Исследовано совместное применение отходов производства минеральной ваты (МВ) и отработанного катализатора (МК) каталитического крекинга нефтепродуктов в производстве керамики. Установлено, что по сравнению с контрольным составом МВ в процессе обжига при температуре 1080 °С действует как флюсующая добавка, увеличивая плотность образцов на 3,3 %, прочность при сжатии на 19,2 %, усадочную деформацию на 16,1 %, снижая водопоглощение в 3 раза. Совместное использование МВ и МК в составе (при увеличении МК от 10 до 20 %) способствует интенсификации кристаллизации минералов анортита и муллита, что обеспечивает снижение усадочной деформации до 1,85 раз, не ухудшая механические свойства по сравнению с контрольным составом без добавок
Wanga L., Jin Y., Nieb Y., Li R. Recycling of municipal solid waste incineration fly ash for ordinary Portland cement production: A real-scale test Resources // Resources, Conservation and Recycling. 2010. V. 54, Nо. 12. P. 1428 ? 1435.
Song Y., Li B., Yang E.H. et al. Feasibility study on utilization of municipal solid waste incineration bottom ash as aerating agent for the production of autoclaved aerated concrete // Cement and Concrete Composites. 2015. V. 56. P. 51 ? 58.
Yang J., Xiao B., Boccaccini A. R. Preparation of low melting temperature glass-ceramics from municipal waste incineration fly ash // Fuel. 2009. V. 88, Nо. 7. P. 1275 ? 1280.
Mymrin V., Klitzke W., Alekseev K. et al. Red clay application in the utilization of paper production sludge and scrap glass to fabricate ceramicmaterials // Applied Clay Science. 2015. V. 107. P. 28 ? 35.
Stonys R., Kuznetsov D., Krasnikovs A. et al. Reuse of ultrafine mineral wool production waste in the manufacture of refractory concrete // Journal of Environmental Management. 2016. V. 176. P. 149 ? 156.
Karayannis V.G. Development of extruded and fired bricks with steel industry byproduct towards circular economy // Journal of Building Engineering. 2016. V. 7. P. 382 ? 387.
Kazmia S. M. S., Abbas S., Munira M. J., Khitab A. Exploratory study on the effect of waste rice husk and sugarcane bagasse ashes in burnt clay bricks // Journal of Building Engineering. 2016. V. 7. P. 372 ? 378.
Taha Y., Benzaazoua M., Hakkou R., Mansori M. Natural clay substitution by calamine processing wastes to manufacture fired bricks // Journal of Cleaner Production. 2016. V. 135. P. 847 ? 858.
Li H., Liuliu D., Jiang Z. et al. Study on utilization of red brick waste powder in the production of cement-based red decorative plaster for walls // Journal of Cleaner Production. 2016. V. 133. P. 1017 ? 1026.
P. Mu?oz V., M. P. Morales O., V. Letelier G., M. A. Mend?vil G. Fired clay bricks made by adding wastes: Assessment of the impact on physical, mechanical and thermal properties // Construction and Building Materials. 2016. V. 125. P. 241 ? 252.
Coletti C., Maritan L., Cultrone G., Mazzoli C. Use of industrial ceramic sludge in brick production: Effect on aesthetic quality and physical properties // Construction and Building Materials. 2016. V. 124. P. 219 ? 227.
Soltan A. M. M., P?hler K., Fuchs F. et al. Clay-bricks from recycled rock tailings // Ceramics International. 2016. V. 42, Nо. 15. P. 16685 ? 16696.
Bernardo E., Bonomo E., Dattoli A. Optimisation of sintered glass?ceramics from an industrial waste glass // Ceramics International. 2010. V. 36, Nо. 5. P. 1675 ? 1680.
Erol M., Kucukbayrak S., Ersoy-Mericboyu A. The influence of the binder on the properties of sintered glass-ceramics produced from industrial wastes // Ceramics International. 2009. V. 35, Nо. 7. P. 2609 ? 2617.
Monteiro S. N., Alexandre J., Margem J. I. et al. Incorporation of sludge waste from water treatment plant into red ceramic // Construction and Building Materials. 2008. V. 22, Nо. 6. P. 1281 ? 1287.
Ducman V., Kopar T. The influence of different waste additions to clay-product mixtures // Materials and Technology. 2007, V. 41. Nо. 6. P. 289 ? 293.
El-Shimy Y. N., Amin Sh. K., EL-Sherbiny S. A., Abadir M. F. The use of cullet in the manufacture of vitrified clay pipes // Construction and Building Materials. 2014. V. 73. P. 452 ? 457.
