Çimento Kompozitlerinin Donma/Çözülme Direnci Üzerinde Kendi Kendini İyileştiren Kimyasal Katkı Maddelerinin Etkinliği
Abstract
Betonun kendi kendini iyileştirmesi, malzemenin mevcut çatlakları iyileştirerek kendini yenileme sürecidir Bu ya otojen/doğal kendi kendini iyileştirme ile ya da otonom/yapay kendi kendini iyileştirme ile olabilir. Otonom kendi kendini iyileştirme teknikleri arasında kristalli hidrofilik katkı maddelerinin kullanımı, bakteriyel yöntem ve mikroenkapsülasyon yöntemi yer alır. İçsel çatlamalar, donma/çözülme döngüleri tarafından meydana gelen hasar biçimlerinden biri olduğundan, bu makalenin amacı, kristal hidrofilik katkı maddesi ve mikrokapsüller gibi yapay kendi kendini iyileştirme tekniklerinin çimento kompozitlerinin donma/çözülme direnci üzerindeki etkinliğini değerlendirmektir. Bu amaçla, şahit harç karışımı, kristal hidrofilik katkılı harç karışımı ve toluen diizosiyanat (TDI) mikrokapsüllü harç karışımı (her iki katkı da çimento ağırlığına göre 2% oranında eklenmiştir) hazırlanmıştır. Sertleşmiş harç numuneleri CEN/TS 12390-9:2006 'ya göre donma/çözülme döngülerine tabi tutulmuş ve donma/çözülme döngülerinden kaynaklanan tufal malzeme miktarı ölçülmüştür. Kendi kendini iyileştiren katkı maddelerine sahip her iki harç karışımında tufal malzeme miktarının, burada kullanılan kendi kendini iyileştiren kimyasal katkı maddelerinin çimento kompozitlerinin donma/çözülme döngülerine karşı direncini artırabileceğini gösteren referans harç karışımına göre, daha düşük olduğu görülmüştür.
Keywords
Kristal hidrofilik katkı maddesi TDI mikrokapsüller Çimento kompozitleri Donma/çözülme direnci
References
- Abas Abdela Salem, M.; Pandey, R. K. (2017) Effect of air entrainment on compressive strength, density and ingredients of concrete. International Journal of Advances in Mechanical and Civil Engineering, ISSN: 2394-2827 Volume-4, Issue-6
- Byoung Sun, P., & Young, C. C. (2019) Investigating a new method to assess the self-healing performance of hardened cement pastes containing supplementary cementitious materials and crystalline admixtures. Journal of Materials Research and Technology, 8(6), 6058-6073
- Calvo, J.L.G.; Moreno, M.S.; Carballosa, P.; Pedrosa, F.; Tavares, F. (2019) Improvement of the Concrete Permeability by Using Hydrophilic Blended Additive. Materials, 12, 2384
- Cappellesso, V.G.; Petry, N.D.S.; Molin, D.C.C.D.; Masuero, A.B. (2016) Use of crystalline waterproofing to reduce capillary porosity in concrete. J. Build. Pathol. Rehabil., 1, 9
- CEN: Brussels. (1999) EN 1015-3:1999, Methods of test for mortar for masonry. Determination of consistence of fresh mortar (by flow table). Belgium
- CEN: Brussels. (2006) CEN/TR 15177:2006. Testing the freeze-thaw resistance of concrete - Internal structural damage. Belgium
- CEN: Brussels. (2006) CEN/TS 12390-9:2006. Testing hardened concrete - Part 9: Freeze-thaw resistance – Scaling. Belgium
- Danish, A.; Mosaberpanah, M. A.; Salim, M. U. (2020) Past and present techniques of self-healing in cementitious materials: A critical review on efficiency of implemented treatments. Journal of Materials Research and Technology
- Du, W.; Liu, Q.; Lin, R. (2021) Effects of toluene-di-isocyanate microcapsules on the frost resistance and self-repairing capability of concrete under freeze-thaw cycles. Journal of Building Engineering
- Du, W.; Yu, J.Y.; Gu, Y.; Li, Y.; Han, X.B.; Liu, Q.T. (2019) Preparation and application of microcapsules containing toluene diisocyanate for self-healing of concrete. Construction and Building Materials, 202, 762–769
- Du, W.; Yu, J.; He, B.; He, Y.; He, P.; Li, Y.; Liu, Q. (2020) Preparation and characterization of nano-SiO2/paraffin/PE wax composite shell microcapsules containing TDI for self-healing of cementitious materials. Construction and Building Materials 231, 117060
- García-Vera, V.E.; Tenza-Abril, A.J.; Saval, J.M.; Lanzón, M. (2019) Influence of Crystalline Admixtures on the Short-Term Behaviour of Mortars Exposed to Sulphuric Acid. Materials, 12, 82
