بتن ضد آب: نوآوری در ساخت و ساز

1. German Committee on Reinforced Concrete Guidelines for the Protection and Repair of Concrete Components, Part 3: Quality Assurance in Execution of the Works DAfStb, Berlin, Germany (1991)

2.Pfeiffer, D. W., & Scali, M. J. (1981). Concrete sealing for protection of bridge structures. National Cooperative Highway Research Program (NCHRP 244). Transportation Research Board, Washington DC.‏

3. Wong, H. S., Barakat, R., Alhilali, A., Saleh, M., & Cheeseman, C. R. (2015). Hydrophobic concrete using waste paper sludge ash. Cement and Concrete Research, 70, 9-20.‏

4. Tittarelli, F., & Moriconi, G. (2010). The effect of silane-based hydrophobic admixture on corrosion of galvanized reinforcing steel in concrete. Corrosion Science, 52(9), 2958-2963.‏

5. Zhou, Q., & Xu, Q. (2009). Experimental study of waterproof membranes on concrete deck: Interface adhesion under influences of critical factors. Materials & Design, 30(4), 1161-1168.‏

6. Dong, W., Li, W., Sun, Z., Ibrahim, I., & Sheng, D. (2022). Intrinsic graphene/cement-based sensors with piezoresistivity and superhydrophobicity capacities for smart concrete infrastructure. Automation in Construction, 133, 103983.‏

7. Jahandari, S., Tao, Z., & Alim, M. A. (2021, September). Effects of different integral hydrophobic admixtures on the properties of concrete. In Proceedings of the 30th Biennial National Conference of the Concrete Institute of Australia, Perth, Australia (pp. 5-8).‏

8. Mehdizadeh, B., Jahandari, S., Vessalas, K., Miraki, H., Rasekh, H., & Samali, B. (2021). Fresh, mechanical, and durability properties of self-compacting mortar incorporating alumina nanoparticles and rice husk ash. Materials, 14(22), 6778.‏

9. Hossain, M. M., Karim, M. R., Hasan, M., Hossain, M. K., & Zain, M. F. M. (2016). Durability of mortar and concrete made up of pozzolans as a partial replacement of cement: A review. Construction and building materials, 116, 128-140.‏

[10. Oltulu, M., & Şahin, R. (2011). Single and combined effects of nano-SiO2, nano-Al2O3 and nano-Fe2O3 powders on compressive strength and capillary permeability of cement mortar containing silica fume. Materials Science and Engineering: A, 528(22-23), 7012-7019.‏

11. Muhunthan, B., and Sariosseiri, F. (2008).“Interpretation of geotechnical properties of cement treated soils,” Research Report FHWA Contract DTFH61- 05-C-00008, Washington (State), Department of Transportation.

12. سوری، ع، "مقدمه‌اي بر مواد مكمل سيماني – بخش 1، فصل‌نامه سرامیک ایران، دوره 8، شماره 46، ، 1395.

13. C. Gervais, S.K. Ouki, 2002. Performance study of cementitious systems containing zeolite and silica fume: effects of four metal nitrates on the setting time, strength and leaching characteristics, Journal of Hazardous Materials. B93:187-200.

14. Tao ,Ji. (2005). “ Preliminary study on the water permeability and microstructure of concrete incorporating nano-SiO2 , ” Cement and Concrete Research: v35(Pages 1943-1947)

15. Yen Thi Tran, Jechan Lee, Pawan Kumar, Ki-Hyun Kim, Sang Soo Lee, 2018. Natural zeolite and its application in concrete composite production, Composites Part B, December .

16. Mailvaganam, N. P., Rixom, M. R., Manson, D. P., & Gonzales, C. (1999). Chemical admixtures for concrete. Crc Press.‏

17. A resin adhesive mortar preparation and phenol, 代丽珍, 常路生, 王勤, (2013). Materials Science.

18. Spaeth, V., Lecomte, J., & Delplancke-Ogletree, M. (2014). Integral water repellent based materials: Impact of aging on cement microstructure and performances. In Proc., Hydrophobe 7th Int. Conf. on Water Repellent Treatment and Protective Surface Technology for Building Materials (pp. 57-66).‏

19. Yoon, C. B., & Lee, H. S. (2020). Experimental study on the evaluation of physical performance and durability of cement mortar mixed with water repellent impregnated natural zeolite. Materials, 13(15), 3288.‏

20. Zhao, Y., Lei, L., Wang, Q., & Li, X. (2023). Study of superhydrophobic concrete with integral superhydrophobicity and anti-corrosion property. Case Studies in Construction Materials, 18, e01899.‏

21. Justnes, H. (2008). Low water permeability through hydrophobicity. COIN Project report, 1.‏

22. Song, Q., Wang, Q., Xu, S., Mao, J., Li, X., & Zhao, Y. (2022). Properties of water-repellent concrete mortar containing superhydrophobic oyster shell powder. Construction and Building Materials, 337, 127423.‏

23. Wang, M., Wang, Q., Mao, J., Xu, S., & Shi, Z. (2022). Study on water-repellent and corrosion-resistant properties of cement mortar using superhydrophobic iron ore tailings. Journal of Building Engineering, 62, 105360.‏

24. Wong, H. S., Barakat, R., Alhilali, A., Saleh, M., & Cheeseman, C. R. (2015). Hydrophobic concrete using waste paper sludge ash. Cement and Concrete Research, 70, 9-20.‏

25. Qu, Z. Y., & Yu, Q. L. (2018). Synthesizing super-hydrophobic ground granulated blast furnace slag to enhance the transport property of lightweight aggregate concrete. Construction and Building Materials, 191, 176-186.‏