P?rez-Villarejo L., Corpas-Iglesias F. A., Mart?nez-Mart?nez S. et al. Manufacturing new ceramic materials from clay and red mud derived from the aluminiumindustry // Construction and Building Materials. 2012. V. 35. P. 656 ? 665.
Kizinievi? O., Balkevi?ius V., Pranckevi?ien? J., Kizinievi? V. Investigation of the usage of centrifuging waste of mineral wool melt (CMWW), contaminated with phenol and formaldehyde, in manufacturing of ceramic products // Waste Management. 2014. V. 34, Nо. 8. P. 1488 ? 1494.
Boltakova N. V., Faseeva G. R., Kabirov R. R. et al. Utilization of inorganic industrial wastes in producing construction ceramics. Review of Russian experience for the years 2000?2015 // Waste Management. 2017. . 60. P. 230 ? 246.
Eidukevi?ius K., Laukaitis A., Siaurys V. Investigation of properties of briquettes from mineral wool waste, clay, cement dust, dolomite // International Conference Silicate technology. Kaunas, 2003. P. 138 ? 143.
Pranckevi?ien? J., Balkevi?ius V., ?pokauskas A. A. Investigations on properties of sintered ceramics out of low-melting illite clay and additive of fine-dispersed nepheline syenite // Materials science. 2010. V. 16, Nо. 3. P. 231 ? 235.
Dweck J., Pinto C. A., B?chler P. M. Study of a Brazilian spent catalyst as cement aggregate by thermal and mechanical analysis // Journal of Thermal Analysis and Calorimetry. 2008. V. 92, Nо. 1. P. 121 ? 127.
Sun D. D., Tay J. H., Cheong H. K. et al. Recovery of heavy metals and stabilization of spent hydrotreating catalyst using a glass?ceramic matrix // Journal of Hazardous Materials. 2001. V. 87, Nо. 1. ? 3. P. 213 ? 223.
Su N., Fang H. Y., Chen Z. H., Liu F. S. Reuse of waste catalysts from petrochemical industries for cement substitution // Cement and Concrete Research. 2000. V. 30, Nо. 11. P. 1773 ? 1783.
Su N., Chen Z. H., Fang H. Y. Reuse of spent catalyst as fine aggregate in cement mortar // Cement and Concrete Composites. 2001. V. 23, Nо. 1. P. 111 ? 118.
Marafi M., Stanislaus A. Spent catalyst waste management: A review // Resources, Conservation and Recycling. 2008. V. 52, Nо. 6. P. 859 ? 873.
Ramezani A., Emami S. M., Nemat S. Reuse of spent FCC catalyst, waste serpentine and kiln rollers waste for synthesis of cordierite and cordierite-mullite ceramics // Journal of Hazardous Materials. 2017. V. 338. P. 177 ? 185.
Sokolov V. M., Litvin L. G., Martynenko V. V. et al. Substitution of alumina by spent catalyst carrier in the refractory production // REWAS?04 ? Global Symposium on recycling, waste treatment and clean technology. Madrid, 2004. P. 381 ? 390.
Vargas F., Restrepo E., Rodr?guez J. E. et al. Solid-state synthesis of mullite from spent catalysts for manufacturing refractory brick coatings // Ceramics International. 2018. V. 44, Nо. 4. P. 3556 ? 3562.
Mart?nez J. D., Betancourt-Parra S., Carvajal-Mar?n I., Betancur-V?lez M. Ceramic light-weight aggregates production from petrochemical wastes and carbonates (NaHCO3 and CaCO3) as expansion agents // Construction and Building Materials. 2018. V. 180. P. 124 ? 133.
Кизиневич О., Мачюлайтис Р., Кизиневич В., Яковлев Г. И. Утилизация техногенного сырья нефтеперерабатывающего предприятия при производстве строительной керамики // Стекло и керамика. 2006. ? 2. С. 29 ? 32.
[Kizinievi? O., Ma?iulaitis R. Kizinievi? V., Yakovlev G. Utilization of technogenic material from an oil-processing company in the production of building ceramics // Glass Ceram. 2006. V. 63, Nо. 1?2. P. 64 ? 67.]
Antonovi? V., Pundien? I., Stonys R. et al. A review of the possible applications of nanotechnology in refractory concrete // Journal of Civil Engineering and Management. 2010. V. 16, Nо. 4. P. 595 ? 602.
Gal?n-Arboledas R. J., Cotes-Palomino M. T., Bueno S., Mart?nez-Garc?a C. Evaluation of spent diatomite incorporation in clay based materials for lightweight bricks processing // Construction and Building Materials. 2017. V. 144. P. 327 ? 337.
Статью можно приобрести
в электронном виде!
PDF формат
500 руб
УДК 666.3
Тип статьи:
Без рубрики
Оформить заявку