Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
Polymers are widely used in cement mortar and concrete modification due to their significant role in improving the overall performance of cement-based materials. Their physical interaction is well-accepted, while less attention is given to chemical interaction between the polymers and cement. Through a review of prior arts, chemical interactions are discussed and summarized in this paper. Various chemical interactions may take place between cement and different types of polymers. Understanding these chemical interactions will play an important role in clarifying the relationship between microstructure and macrostructure of polymer-modified cementitious materials. Authors expressed and proved the conviction that the organic-inorganic (Polymer-Portland cement) composite with some components chemically bonded, in parallel to the physical interaction, will be the next stage in concrete technology progress.
Rocznik
Tom
Strony
785--792
Opis fizyczny
Bibliogr. 51 poz., rys., tab., il., wykr.
Twórcy
autor
- Key Laboratory of Advanced Civil Engineering Materials of Ministry of Education, School of Materials Science and Engineering, Tongji University, 4800 Cao’an St., Shanghai 201804, China
autor
- Key Laboratory of Advanced Civil Engineering Materials of Ministry of Education, School of Materials Science and Engineering, Tongji University, 4800 Cao’an St., Shanghai 201804, China
autor
- Key Laboratory of Advanced Civil Engineering Materials of Ministry of Education, School of Materials Science and Engineering, Tongji University, 4800 Cao’an St., Shanghai 201804, China
autor
- Building Research Institute (ITB), 1 Filtrowa St., 00-611 Warsaw, Poland
Bibliografia
- [1] S. Chandra, “Historical background of polymers used in concrete”, 8th International Congress on Polymers in Concrete (ICPIC’1995), Ostend, Belgium, 3–11 (1995).
- [2] L. Cresson. “Improved manufacture of rubber road-acing, rubber-flooring, rubber-tiling or other rubber-lining”, British patent No. 191,474, 1923.
- [3] L. Czarnecki, “Concrete-polymer composites C-PC – Reading with understanding”, Restoration of buildings and monuments 18 (3–4), 135–142 (2012).
- [4] D. Van Gemert, “Synergies between polymers and cement concrete providing opportunities for sustainable construction”, Advanced Materials Research 687, 12–20 (2013).
- [5] D. Van Gemert and A. Beeldens, “Evolution in modeling microstructure formation in polymer-cement-concrete”, Restoration of Buildings and Monuments 19 (2–3), 97–108 (2013).
- [6] R. Bareš, “A conception of a structural theory of composite materials”, Brittle Matrix Composites I, eds. A. Brand and I. Marshall, 25–48 (1985).
- [7] D. Van Gemert, L. Czarnecki, and R. Bareš, “Basis for selection of PC and PCC for concrete repair”, Internation Journal of Cement Composites and Lightweight Concrete 110 (2), 121–123 (1988).
- [8] Y. Ohama, “Principle of latex modification and some typical properties of latex modified mortars and concretes”, ACI Materials Journal 84 (6), 511–518 (1987).
- [9] J. Bijen and Z. Su, “Polymer cement concrete: a contribution to modeling of the microstructure”, Proceedings of TC 113: Symposium on properties and test methods for concrete-polymer composites, ed. D. Van Gemert, Oostende, Belgium, 19–27 (1995).
- [10] M. Puterman and W. Malorny, “Some doubts and ideas on the microstructure formation of PCC”, Proceedings of the 9th ICPIC Congress, Bologna, ed. F. Sandrolini, 165–178 (1998).
- [11] H. Schorn and M. Schiekel, “Shape and distribution of polymer particles in PCC, investigated by ESEM”, Proceedings of 10th ICPIC, ed. D. Fowler, Hawaii, CD-ROM (2001).
- [12] A. Beeldens, D. Van Gemert, H. Schorn, Y. Ohama, and L. Czarnecki, “From microstructure to macrostructure: an integrated model of structure formation in polymer modified concrete”, RILEM Materials and Structures 38 (280), 601–607 (2005).