- Gardner, D.; Lark, R.; Jefferson, T.; Davies, R. (2018) A survey on problems encountered in current concrete construction and the potential benefits of self-healing cementitious materials. Case studies in construction materials, 8, 238-247
- Gojević, A.; Ducman, V.; Netinger-Grubeša, I.; Baričević, A.; Banjad-Pečur, I. (2021) The Effect of Crystalline Waterproofing Admixtures on the Self-Healing and Permeability of Concrete. Materials
- Islam, Md. M.; Alam, M. T.; Islam, Md. S. (2018) Effect of fly ash on freeze–thaw durability of concrete in marine environment. Australian Journal of Structural Engineering, 19(2):1-16
- Kanellopoulos, A.; Giannaros, P.; Palmer, D.; Kerr A.; Al-Tabbaa, A. (2017) Polymeric microcapsules with switchable mechanical properties for self-healing concrete: synthesis, characterisation and proof of concept. Smart Mater. Struct. 26, 045025 (15pp)
- Koroth, S. R. (1997) Evaluation and Improvement of Frost Durability of Clay Bricks - A Thesis in The Centre for Building Studies. Ottawa, Canada
- Li, W.T.; Zhu, X.J.; Zhao, N.; Jiang, Z.W. (2016) Preparation and properties of melamine–urea–formaldehyde microcapsules for self-healing of cementitious materials. Materials 9, 152–168
- Mao, W.; Litina, C.; Al-Tabbaa, A. (2020) Development and application of novel sodium silicate microcapsule-based self-healing oil well cement. Materials 13, 456
- Nicula, L. M.; Corbu, O.; Iliescu, M. (2020) Influence of Blast Furnace Slag on the Durability Characteristic of Road Concrete Such as Freeze-Thaw Resistance. Procedia Manufacturing Volume 46, 194-201
- Park, B.; Choi, Y.C. (2020) Effect of healing products on the self-healing performance of cementitious materials with crystalline admixtures. Construction and Building Materials, 270, 121389
- Pilehvar, S.; Szczotok, A. M.; Rodríguez, J. F.; Valentini, L.; Lanzón, M.; Pamies, R.; Kjøniksen, A.-L. (2019) Effect of freeze-thaw cycles on the mechanical behavior of geopolymer concrete and Portland cement concrete containing micro-encapsulated phase change materials. Construction and Building Materials, 200, 94-103
- Qiu, Y.; Peng, H.; Zhao, H. (2020) Study on New Type of Concrete Air-Entraining Agent, International Conference on Artificial Intelligence and Electromechanical Automation (AIEA). Tianjin, China
- Richardson, M. G. (2002) Fundamentals of Durable Reinforced Concrete. First Edition, Spon Press, pp. 51, 77, 101, 133, 160-179, 194
- Tong, X.M.; Li, C.F. (2013) Preparation and characterization of self-healing microcapsules containing two-component. Adv. Mater. Res., 734–737, 2176–2180
- Wang, R.; Yu, J.; He, P.; Gu, S.; Cao, Z.; Liu, Q. (2019) Investigation of ion chelator and mineral admixtures improving salt-frost resistance of cement-based materials. Construction and Building Materials, Volume 227, 116670
- Zang, P.; Li, Q.-F. (2013) Freezing–thawing durability of fly ash concrete composites containing silica fume and polypropylene fiber. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications
- Žáková, H.; Pazderka, J.; Reiterman, P. (2020) Textile Reinforced Concrete in Combination with Improved Self-Healing Ability Caused by Crystalline Admixture. Materials, 13, 5787
Abstract
The paper compares the effectiveness of two self-healing chemical additives: crystalline hydrophilic additive and toluene diisocyanate (TDI) microcapsules, on the freeze/thaw resistance of cement composites. The reference mortar mixture, the mortar mixture with crystalline hydrophilic additive as well as the mortar mixture with TDI microcapsules (both additives added in 2% by cement weight) were prepared. Hardened mortar samples are subjected to freezing and thawing cycles according to CEN/TS 12390-9:2006. The testing results indicate that self-healing chemical additives used here could improve resistance of the cement composites to freeze/thaw cycles.
