Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2019, Cilt: 9 Sayı: 2, 241 - 252, 30.12.2019
https://doi.org/10.36222/ejt.648038

Öz

Kaynakça

  • [1] Serna, A., del Rio, M., Palomo, J. G., Gonzalez, M., (2012). Improvement of gypsum plaster strain capacity by the addition of rubber particles from recycled tyres, Construction and Building Materials, 35, 633-641.
  • [2] Biçer, A., Kar, F., (2017). Thermal and mechanical properties of gypsum plaster mixed with expanded polystyrene and tragacanth, Thermal Science and Engineering Progress, 1, 59-65.
  • [3] Gencel, O., del Coz Diaz, J. J., Sütçü, M., Köksal, F., Alvarez Rabanal, F. P., Martinez-Barrera, B., Brostow, W., (2014). Properties of gypsum composites containing vermiculite and polypropylene fibers: Numerical and experimental results, Energy and Buildings, 70, 135-144.
  • [4] Barrera-Barbero, M. M., Medina Flores, N., (2018). The effect of polypropylene fibers on graphite-natural hydraulic lime pastes, Construction and Building Materials, 184, 591-601.
  • [5] Kamnikas, R., Mituzas, J., Kamnikas, A., (2006). The effect of pozzolana on the properties of the finest fraction of separated Portland cement, Ceramics, 50, 15-21.
  • [6] Morsy, M. S., Alsayed, S. H., Salloum Y. A., (2012). Development of eco-friendly binder using metakaolin-fly ash-lime-anhydrous gypsum, Construction and Building Materials, 35, 772-777.
  • [7] Khalil, A. A., Abdel kader A. H., (2010). Preparation and physicomechanical properties of gypsum plaster-agro fiber waste composites, Journal of InterCeram: International Ceramic Review, 21, 62-67.
  • [8] Gartner, E. M., (2009). Cohesion and expansion in polycrystalline solids formed by hydration reactions: the case of gypsum plasters, Cement and Concrete Research, 39, 289-295.
  • [9] Wang, Y., Shui, Z., Gao, X., Huang, Y., Yu, R., Ling, G., (2019). Chloride binding behaviors of metakaolin-lime hydrated blends: influence of gypsum and atmospheric carbonation, Construction and Building Materials, 201, 380-390.
  • [10] Demir, İ., Başpınar, M. S., (2008). Effect of silica fume and expanded perlite addition on the technical properties of the fly ash-lime-gypsum mixture, Construction and Building Materials, 22, 1299-1304.
  • [11] Gourav, K., Reddy, B. V. V., (2018). Out-of-plane flexure behavior of fly ash-lime-gypsum brick masonry walls, Engineering Structures, 173, 241-250.
  • [12] Neto, A. A. M., Cincotto, M. A., Repette, W., (2010). Mechanical properties, drying and autogenous shrinkage of blast furnace slag activated with hydrated lime gypsum, Cement and Concrete Composites, 32, 312-318.
  • [13] Del Rio Merino, M., Astorqui, J. S. C., Saez, P. V., Jimenez, R. S., Cortina, M. G., (2018). Eco plaster mortars with addition of waste for high hardness coatings, Construction and Building Materials, 158, 649-656.
  • [14] Khalil, A. A., Tawfik, A., Hegazy, A. A., El-Shahat, M. F., (2014). Effect of some waste additives on the physical and mechanical properties of gypsum plaster composites, Construction and Building Materials, 68, 580-586.
  • [15] Aubert, J. E., Segui, P., Husson, B., Measson, M., (2012). A method developed to quantify lime and gypsum consumed by mineral additions, Cement and Concrete Composites, 34, 874-880.
  • [16] Massazza, F., (1998). “Pozzolana and Pozzolanic Cements” in Lea’s Chemistry of Cement and Concrete, Butterworth-Heinemann, 471-635.
  • [17] PAGÇEV, Atık İstatistikleri. http://www.pagcev.org/atik-istatistikleri. 2007. Erişim tarihi 07.09.2019.
  • [18] Lu, J. X., Zheng, H., Yang, S., He, Pingping, Poon, C. S., (2019). Co-utilization of waste glass cullet and glass powder in precast concrete products, Construction and Building Materials, 223, 210-220.
  • [19] Du, H., Tan, K. H., (2017). Properties of high volume glass powder concrete, Cement and Concrete Composites, 75, 22-29
  • [20] Ling, T. C., Poon, C. S., (2014). Feasible use of large volumes of GGBS in 100% recycled glass architectural mortar, Cement and Concrete Composites, 53, 350-356.