26. Quraishi, M. A., Kumar, V., Abhilash, P. P., & Singh, B. N. (2011). Calcium stearate: A green corrosion inhibitor for steel in concrete environment. J. Mater. Environ. Sci, 2(4), 365-372.‏

27. Phuah, E. T., Yap, J. W. L., Lau, C. W., Lee, Y. Y., & Tang, T. K. (2022). Vegetable oils and animal fats: sources, properties and recovery. Recent Advances in Edible Fats and Oils Technology: Processing, Health Implications, Economic and Environmental Impact, 1-26.‏

28. Luan, Y., & Asamoto, S. (2023). Experimental study on mortar with the addition of hydrophobic silicone oil for water absorption, strength, and shrinkage. Construction and Building Materials, 367, 130323.‏

29. Justnes, H., Østnor, T. A., & Barnils Vila, N. (2004, October). Vegetable oils as water repellents for mortars. In Proceedings of the 1st international conference of asian concrete federation, Chiang Mai (pp. 28-29).‏

30. Teng, L. W., Huang, R., Chen, J., Cheng, A., & Hsu, H. M. (2014). A study of crystalline mechanism of penetration sealer materials. Materials, 7(1), 399-412.‏

31. https://www.waterproofmag.com/2010/04/understanding-integral-waterproofing, Accessed 18th Jul 2022

32. Borle, S., & Ghadge, A. N. (2016). Comparative study of conventional and modern waterproofing techniques. International Journal of Engineering Research, 5(1), 32-36.‏

33. Al-Kheetan, M. J., & Rahman, M. M. (2019). Integration of anhydrous sodium acetate (ASAc) into concrete pavement for protection against harmful impact of deicing salt. JOM, 71(12), 4899-4909.

‏

34. Al‐Kheetan, M. J., Rahman, M. M., & Chamberlain, D. A. (2018). Development of hydrophobic concrete by adding dual‐crystalline admixture at mixing stage. Structural Concrete, 19(5), 1504-1511.

‏

35. Franzoni, E., Pigino, B., & Pistolesi, C. (2013). Ethyl silicate for surface protection of concrete: Performance in comparison with other inorganic surface treatments. Cement and Concrete Composites, 44, 69-76.‏

36. Al-Kheetan, M. J., Rahman, M. M., & Chamberlain, D. A. (2020). Moisture evaluation of concrete pavement treated with hydrophobic surface impregnants. International Journal of Pavement Engineering, 21(14), 1746-1754.‏

37. Development of hydrophobic concrete by adding dual‐crystalline admixture at mixing stage.

38. Al-Rashed, R., & Al-Jabari, M. (2021). Multi-crystallization enhancer for concrete waterproofing by pore blocking. Construction and Building Materials, 272, 121668.‏

39. Zhang, P., Wittmann, F. H., & Zhao, T. J. (2009). Capillary Suction of and Chloride Penetration into Integral Water Repellent Concrete/Kapillare Saugfähigkeit und Eindringen von Chloriden in integral hydrophobierten Beton. Restoration of buildings and monuments, 15(3), 187-194.‏

40. Leong, K. S. (2019). Mechanical Properties of 1200 Kg/m3 Lightweight Foamed Concrete Incorporate With Calcium Stearate (Doctoral dissertation, UTAR).‏

41. Vijay, K., & Murmu, M. (2020). Experimental study on bacterial concrete using Bacillus subtilis micro-organism. In Emerging Trends in Civil Engineering: Select Proceedings of ICETCE 2018 (pp. 245-252). Springer Singapore.‏

42. Zhang, B., Li, Q., Ma, R., Niu, X., Yang, L., Hu, Y., & Zhang, J. (2021). The influence of a novel hydrophobic agent on the internal defect and multi-scale pore structure of concrete. Materials, 14(3), 609.‏

43. Zhang, Chaoyang, et al. "Water absorption behavior of hydrophobized concrete using silane emulsion as admixture." Cement and Concrete Research 154 (2022): 106738.‏

44. Zhu, Y. G., Kou, S. C., Poon, C. S., Dai, J. G., & Li, Q. Y. (2013). Influence of silane-based water repellent on the durability properties of recycled aggregate concrete. Cement and Concrete Composites, 35(1), 32-38.‏

45. مرادیان،م ، اصلانیان، ز ، نوری، و، 1389" عملکرد بتن حاوی زئولیت و دوده سیلیس در معرض اسید سولفوریک" دومین کنفرانس بتن.

46. صمیمی، ک، لیریایی، ج ، کمالی، س1397،" تاثیر پومیس و زئولیت بر دوام بتن خودتراکم در برابر حملات اسیدی،کربناته شدن و محیط های دریایی" ، اولین کنفرانس ملی دوام بتن.

47. Fanijo, E.O., Kolawole, J.T., & Almakrab, A. (2021). "Alkali-silica reaction (ASR) in concrete structures": Mechanisms, effects and evaluation test methods adopted in the United States Case Studies in Construction Materials.

48. Weise, F., von Werder, J., Manninger, T., Maier, B., Fladt, M., Simon, S., ... & Meng, B. (2022). A multiscale and multimethod approach to assess and mitigate concrete damage due to alkali–silica reaction. Advanced engineering materials, 24(6), 2101346.‏

49. G.K. Al-Chaar, M. Alkadi, P.G. Asteris, (2013). "Natural pozzolan as a partial substitute for cement in concrete", The Open Construction and Building Technology Journal, 7, 33-42.

50. Naiqian, F., Hongwei, J., & Enyi, C. (1998). "Study on the suppression effect of natural zeolite on expansion of concrete due to alkali-aggregate reaction". Magazine of Concrete Research, 50(1), 17-24.