Keywords
Crystalline hydrophilic additive TDI microcapsules Cement composites Freeze/thaw resistance
References
- Abas Abdela Salem, M.; Pandey, R. K. (2017) Effect of air entrainment on compressive strength, density and ingredients of concrete. International Journal of Advances in Mechanical and Civil Engineering, ISSN: 2394-2827 Volume-4, Issue-6
- Byoung Sun, P., & Young, C. C. (2019) Investigating a new method to assess the self-healing performance of hardened cement pastes containing supplementary cementitious materials and crystalline admixtures. Journal of Materials Research and Technology, 8(6), 6058-6073
- Calvo, J.L.G.; Moreno, M.S.; Carballosa, P.; Pedrosa, F.; Tavares, F. (2019) Improvement of the Concrete Permeability by Using Hydrophilic Blended Additive. Materials, 12, 2384
- Cappellesso, V.G.; Petry, N.D.S.; Molin, D.C.C.D.; Masuero, A.B. (2016) Use of crystalline waterproofing to reduce capillary porosity in concrete. J. Build. Pathol. Rehabil., 1, 9
- CEN: Brussels. (1999) EN 1015-3:1999, Methods of test for mortar for masonry. Determination of consistence of fresh mortar (by flow table). Belgium
- CEN: Brussels. (2006) CEN/TR 15177:2006. Testing the freeze-thaw resistance of concrete - Internal structural damage. Belgium
- CEN: Brussels. (2006) CEN/TS 12390-9:2006. Testing hardened concrete - Part 9: Freeze-thaw resistance – Scaling. Belgium
- Danish, A.; Mosaberpanah, M. A.; Salim, M. U. (2020) Past and present techniques of self-healing in cementitious materials: A critical review on efficiency of implemented treatments. Journal of Materials Research and Technology
- Du, W.; Liu, Q.; Lin, R. (2021) Effects of toluene-di-isocyanate microcapsules on the frost resistance and self-repairing capability of concrete under freeze-thaw cycles. Journal of Building Engineering
- Du, W.; Yu, J.Y.; Gu, Y.; Li, Y.; Han, X.B.; Liu, Q.T. (2019) Preparation and application of microcapsules containing toluene diisocyanate for self-healing of concrete. Construction and Building Materials, 202, 762–769
- Du, W.; Yu, J.; He, B.; He, Y.; He, P.; Li, Y.; Liu, Q. (2020) Preparation and characterization of nano-SiO2/paraffin/PE wax composite shell microcapsules containing TDI for self-healing of cementitious materials. Construction and Building Materials 231, 117060
- García-Vera, V.E.; Tenza-Abril, A.J.; Saval, J.M.; Lanzón, M. (2019) Influence of Crystalline Admixtures on the Short-Term Behaviour of Mortars Exposed to Sulphuric Acid. Materials, 12, 82
- Gardner, D.; Lark, R.; Jefferson, T.; Davies, R. (2018) A survey on problems encountered in current concrete construction and the potential benefits of self-healing cementitious materials. Case studies in construction materials, 8, 238-247
- Gojević, A.; Ducman, V.; Netinger-Grubeša, I.; Baričević, A.; Banjad-Pečur, I. (2021) The Effect of Crystalline Waterproofing Admixtures on the Self-Healing and Permeability of Concrete. Materials