  • [21] Vaitkevicius, V., Serelis, E., Hilbig, H., (2014). The effect of glass powder on the micro-structure of ultra high performance concrete, Construction and Building Materials, 68, 102-109.
  • [22] Redden, R., Neithalath, N., (2014). Microstructure, strength, and moisture stability of alkali activated glass powder-based binders, Cement and Concrete Composites, 45, 46-56.
  • [23] Shao, Y., Lefort, T., Moras, S., Rodriguez, D., (2000). Studies on concrete containing ground waste glass, Cement and Concrete Research, 30, 91-100.
  • [24] Papadakis, V. G., Tsimas, S., (2002). Supplementary cementing materials in concrete Part I: efficiency and design, Cement and Concrete Research, 32, 1525-1532.
  • [25] Sevim, U. K., (2011). Colemanite ore waste concrete with low shrinkage and high split tensile strength, Materials and Structures, 44, 187-193.
  • [26] Olgun, A., Kavas, T., Erdogan Y., Once G., (2007). Physico-chemical characteristics of chemically activated cement containing boron, Building and Environment, 42, 2384-2395.
  • [27] Ochoa, G. P. A., Eras, J. J. C., Gutierrez, A. S., Hens, L., Vandecasteele, C., (2010). Residue from sugarcane juice filtration (filter cake): Energy use at the sugar factory, Waste and Biomass Valorization, 1, 407-413.
  • [28] Makul, N., Sua-iam, G., (2016). Characteristics and utilization of sugarcane filter cake waste in the production of lightweight foamed concrete, Journal of Cleaner Production, 126, 118-133.
  • [29] Yaduvanshi, N. P. S., Yadav, D. V., (1990). Effect of sulphation press mud and nitrogen fertilizer on biomass, nitrogen economy and plant composition in sugarcane and soil chemical properties, The Journal of Agricultural Science, 114 (3), 259-263.
  • [30] Neha, G., Sumit, T., Chandrajit, B., (2011). Characterization of press mud: a sugar industry waste, Fuel, 90, 389-394.
  • [31] Ribbing, C., (2007). Environmentally friendly use of non-coal ashes in Sweden, Waste Management, 27, 142-235.
  • [32] Li, H., Xu, J., Wu, J., Xu W., Xu, Yan, (2012). Influence of sugar filter mud on formation of Portland cement clinker, Journal of Wuhan University of Technology, 28 (4), 746-750.
  • [33] Li, H., Xu, W., Yang, X., Wu, J., (2014). Preparation of Portland cement with sugar filter mud as lime-based raw material, Journal of Cleaner Production, 66, 107-112.
  • [34] James, J., Pandian P. K., (2016). Geoenvironmental application of sugarcane press mud in lime stabilization of an expansive soil: a preliminary report, Australian Journal of Civil Engineering, 14 (2), 114-122.
  • [35] Mansoor, A. M., Visgai, P., Sumeha, P. S., Swathi, K., Sowmiya, R., (2017). Utilization of sugar mill waste in manufacturing of bricks, International Journal of Engineering Research and Technology, 5 (13), 1-5.
  • [36] Tesch, V., Middendorf, B., (2006). Occurrence of thaumasite in gypsum lime mortars for restoration, Cement and Concrete Research, 36, 1516-1522.
  • [37] TS EN 13279-1, Gypsum binders and gypsum plasters – Part 1: Definitions and requirements, February 2009, Turkish Standards Institute, Ankara.
  • [38] TS EN 459-1, Building lime – Part 1: Definitions, specifications and conformity criteria, 2015, Turkish Standards Institute, Ankara.
  • [39] Bu, J., Tian, Z., (2016). Relationship between pore structure and compressive strength of concrete: Experiment and statistical modeling, Sadhana, 41 (3), 337-344.
  • [40] Schiller, K. K., (1971). Strength of porous materials, Cement and Concrete Research, 1 (4), 419-422.
  • [41] Vimmrova, A., Keppert, M., Michalko, O., Cerny, R., (2014). Calcined gypsum-lime-metakaolin binders: Desing of optimal composition, Cement and Concrete Composites, 52, 91-96.
  • [42] Gencel, O., del Coz Diaz, J. J., Sutcu, M., Koksal, F., Alvarez Rabanal, F. P., Martinez-Barrera, G., (2016), A novel lightweight gypsum composite with diatomite and polypropylene fibers, Construction and Building Materials, 113, 732-740.

