosity tests. The results further show that addition of MP along with ESD is beneficial for performance of cement paste composites.

Reference

[1] Ayd?n, “Novel coal bottom ash waste composites for sustainable construction,” Construction and Building Materials, vol. 124, pp. 582–588, 2016.
[2] R. Feiz, J. Ammenberg, L. Baas, M. Eklund, A. Helgstrand, R. Marshall, “Improving the CO2 performance of cement, part I: utilizing life-cycle assessment and key performance indicators to assess development within the cement industry,” Journal of Cleaner Production, vol. 98, pp. 272– 281, 2015.
[3] H. Mikul?i?, J.J. Klemeš, M. Vujanovi?, K. Urbaniec, N. Dui?, “Reducing greenhouse gasses emissions by fostering the deployment of alternative raw materials and energy sources in the cleaner cement manufacturing process,” Journal of Cleaner Production, vol. 136, pp. 119–132, 2016.
[4] M.M. Hosseini, Y. Shao, J.K. Whalen, “Biocement production from silicon-rich plant residues: perspectives and future potential in Canada,” Biosystems Engineering, vol. 110, pp. 351–362, 2011.
[5] P. Kaewwichit, J. Junsomboon, P. Chakartnarodom,
[6] Tippayasa, T. Srichumpong, P. Thavorniti, C. Leonelli, D. Chaysuwan, “Development of microwave- assisted sintering of Portland cement raw meal,” Journal of Cleaner Production, vol. 142, pp. 1252– 1258, 2017.
[7] Chen, G. Habert. Y. Bouzidi, A. Jullien, A. Ventura,” LCA allocation procedure used as an initative method for waste recycling: an application to mineral additions in concrete, Resources,” Conservation and Recycling, vol. 54, pp. 1231– 1240, 2010.
[8] S. Sinyoung, K. Kunchariyakun, S. Asavapisit,
[9] K.J.D MacKenzie, “Synthesis of belite cement from nanosilica extracted from two rice husk ashes,” Journal of Environmental Management, vol. 190, pp. 53–60, 2017.
[10] L.C. Ying, J.E. Chang, P.H. Shin, M.S. Ko, Y.K. Chang, L.C. Chiang, “Reusing pretreated desulfurization slag to improve clinkerization and clinker grindability for energy conservation in cement manufacture” J. Environ. Managemen, vol. 9, pp. 1892–1897, 2010.
[11] S. Ruan, C. Unluer, “Comparative life cycle assessment of reactive MgO and Portland cement production,” Journal of Cleaner Production, vol. 137, pp.258–273, 2016.
[12] Z. Cao, L. Shen, J. Zhao, L. Liu, S. Zhong, Y. Sun,Y. Yang, Toward a better practice for estimating the CO2 emission factors of cement production: An experience from China, ” Journal of Cleaner Production, vol. 139, pp. 527–539, 2016.
[13] T. Gao, L. Shen, M. Shen, L. Liu, F. Chen, “Analysis of material flow and consumption in cement production process,” Journal of Cleaner Production, vol. 112, pp. 553–565, 2016.
[14] H.?. Arel, “Recyclability of waste marble in concrete production,” Journal of Cleaner Production vol. 131, pp. 179–188, 2016.
[15] S. Supino, O. Malandrino, M. Testa, D. Sica, “Sustainability in the EU cement industry: The Italian and German experiences.” J Clean Prod, vol 112, pp. 430–442, 2016.
[16] K. Kupwade-Patil, C. de Wolf, S. Chin, J. Ochsendorf, A.E. Hajiah, A. Al-Mumin, O. Büyüköztürk, “Impact of Embodied Energy on materials/buildings with partial replacement of ordinary Portland Cement (OPC) by natural Pozzolanic Volcanic Ash”, Journal of Cleaner Production, vol. 177, pp. 547–554, 2018.
[17] Z. Zhang, J.L. Provis, A. Reid, H. Wang, “Geopolymer foam concrete: An emerging material for sustainable construction,” Construction and Building Materials, vol. 56, pp. 113–127, 2014.