- Islam, Md. M.; Alam, M. T.; Islam, Md. S. (2018) Effect of fly ash on freeze–thaw durability of concrete in marine environment. Australian Journal of Structural Engineering, 19(2):1-16
- Kanellopoulos, A.; Giannaros, P.; Palmer, D.; Kerr A.; Al-Tabbaa, A. (2017) Polymeric microcapsules with switchable mechanical properties for self-healing concrete: synthesis, characterisation and proof of concept. Smart Mater. Struct. 26, 045025 (15pp)
- Koroth, S. R. (1997) Evaluation and Improvement of Frost Durability of Clay Bricks - A Thesis in The Centre for Building Studies. Ottawa, Canada
- Li, W.T.; Zhu, X.J.; Zhao, N.; Jiang, Z.W. (2016) Preparation and properties of melamine–urea–formaldehyde microcapsules for self-healing of cementitious materials. Materials 9, 152–168
- Mao, W.; Litina, C.; Al-Tabbaa, A. (2020) Development and application of novel sodium silicate microcapsule-based self-healing oil well cement. Materials 13, 456
- Nicula, L. M.; Corbu, O.; Iliescu, M. (2020) Influence of Blast Furnace Slag on the Durability Characteristic of Road Concrete Such as Freeze-Thaw Resistance. Procedia Manufacturing Volume 46, 194-201
- Park, B.; Choi, Y.C. (2020) Effect of healing products on the self-healing performance of cementitious materials with crystalline admixtures. Construction and Building Materials, 270, 121389
- Pilehvar, S.; Szczotok, A. M.; Rodríguez, J. F.; Valentini, L.; Lanzón, M.; Pamies, R.; Kjøniksen, A.-L. (2019) Effect of freeze-thaw cycles on the mechanical behavior of geopolymer concrete and Portland cement concrete containing micro-encapsulated phase change materials. Construction and Building Materials, 200, 94-103
- Qiu, Y.; Peng, H.; Zhao, H. (2020) Study on New Type of Concrete Air-Entraining Agent, International Conference on Artificial Intelligence and Electromechanical Automation (AIEA). Tianjin, China
- Richardson, M. G. (2002) Fundamentals of Durable Reinforced Concrete. First Edition, Spon Press, pp. 51, 77, 101, 133, 160-179, 194
- Tong, X.M.; Li, C.F. (2013) Preparation and characterization of self-healing microcapsules containing two-component. Adv. Mater. Res., 734–737, 2176–2180
- Wang, R.; Yu, J.; He, P.; Gu, S.; Cao, Z.; Liu, Q. (2019) Investigation of ion chelator and mineral admixtures improving salt-frost resistance of cement-based materials. Construction and Building Materials, Volume 227, 116670
- Zang, P.; Li, Q.-F. (2013) Freezing–thawing durability of fly ash concrete composites containing silica fume and polypropylene fiber. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications
- Žáková, H.; Pazderka, J.; Reiterman, P. (2020) Textile Reinforced Concrete in Combination with Improved Self-Healing Ability Caused by Crystalline Admixture. Materials, 13, 5787
Details
| Primary Language | English |
|---|---|
| Subjects | Civil Engineering |
| Journal Section | Research Articles |
| Authors | |
| Publication Date | December 31, 2021 |
| Published in Issue | Year 2021 Volume: 3 Issue: 2 |