INVESTIGATING THE UTILIZATION OF WASTE GLASS POWDER, COLEMANITE ORE WASTE AND SUGAR FACTORY FILTER CAKE IN GYPSUM-LIME BASED MORTARS

Yıl 2019, Cilt: 9 Sayı: 2, 241 - 252, 30.12.2019
https://doi.org/10.36222/ejt.648038

Öz

The wastes generated by the recent
industrial developments threaten the future of the world. Therefore, researches
on the recycling of the industrial wastes in various ways are increasing day by
day. In this study, glass powder, a waste of glass industry, colemanite ore
waste, a by-product of boron industry and filter cake, one of the wastes of
sugar factories, were used. The evaluation of these wastes in gypsum and lime-based
mortars, which have been widely used for centuries, has been investigated. In
this study, 10, 20 and 30% of the waste materials were used instead of gypsum. Unit
weights, ultrasonic pulse velocities, apparent porosities and thermal
conductivity coefficients of the gypsum-lime based mortars were determined.
Compressive strength and bending strength tests were performed to determine the
mechanical properties. In this way, it is aimed to protect the natural raw
materials and to evaluate the waste materials.

Kaynakça

  • [1] Serna, A., del Rio, M., Palomo, J. G., Gonzalez, M., (2012). Improvement of gypsum plaster strain capacity by the addition of rubber particles from recycled tyres, Construction and Building Materials, 35, 633-641.
  • [2] Biçer, A., Kar, F., (2017). Thermal and mechanical properties of gypsum plaster mixed with expanded polystyrene and tragacanth, Thermal Science and Engineering Progress, 1, 59-65.
  • [3] Gencel, O., del Coz Diaz, J. J., Sütçü, M., Köksal, F., Alvarez Rabanal, F. P., Martinez-Barrera, B., Brostow, W., (2014). Properties of gypsum composites containing vermiculite and polypropylene fibers: Numerical and experimental results, Energy and Buildings, 70, 135-144.
  • [4] Barrera-Barbero, M. M., Medina Flores, N., (2018). The effect of polypropylene fibers on graphite-natural hydraulic lime pastes, Construction and Building Materials, 184, 591-601.
  • [5] Kamnikas, R., Mituzas, J., Kamnikas, A., (2006). The effect of pozzolana on the properties of the finest fraction of separated Portland cement, Ceramics, 50, 15-21.
  • [6] Morsy, M. S., Alsayed, S. H., Salloum Y. A., (2012). Development of eco-friendly binder using metakaolin-fly ash-lime-anhydrous gypsum, Construction and Building Materials, 35, 772-777.
  • [7] Khalil, A. A., Abdel kader A. H., (2010). Preparation and physicomechanical properties of gypsum plaster-agro fiber waste composites, Journal of InterCeram: International Ceramic Review, 21, 62-67.
  • [8] Gartner, E. M., (2009). Cohesion and expansion in polycrystalline solids formed by hydration reactions: the case of gypsum plasters, Cement and Concrete Research, 39, 289-295.
  • [9] Wang, Y., Shui, Z., Gao, X., Huang, Y., Yu, R., Ling, G., (2019). Chloride binding behaviors of metakaolin-lime hydrated blends: influence of gypsum and atmospheric carbonation, Construction and Building Materials, 201, 380-390.
  • [10] Demir, İ., Başpınar, M. S., (2008). Effect of silica fume and expanded perlite addition on the technical properties of the fly ash-lime-gypsum mixture, Construction and Building Materials, 22, 1299-1304.