[18] Oxford: Oxford University Press “World Commission on Environment and Development. Our Common Future. Chapter 2: Towards sustainable development”; 1987.
[19] Holden, K. Linnerud, “D. Banister, Sustainable development: Our Common Future revisited, Global” Environmental Change, vol. 26, pp. 130–139, 2014.
[20] R. Siddique, G. Singh, M. Singh, “Recycle option for metallurgical by-product (Spent Foundry Sand) in green concrete for sustainable construction,” Journal of Cleaner Production, vol. 172, pp. 1111–1120, 2018.
[21] R. Bucher, P. Diederich, G. Escadeillas, M. Cyr, “Service life of metakaolin-based concrete exposed to carbonation: Comparison with blended cement containing fly ash, blast furnace slag and limestone filler,” Cement and Concrete Research, vol. 99, pp. 18– 29, 2017.
[22] R. Siddique, K. Singh, Knual, M. Singh, V. Corinaldesi, “A. Rajor, Properties of bacterial rice husk ash concrete,” Construction and Building Materials vol. 121, pp. 112–119, 2016.
[23] M. Sivakumar, N. Mahendran, “Strength and Permeability Properties of Concrete Using Fly Ash (Fa), Rise Husk Ash (Rha) and Egg Shell Powder (Esp),” Journal of Theoretical and Applied Information Technology vol. 66, pp. 489–499, 2014.
[24] Turkey Statistical Agency, 2017.
[25] P. Pliya, D. Cree, “Limestone derived eggshell powder as a replacement in Portland cement mortar,” Construction and Building Materials, vol. 95, pp. 1–9, 2015.
[26] A. Yerramala, “Properties of concrete with eggshell powder as cement replacement” The Indian Concrete Journal, pp. 94–102, 2014.
[27] Ö. Petersson, “Limestone Powder as Filler in Self- Compacting Concrete– Frost Resistance, Compressive Strength and Chloride Diffusivity,” First North American Conference on the Design and Use of Self- Consolidating Concrete, pp. 391–396, 2002.
[28] Bonavetti, H. Donza, G. Menendez, O. Cabrera,E.F. Irassar, “Limestone filler cement in low w/c concrete: A rational use of energy,” Cement and Concrete Research, vol. 33, pp. 865–871, 2003.
[29] T. Matschei, B. Lothenbach, F.P. Glasser, “The role of calcium carbonate in cement hydration,” Cement and Concrete Research, vol. 37, pp. 551–558, 2007.
[30] M.E. Ç?nar, F. Kar, “Characterization of composite produced from waste PET and marble dust,” Construction and Building Materials," vol. 163, pp. 734–741, 2018.
[31] O.M. Omar, G.D. Abd Elhameed, M.A. Sherif, H.A. Mohamadien, “Influence of limestone waste as partial replacement material for sand and marble powder in concrete properties,” HBRC Journal, vol. 8, pp. 193–203, 2012.
[32] T. Vuk, V. Tinta, R. Gabrovek, V. Kaui, “The effects of limestone addition, clinker type and fineness on properties of Portland cement,” Cement and Concrete Research, vol. 31, pp. 135–139, 2001.
[33] Arunta? et al., H.Y. Arunta?, M. Gürü, M. Day?, ?. Tekin, “Utilization of waste marble dust as an additive in cement production” Mater. Des., vol. 31, pp. 4039- 4042, 2010.
[34] M. Tennich, A. Kallel, M.B. Ouezdou, “Incorporation of fillers from marble and tile wastes in the composition of self-compacting concretes,” Constr. Build. Mater., vol. 91, pp. 65–70, 2015.
[35] B. Demirel, “The effect of the using waste marble dust as fine sand on the mechanical properties of the concrete,” Int. J. Phys. Sci., vol. 5, pp. 1372–1380, 2010.
[36] M.C. Dhoka, “Green concrete: using industrial waste of marble powder, quarry dust and paper pulp,” Int. J. Eng. Sci. Invent, vol. 2, pp. 67–70, 2013.
