PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
Tytuł artykułu

Badania cementu anhydrytowego otrzymywanego z fosfogipsu

Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
EN
Investigation of anhydrite cement produced from phosphogypsum
Języki publikacji
PL EN
Abstrakty
PL
Zbadano przydatność fosfogipsu, odpadu z produkcji kwasu fosforowego (surowcem był apatyt z półwyspu Kola w Rosji). W tym celu fosfogips, po neutralizacji wapnem, z dodatkiem 5% gliny i 5% mielonego szkła, prażono w temperaturze 900°C. Ta metoda daje cement anhydrytowy o dobrych właściwościach, którego wytrzymałość po 28 dniach twardnienia wnosi 55 MPa, w przypadku próbek suchych.
EN
The possibility of phosphogypsum, byproduct from the production of phosphoric acid (raw material - apatite from Kola peninsula, Russia), application for anhydrite cement production. Phosphogypsum, neutralized with lime, with addition of 5% of clay and 5% of ground glass was burned at 900°C. This method was assuring the production of anhydrite cement of high quality with compressive strength of 55 MPa of dry samples.
Czasopismo
Rocznik
Strony
362--369
Opis fizyczny
Bibliogr. 29 poz., il., tab.
Twórcy
  • Kaunas University of Technology, Lithuania
  • Kaunas University of Technology, Lithuania
Bibliografia
  • 1. M. Sing, M. Garg, Making of anhydrite cement from waste gypsum, Cem. Concr. Res., 30, 571-577 (2000).
  • 2. A. Jarosinski, Properties of anhydrite cement obtained from apatite phosphogypsum. Cem. Concr. Res., 24, 99 (1994).
  • 3. J. Cesniene, Influence of phosphatic impurities on the anhydrite binding material of phosphogypsum, Ceramics – Silicaty, 51, 3, 153-159 (2007).
  • 4. H. Tayibi, M. Choura, F. A. López, F. J. Alguacil, A. López-Delgado, Environmental impact and management of phosphogypsum, Journal of Management, 90, 8, 2377-2386 (2009).
  • 5. S. A. Evencik, A. A. Novikova, Phosphogypsum and its use, Moskow 1990. ( in Russian)
  • 6. B. B. Ivanitsky, Properties of the products of thermal processing of various types of gypsum materials, Build. Mat., 4, 26-27 (1985).
  • 7. S. Stonis, A. Kaziliunas, B. Vektaris, The production of calcium sulphate ß-hemihydrate, US Pat. 1224287 (1982).
  • 8. A. Kaziliunas, V. Leskeviciene, V. Vektaris, Z. Valancius, The study of neutralization of the dihydrate phosphogypsum impurities, Ceramics – Silicaty, 50, 3, 178-184 (2006).
  • 9. M. Garg, N. Jain, Waste gypsum from intermediate dye industries for production of building materials, Constr. Build. Mater., 24, 1632-1637 (2010).
  • 10. M. Sing, M. Garg, Study on anhydrite plaster from waste phosphogypsum for use in polymerized flooring composition, Constr. Build. Mater., 19, 1, 25-29 (2005),.
  • 11. J. Andriusiene, S. Stonis, B. Vektaris, C. Baublis, Raw mix for the production anhydrite binding material, US Pat. 1837055 (1988).
  • 12. V. Leskeviciene, D. Nizeviciene, Anhydrite binder calcined from phosphogypsum, Ceramics-Silikaty, 54, 2, 152-159 (2010).
  • 13. A. Kazragis, A. Jukneviciute, A. Gailius, E. Zalieckiene, Utilization of boon and chaff for manufacturing lightweight walling materials, J. Environ. Engin. Landscape Manage., 12, 1, 12-21 (2004).
  • 14. J. Grandans, E. Girsh, E. Moiseeva, Self-adjusting floor based on phosphoanhydrite, Building materials, 12 (1989) ( in Russian).
  • 15. J. Žvironaitė, J. Kerienė, D. Makutėnienė, V. Kizinievič, The peculiarities of hardening of composite anhydrite cement pozzolanna binding material with not burned natural anhydrite, Materials Science, 16 (2), 159-164 (2010).
  • 16. A. Jarosinski, Cz. Ostrowski, Effect of portland cement on strength development of phosphoanhydrite-pozzolana cement, Fizykochemiczne Problemy Mineralogii, 31, 137-143 (1997).[in Polish]
  • 17. C. S. Poon, S. C. Kou, L. Lam, Z. S. Lin, Activation of fly ash/cement systems using calciumsulfateanhydrite (CaSO4). Cem. Concr. Res., 31, 6, 873-881 (2001).
  • 18. L. Pelletier-Chaignat, F. Winnefeld, B. Lothenbach, G. Saout, Ch. Müller, Ch. Famy, Influence of the calcium sulphate source on the hydration mechanism of Portland cement–calcium sulphoaluminate clinker–calcium sulphate binders, Cem. Concr. Comp., 33, 5, 551-561 (2011).
  • 19. G. Tzouvalas, N. Dermatas, S. Tsimas, Alternative calcium sulphate-bearing materials as cement retarders, Part I. Anhydrite, Cem. Concr. Res., 34, 11, 2113-2118 (2004).
  • 20. EN 196-2. Methods of testing cement - Part 2: Chemical analysis of cement.
  • 21. GOST 20851.2 -75. Mineral fertilizers. Methods of determination of phosphorus content (in Russian).
  • 22. PDF – 2 International Centre for Diffraction Data, 12 Campus Boulevard Newtown Square, PA 19073-3273 USA.
  • 23. K. Nakamoto, Infrared and raman spectra of inorganic and coordination compounds, Wiley & Sons, New York 1997.
  • 24. D. Nizevičienė, V. Leškevičienė, Z. Valančius, V. Barkauskienė, Research into CO2 emission from ceramic product burning under the method of thermal analysis, Material Science and Applied Chemistry, 1, 15, 51-57 (2007).
  • 25. A. M. Sviklas, R. Paleckienė, R. Šlinksiene, V. Paltanavičius, S. Zemleckas, V. Štreimikis, Granulation of NPKS Fertilizers Using Ammoniating Solution and Sulphuric Acid, Fertilizers and Fertilization, 4, 17, 49-55 (2003).
  • 26. M. Bacauskiene, Investigation of dehydration of acid phosphogypsum, Chemical Technology, 4 (13), 38–45 (1999) (in Lithuanian).
  • 27. Ullmanns, Encyclopedia of industrial chemistry, 5th completely revised edition, Vol. A4, 1995.
  • 28. M. Martusevicius, R. Kaminskas, J. Mituzas, The chemical technology of binding materials, Kaunas, (2002) (in Lithuanian).
  • 29. A. Kazragis, A. Gailius, L. Valaityte, Binders on the base of gypsum either phosphogypsum and kaolin in: 14 International Baustofftagung (14 ibausil), Weimar, 0227-0230 (2000).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-b8f6e243-8b5b-439f-b52e-64bbf4e9b175
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.