  • [11] Gourav, K., Reddy, B. V. V., (2018). Out-of-plane flexure behavior of fly ash-lime-gypsum brick masonry walls, Engineering Structures, 173, 241-250.
  • [12] Neto, A. A. M., Cincotto, M. A., Repette, W., (2010). Mechanical properties, drying and autogenous shrinkage of blast furnace slag activated with hydrated lime gypsum, Cement and Concrete Composites, 32, 312-318.
  • [13] Del Rio Merino, M., Astorqui, J. S. C., Saez, P. V., Jimenez, R. S., Cortina, M. G., (2018). Eco plaster mortars with addition of waste for high hardness coatings, Construction and Building Materials, 158, 649-656.
  • [14] Khalil, A. A., Tawfik, A., Hegazy, A. A., El-Shahat, M. F., (2014). Effect of some waste additives on the physical and mechanical properties of gypsum plaster composites, Construction and Building Materials, 68, 580-586.
  • [15] Aubert, J. E., Segui, P., Husson, B., Measson, M., (2012). A method developed to quantify lime and gypsum consumed by mineral additions, Cement and Concrete Composites, 34, 874-880.
  • [16] Massazza, F., (1998). “Pozzolana and Pozzolanic Cements” in Lea’s Chemistry of Cement and Concrete, Butterworth-Heinemann, 471-635.
  • [17] PAGÇEV, Atık İstatistikleri. http://www.pagcev.org/atik-istatistikleri. 2007. Erişim tarihi 07.09.2019.
  • [18] Lu, J. X., Zheng, H., Yang, S., He, Pingping, Poon, C. S., (2019). Co-utilization of waste glass cullet and glass powder in precast concrete products, Construction and Building Materials, 223, 210-220.
  • [19] Du, H., Tan, K. H., (2017). Properties of high volume glass powder concrete, Cement and Concrete Composites, 75, 22-29
  • [20] Ling, T. C., Poon, C. S., (2014). Feasible use of large volumes of GGBS in 100% recycled glass architectural mortar, Cement and Concrete Composites, 53, 350-356.
  • [21] Vaitkevicius, V., Serelis, E., Hilbig, H., (2014). The effect of glass powder on the micro-structure of ultra high performance concrete, Construction and Building Materials, 68, 102-109.
  • [22] Redden, R., Neithalath, N., (2014). Microstructure, strength, and moisture stability of alkali activated glass powder-based binders, Cement and Concrete Composites, 45, 46-56.
  • [23] Shao, Y., Lefort, T., Moras, S., Rodriguez, D., (2000). Studies on concrete containing ground waste glass, Cement and Concrete Research, 30, 91-100.
  • [24] Papadakis, V. G., Tsimas, S., (2002). Supplementary cementing materials in concrete Part I: efficiency and design, Cement and Concrete Research, 32, 1525-1532.
  • [25] Sevim, U. K., (2011). Colemanite ore waste concrete with low shrinkage and high split tensile strength, Materials and Structures, 44, 187-193.
  • [26] Olgun, A., Kavas, T., Erdogan Y., Once G., (2007). Physico-chemical characteristics of chemically activated cement containing boron, Building and Environment, 42, 2384-2395.
  • [27] Ochoa, G. P. A., Eras, J. J. C., Gutierrez, A. S., Hens, L., Vandecasteele, C., (2010). Residue from sugarcane juice filtration (filter cake): Energy use at the sugar factory, Waste and Biomass Valorization, 1, 407-413.