- [13] L. Czarnecki and H. Schorn, “Nanomonitoring of polymer cement concrete microstructure”, Restoration of Buildings and Monuments 13 (3), 141–152 (2007).
- [14] A. Dimmig-Osburn, “Microstructure of PCC – effects of polymer components and additives,. Proceedings of 12th ICPIC, Chuncheon, Korea, 239–248 (2007).
- [15] Y. Tian, Z. Li, H. Ma, and N. Jin, “An investigation on the microstructure formation of polymer modified mortars in the presence of polyacrylate latex”, Proceedings of International RILEM Conference on Advances in Construction Materials Through Science and Engineering, eds. C. Leung and K. Wan, Hong Kong, 71–77 (2011).
- [16] E. Knapen, A. Beeldens, and D. Van Gemert, “Water-soluble polymeric modifiers for cement mortar and concrete”, Proceedings of ConMat’05 3rd International Conference on Construction Materials: Performance, Innovation and structural Implications, Vancouver, Canada, (2005).
- [17] E. Knapen and D. Van Gemert, “Cement hydration and microstructure formation in the presence of water-soluble polymers”, Cement and concrete Research 39 (1), 6–13 (2009).
- [18] V. Riley and I. Razi, “Polymers additive for cement composites: a review. Composites 5 (1), 27–33 (1974).
- [19] S. Zeng, C. Short and C. Page, “Early-age hydration kinetics of polymer-modified cement”, Advances in Cement Research 8 (29), 1–9 (1996).
- [20] L. Czarnecki and P. Łukowski, “Influence of polymer admixtures and additives on durability of concrete”, Cement Lime Concrete 1, 38–47 (2004), [in Polish and English].
- [21] X. Fang, Z. Jing, J. P. Chen, et al., “Study on the interfacial adhesive performance and enhancement mechanism of polymer modified cement paste interface agent”, J. Materials Review 26, 119–122 (2012).
- [22] H. Cao, X.L. Zhang, X.H. Guo, et al., „Experimental study on anti-penetration performance of steel fiber reinforced polymer-modified concrete”. J. Advanced Materials Research 1030–1032, 1100–1103 (2014).
- [23] J. L. Nong, “Study on bonding performance of polymer-modified cement-based bonding composite”, Hunan, (2014).
- [24] Z. Xu, X. Lu, and L. S. Wang, “The carbonation of concrete and its control measures”, J. Ready-mixed Concrete. 3, 43–44 (2014).
- [25] X. H. Guo, X. L. Zhang, H. Cao, “Experimental investigation on impact ductility of polymer-modified concrete subjected to falling weight loading”, J. Advanced Materials Research 1030–1032, 770–773 (2014).
- [26] H. Cao, “Research on freeze-thaw characteristics for polymer modified porous concrete”, J. China Building Materials Science & Technology 5, 25–27 (2013).
- [27] Z. H. Wang, “Performance of polymer cement concrete”, J. Transportation Standardization 42, 88–90 (2014).
- [28] F. Q. Han, X. H. Lin, C. T. Zhang, et al., “Effects of CMC polymer on mechanical properties of cement mortars”, J. Building Science 31, 70–74 (2015).
- [29] R. Wang and P. M. Wang, “Research development of the properties and mechanism of polymer-modified cementitious materials”, J. Materials Review 21, 93–96 (2007).
- [30] D. A. Silva, H. R. Roman, and P. J. P. Gleize, “Evidences of chemical interaction between EVA and hydrating portland cement”, J. Cement and Concrete Research 32, 1383–1390 (2002).
- [31] J. Dikeou, “Review of worldwide developments and use of polymers in concrete”, 1st ICPIC’75, London, UK, 2–8 (1975).
- [32] J. Geist, S. Amanga, and B. Mellor “Improved portland cement mortars with polyvinyl acetate emulsions”, Industrial and Engineering Chemistry 45, 759–767 (1953).
