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Use of Sustainable Fine-Grain Aggregates in Cement Composites

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The previous research and the analyses from various research centers indicate the usefulness of the aggregates obtained from waste in the construction materials technology, although their technical parameters are not always comparable to the properties of traditional materials manufactured on the basis of primary raw materials. However, with a very large variety of expected technical features, these slightly lower parameters may be sufficient for use in engineering facilities. Mortars and concretes are the most popular group of materials, where aggregates obtained from waste can be used without any problems. The presented characteristics of the properties of fine aggregates, which were produced by grinding concrete and ceramic debris, as well as the fragmentation of municipal sewage sludge, in connection with the properties of cement mortars, is a clear example of this. The study showed that the cement mortars, in which natural aggregate was replaced by waste glass with the same granulation, confirmed their usefulness as mortar for building masonry, or underlays for floors. However, the fact that carrying out the process of fragmentation of waste to adequately fine granulation on an industrial scale is highly inconvenient, cannot be omitted. There are no difficulties in obtaining the aggregates with larger grains, which are used in hardening unpaved roads or as a concrete component. Obtaining finer grains of recycled aggregate becomes more challenging. Overcoming this obstacle will make the fine-grained aggregates obtained through the recycling of waste materials a viable alternative to the natural aggregates. This will contribute to the reduction of the extraction of natural sands, and thus to the protection of the natural environment.
Rocznik
Strony
102--109
Opis fizyczny
Bibliogr. 26 poz., rys., tab.
Twórcy
  • Department of Building Physics and Building Materials, Faculty of Civil Engineering and Architecture, West Pomeranian University of Technology, Szczecin, al. Piastów 50, 70-310 Szczecin, Poland
Bibliografia
  • 1. Aly M., Hashmi M.S.J., Olabi A.G., Messeiry M., Abadir E.F., Hussain A.I. 2012. Effect of colloidal nano-silica on the mechanical and physical behavior of waste glass cement mortar. Materials and Design, 33, 127–135.
  • 2. Batayneh M., Marie I., Asi I. 2007. Use of selected waste materials in concrete mixes. Waste Management, 27, 1870–1876.
  • 3. Bołtryk M., Kalinowska-Wichrowska K. 2017. Frakcja drobna z recyklingu betonu jako aktywny wypełniacz wyrobów wapienno-piaskowych, Materiały Budowlane 8, Wydawnictwo Sigma-Not, Warszawa, 54–55.
  • 4. Brito J. 2005. Recycled aggregates and its influence on concrete properties (in Portuguese), Public Lecture within the Full Professorship in Civil Engineering Pre-Admission Examination, Instituto Superior Técnico, Technical University of Lisbon.
  • 5. Brito J., Pereira A.S., Correia J.R. 2005. Mechanical behaviour of non-structural concrete made with recycled ceramic aggregates, Cement and Concrete Composites, 27(4), 429–433.
  • 6. Brożyna A., Kozioł W. 2014. Prognozy wyczerpywania bazy zasobów kopalin – teoria i praktyka, Przegląd Górniczy, 70(4), 86–89.
  • 7. Du H., Tan K.H. 2014. Concrete with Recycled Glass as Fine Aggregates, ACI Materials Journal, 47–57.
  • 8. Etxeberria M., Vazquez E., Mari A., Barra M. 2007. Influence of amount of recycled coarse aggregates and production process on properties of recycled aggregate concrete, Cement and Concrete Research, 7(5), 735–742.
  • 9. Evangelista L., Brito J. 2007. Mechanical behaviour of concrete made with fine recycled concrete aggregates, Cement and Concrete Composites, 29(5), 397–401.
  • 10. Fonseca N., Brito J., Evangelista L. 2011. The influence of curing conditions on the mechanical performance of concrete made with recycled concrete waste, Cement and Concrete Composites, 33(6), 637–643.
  • 11. Głowacka A., Rucińska T., Kiper J. 2017. The slag original from the process of sewage sludge incineration selected properties characteristic, E3S Web Conf., Volume 22.
  • 12. Gołek Ł., Kapeluszna E. 2013. Zastosowanie stłuczki szklanej i popiołów fluidalnych do produkcji spoiw, Świat Szkła, 5, 42–44.
  • 13. Goncalves P., Brito J. 2010. Recykled aggregate concerete (RAC) – comparative analysis of existing specifications. Magazine of Concrete Research, 62(5), 339–346.
  • 14. Jura J., Halbiniak J., Ulewicz M. 2015. Wykorzystanie odpadów ceramiki użytkowej i sanitarnej w zaprawach cementowych, Materiały Ceramiczne, 67(4), 438–442.
  • 15. Kurpińska M., Ferenc T. 2017. Effect of porosity on physical properties of lightweight cement composite with foamed glass aggregate, ITM Web of Confrences, 15, 06005.
  • 16. Kuśnierz A. 2010. Recykling szkła, Prace Instytutu Ceramiki i Materiałów Budowlanych, 3(6), 438–442.
  • 17. Limbachiya M.C., Dhir R.K., Leelawat T. 2000. Use of recycled concrete aggregate in high-strength concrete, Materials and Structures, 33(9), 574–580.
  • 18. Rucińska T. 2018. Sustainable cement mortars, E3S Web of Conferences, 49, 00090, 1–8.
  • 19. Sikora P., Augustyniak A., Cendrowski K., Horszczaruk E., Rucinska T., Nawrotek P., Mijowska E. 2016. Characterization of Mechanical and Bactericidal Properties of Cement Mortars Containing Waste Glass Aggregate and Nanomaterials. Materials, 9(8), 701.
  • 20. Sikora P., Horszczaruk E., Rucińska T., Straszyńska A. 2015. Wpływ wysokiej temperatury na właściwości mechaniczne zapraw cementowych ze stłuczką szklaną. Materiały Budowlane, 5, 116–118.
  • 21. Siwińska A. and Garbalińska H. 2011. Thermal conductivity coefficient of cement-based mortars as air relative humidity function. Heat Mass Transfer, 47, 1077–1087.
  • 22. Skoczylas K., Rucińska T. 2018. The effects of waste glass cullets and nanosilica on the long-term properties of cement mortars, E3S Web of Conferences, 49, 00102.
  • 23. Skoczylas K., Rucińska T. 2018. Strength and durability of cement mortars containing nanosilica and waste glass fine aggregate, Cement-Wapno-Beton, 3, 206–215.
  • 24. Strzałkowski J., Garbalińska H. 2018. Thermal simulation of building performance with different loadbearing materials, IOP Conference Series: Materials Science and Engineering, Kraków, 415, 1–10.
  • 25. Strzałkowski J., Garbalińska H. 2016. Thermal and strength properties of lightweight concretes with addition of aerogel particles, Advances in Cement Research, 567–575.
  • 26. Zhou C., Chen Z. 2017. Mechanical properties of recycled concrete made with different types of coarse aggregate, Construction and Building Materials, 134, 497–506.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-d9671ee0-2869-4ac9-9ffd-b9bdc8afe421
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