  • [28] Makul, N., Sua-iam, G., (2016). Characteristics and utilization of sugarcane filter cake waste in the production of lightweight foamed concrete, Journal of Cleaner Production, 126, 118-133.
  • [29] Yaduvanshi, N. P. S., Yadav, D. V., (1990). Effect of sulphation press mud and nitrogen fertilizer on biomass, nitrogen economy and plant composition in sugarcane and soil chemical properties, The Journal of Agricultural Science, 114 (3), 259-263.
  • [30] Neha, G., Sumit, T., Chandrajit, B., (2011). Characterization of press mud: a sugar industry waste, Fuel, 90, 389-394.
  • [31] Ribbing, C., (2007). Environmentally friendly use of non-coal ashes in Sweden, Waste Management, 27, 142-235.
  • [32] Li, H., Xu, J., Wu, J., Xu W., Xu, Yan, (2012). Influence of sugar filter mud on formation of Portland cement clinker, Journal of Wuhan University of Technology, 28 (4), 746-750.
  • [33] Li, H., Xu, W., Yang, X., Wu, J., (2014). Preparation of Portland cement with sugar filter mud as lime-based raw material, Journal of Cleaner Production, 66, 107-112.
  • [34] James, J., Pandian P. K., (2016). Geoenvironmental application of sugarcane press mud in lime stabilization of an expansive soil: a preliminary report, Australian Journal of Civil Engineering, 14 (2), 114-122.
  • [35] Mansoor, A. M., Visgai, P., Sumeha, P. S., Swathi, K., Sowmiya, R., (2017). Utilization of sugar mill waste in manufacturing of bricks, International Journal of Engineering Research and Technology, 5 (13), 1-5.
  • [36] Tesch, V., Middendorf, B., (2006). Occurrence of thaumasite in gypsum lime mortars for restoration, Cement and Concrete Research, 36, 1516-1522.
  • [37] TS EN 13279-1, Gypsum binders and gypsum plasters – Part 1: Definitions and requirements, February 2009, Turkish Standards Institute, Ankara.
  • [38] TS EN 459-1, Building lime – Part 1: Definitions, specifications and conformity criteria, 2015, Turkish Standards Institute, Ankara.
  • [39] Bu, J., Tian, Z., (2016). Relationship between pore structure and compressive strength of concrete: Experiment and statistical modeling, Sadhana, 41 (3), 337-344.
  • [40] Schiller, K. K., (1971). Strength of porous materials, Cement and Concrete Research, 1 (4), 419-422.
  • [41] Vimmrova, A., Keppert, M., Michalko, O., Cerny, R., (2014). Calcined gypsum-lime-metakaolin binders: Desing of optimal composition, Cement and Concrete Composites, 52, 91-96.
  • [42] Gencel, O., del Coz Diaz, J. J., Sutcu, M., Koksal, F., Alvarez Rabanal, F. P., Martinez-Barrera, G., (2016), A novel lightweight gypsum composite with diatomite and polypropylene fibers, Construction and Building Materials, 113, 732-740.
Toplam 42 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular İnşaat Mühendisliği
Bölüm Araştırma Makalesi
Yazarlar

Muhammed Yasin Durgun 0000-0003-4656-9430

Yayımlanma Tarihi 30 Aralık 2019
Yayımlandığı Sayı Yıl 2019 Cilt: 9 Sayı: 2

Kaynak Göster

APA Durgun, M. Y. (2019). INVESTIGATING THE UTILIZATION OF WASTE GLASS POWDER, COLEMANITE ORE WASTE AND SUGAR FACTORY FILTER CAKE IN GYPSUM-LIME BASED MORTARS. European Journal of Technique (EJT), 9(2), 241-252. https://doi.org/10.36222/ejt.648038

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