- [33] Report on polymer-modified concrete, Report of ACI Committee 548, ACI Publication nr. 548.3R-09, Farmington Hills, USA, 2009.
- [34] Y. Ohama, “Polymer-based admixtures”, J. Cement and Concrete Composites 20, 189–212 (1998).
- [35] A. M. Betioli, J. Hoppe Filho, M. A. Cincotto, et al., “Chemical interaction between EVA and portland cement hydration at early-age”, J. Construction and Building Materials 23, 3332–3336 (2009).
- [36] D. A. Silva and P. J. M. Monteiro, “Analysis of C3A hydration using soft x-rays transmission microscopy: effect of EVA copolymer”, J. Cement and Concrete Research 35, 2026–2032 (2005).
- [37] J. L. MacDonald, U. W. Zwanziger, B. H. Chen, et al., “A 43Ca and 13C NMR study of the chemical interaction between poly(ethylene–vinylacetate) and white cement during hydration”, J. Solid State Nuclear Magnetic Resonance 40, 78–83 (2011).
- [38] H. Ma, Y. Tian, and Z. Li, “Interactions Between Organic and Inorganic Phases in PA-and PU/PA-modified-cement-based Materials”, J. Journal of Materials in Civil Engineering 23, 1412–1421 (2011).
- [39] Y. Tian, X. Jin, N. Jin, et al., “Research on the microstructure formation of polyacrylate latex modified mortars”, J. Construction and Building Materials 47, 1381–1394 (2013).
- [40] B. Li, Y. Tian, R. Y. Zhao, et al., “Microstructure and modification mechanism of polyacrylate latex modified mortars”, J. Journal of Zhejiang University 48, 1345–1361 (2014).
- [41] J. Long, K. Yu, and G. D. Li, “Correlation between cement hydrate and polymers”, J. Concrete 3, 35–41 (1995).
- [42] J. M. Gao and K. Morino, “Research on polymer modified cement mortar containing silica fume”, J. China Concrete and Cement Products 5, 8–10 (2000).
- [43] R. Wang, L. J. Yao, and P. M. Wang, “Mechanism analysis and effect of styrene-acrylate copolymer powder on cement hydrates”, J. Construction and Building Materials 41, 538–544 (2013).
- [44] S. Chandra and L. Berntsson, “Behavior of calcium hydroxide with styrene acrylates polymer dispersion”, J. Cement and Concrete Research 11, 125–129 (1981).
- [45] J. Plank and M. Gretz, “Study on the interaction between anionic and cationic latex particles and portland cement”, J. Colloids and Surfaces Aspects 330, 227–233 (2008).
- [46] C. Y. Rha and J. W Seong, “Properties and interactions of cement with polymer in the hardened cement pastes added absorbent polymer”, J. Journal of Materials Science 34, 4653–4659 (1999).
- [47] S. G. Hu, “Some characteristic analyses in the hydration system of polyacrylamide-monocalcium aluminate”, Journal of Wuhan University of Technology 16, 69–73 (1994).
- [48] P. Choonkeum, C. Dongwon, and O. Heegap, “Role of ions in the marco-defect-free cementitious materials made with ordinary portland cement”, Journal of the Chinese Ceramic Society 24, 382–388 (1996).
- [49] D. Gawin, M. Koniorczyk, and F. Pesavento, “Modelling of hydro-thermo-chemo-mechanical phenomena in buildings materials”, Bull. Pol. Ac.: Tech 61 (1), 51–64 (2013).
- [50] P. Łukowski, “Material modification in concrete”, Ass. Of Concrete Producers, Cracow, 2016 [in Polish].
- [51] L. Czarnecki and J. J. Sokołowska, “Material model and revealing the truth”, Bull. Pol. Ac.: Tech. 63 (1), 7–14 (2015).
Uwagi
PL
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-fb854cbc-126e-4dc9-a655-3e9e1f1d19d1