[37] H. Hebhoub, H. Aoun, M. Belachia, H. Houari, E. Ghorbel, “Use of waste marble aggregates in concrete,” Constr. Build. Mater., vol. 25, pp. 1167–1171, 2011.
[38] M. Geso?lu, E. Guneyisi, M.E. Kocaba?, V. Bayram, K. Mermerda?, “Fresh and hardened characteristics of self compacting concretes made with combined use of marble powder, limestone filler, and fly ash,” Construction and Building Materials, vol. 37, pp. 160–170, 2012.
[39] G.B. Bandhavya, K. Sandeep, G.B. Bindhushree, “An Exper?mental Study on Partial Replacement of Cement with Egg Shell Powder In Concrete”, International Research Journal of Engineering and Technology (IRJET), vol.4, pp. 2318–2323, 2017.”
[40] P Kumar, V. Sarathy, J. Ravindraraj, “Experimental Study on Partial Replacement of Cement with Egg Shell Powder”, International Journal of Innovations in Engineering and Technology (IJIET), vol. 5, pp. 334–341, 2015.
[41] S.M. Hama, “Improving mechanical properties of lightweight Porcelanite aggregate concrete using different waste material,” International Journal of Sustainable Built Environment, vol. 6, pp. 81–90, 2017.
[42] N.Parthasarathi, M. Prakash, K.S. Satyanarayanan, “Exper?mental Study on Partial Replacement of Cement with Egg Shell Powder And S?l?ca Fume,” Rasayan J. Chem., vol. 10 pp. 442–449, 2017.
[43] A. Rana, P. Kalla, L.J. Csetenyi, “Sustainable use of marble slurry in concrete,” Journal of Cleaner Production, vol. 94, pp. 304–311, 2015.
[44] P.A. Shirule, A. Rahman, R.D. Gupta, “Partial replacement of cement with marble dust powder,” Int. J. Adv. Eng. Res. Stud., vol. 1, pp. 175–177, 2012.
[45] ASTM C150 / C150M-17, Standard Specification for Portland Cement, ASTM International, West Conshohocken, PA, 2017, www.astm.org
[46] ASTM C31 / C31M-17, Standard Practice for Making and Curing Concrete Test Specimens in the Field, ASTM International, West Conshohocken, PA, 2017, www.astm.org.
[47] H. Binici, O. Aksogan, A.H. Sevinç, E. Cinpolat, “Mechanical and radioactivity shielding performances of mortars made with cement, sand and egg shells,” Construction and Building Materials, vol. 93, pp. 1145–1150, 2015.
[48] ASTM C109 / C109M-16a, Standard Test Method for Compressive Strength of Hydraulic Cement Mortars (Using 2- in. or [50-mm] Cube Specimens), ASTM International, West Conshohocken, PA, 2016, www.astm.org
[49] ASTM C230 / C230M-14, Standard Specification for Flow Table for Use in Tests of Hydraulic Cement, ASTM International, West Conshohocken, PA, 2014, www.astm.org.
[50] W. Xu, Y.T. Lo, D. Ouyang, S.A. Memon, F. Xing,W. Wang, X. Yuan,” Effect of rice husk ash fineness on porosity and hydration reaction of blended cement paste,” Construction and Building Materials, vol. 89, pp. 90–101, 2015.
[51] R. Rodrigues, J. de Brito, M. Sardinha, “Mechanical properties of structural concrete containing very fine aggregates from marble cutting sludge,” Construction and Building Materials, vol. 77, pp. 349–356, 2015.
[52] A.C.A. Muller, K.L. Scrivener, J. Skibsted, A.M. Gajewicz, P.J. McDonald, “Influence of silica fume on the microstructure of cement pastes: New insights from 1H NMR relaxometry,” Cement and Concrete Research, vol. 74, pp. 116–125, 2015.

Keywords
egg shell dust, graulated egg shel, marble powder, cement paste composites, compressive strength