Mechanical Properties of Low Strength Concrete Incorporating Carbon Nanotubes
محورهای موضوعی :
ایمنی زیستی
Meysam Morsali
1
,
Reza Farokhzad
2
1 - Department of civil engineering, Islamic Azad University, Qazvin Branch
2 - Department of civil engineering, Islamic Azad University, Qazvin Branch
تاریخ دریافت : 1399/07/27
تاریخ پذیرش : 1399/08/27
تاریخ انتشار : 1400/03/11
کلید واژه:
Carbon nanotubes,
Graphene,
Micro silica,
the compressive strength of concrete,
protective cover,
چکیده مقاله :
Nowadays, due to the increasing population and the expansion of urbanization, and consequently the need for high-rise and multi-storey buildings that , the safety and resistance of the load bearing members of the structures has become of interest to researchers. For this purpose, different approaches have been proposed, including nanomaterials as a suitable and optimal method. Using nanomaterials as a percentage of cement weight improves concrete performance and increases its strength. Since these materials should be used at the beginning of concrete construction, therefore, they cannot be used in constructed structures. But a protective coating containing these nanomaterials can enhance and improve the performance of the structures, which is applicable to the fabricated structures. The purpose of this study was to investigate the effect of protective coatings with Nano silica, carbon nanotube and graphene nanomaterials. For this purpose, four thicknesses different and 2% nanomaterials different, the effect of thickness and percentage of nanomaterials were investigated. The results show that the sample containing 15% of silica with 26.74 N/mm2 has the highest effect compared to other nanomaterials. However, due to the low percentages of carbon nanotube and graphene, these materials have a significant effect.
منابع و مأخذ:
Mahmoud Golabchi, Katayoun Taghizadeh, Ehsan Soroushnia, "Nanotechnology in Architecture and Building Engineering", First Edition, University of Tehran, 2011.
Li, G. (2004). Properties of High-Volume Fly Ash Concrete Incorporating Nano-SiO2. Cement and Concrete Research, Vol. 34, pp. 1043-1049.
Jo, B.W, Kim, C.H., Tae, G.H., Park, J.B. (2007). Characteristics of cement mortar with nano-SiO2 particles. Construction and Building Materials, Vol.21, pp. 1351-1355.
Morteza H. Beigi, Javad Berenjian, Omid Lotfi Omran , Aref Sadeghi Nik , Iman M. Nikbin. (2013). An experimental survey on combined effects of fibers and nanosilica on the mechanical, rheological, and durability properties of self-compacting concrete. Materials and Design 50 pp. 1019–1029.
QingY., ZenanZ., DeyuK., RongS.C. (2007). Influence of nano-SiO2 addition on properties of hardened cement paste as compared with silica fume, Construction and Building Materials 21,539-545.
Li, G.Y., Wang, P.M., and Zhao, X. (2005). Mechanical behavior and microstructure of cement composites incorporating surfacetreated multi-walled carbon nanotubes. Carbon,Vol. 43, pp. 1239-1245.
Asghari Nikan, Abolfazl; Ahmari, Ahmad & Gholami, Javad, (2014), "A Study on the Compressive Strength and Structure of Inorganic Ash Cement Composites - Carbon Nanotubes", 3rd National Conference on New Technologies of Chemistry and Chemical Engineering, Islamic Azad University, Quchan Branch, Quchan.
Khalilzadeh Vahidi, Ebrahim and Nozar Moradi, 1, In vitro study of the effect of nanoclay and fly ash on compressive strength of cement sand mortar, Journal of Structural Engineering and Construction.
Chaipanich, A., Nochaiya, T., Wongkeo, W., and Tolkittikul, P. (2010). Compressive strength and microstructure of carbon nanotubes-fly ash cement composites. Materials Science and Engineering a Vol. 527, pp. 1063-1067.
Lau, K.T., Hui, D. (2002). The Revolutionary Creation of New Advanced Materials-Carbon Nanotube Composites, Composite Part B, Vol. 33, pp. 263-277.
Nanotechnology Book, Creation Technology Mirror, Office of Presidential Technological Cooperation at Oil Company Nanotechnology Policy Studies Committee, p. 125-123.
Maheswaran, S., et al. (2013). An Overview on the Influence of Nano Silica in Concrete and a ResearchInitiative. Research Journal of Recent Sciences, ISSN 2277: 2502.
Sanchez, Florence, and Konstantin Sobolev. (2010). Nanotechnology in concrete–a review. Construction and Building Materials 24.11: 2060-2071
Khastband, Hamed; Sohrabi, Mohammad Rezo Samimi, Abdolreza, (2009), "Investigation of the Effect of Nano Silica on Mechanical Properties of Lightweight Concrete, Eighth International Congress of Civil Engineering, Shiraz University, Shiraz.
Ye Qing, Zhang Zenan, Kong Deyu, Chen Rongshen, (2005). Influence of nano-SiO2 addition on properties of hardened cement paste as compared with silica fume. College of Architecture and Civil Engineering, Zhejiang University of Technology, 310014 Hangzhou, PR China, accepted 7 September.
Foroughi, M., (1388). Basic Information about Nano Technology. Azad Eslami University. Najafabad. 247.
Chaipanich, A., Nochaiya, T., Wongkeo, W., and Tolkittikul, P. (2010). Compressive strength and microstructure of carbon nanotubes-fly ash cement composites, Materials Science and Engineering A Vol. 527, pp. 1063-1067.
Nochaiya, T., Tolkidtikul, P., Singjai, P., and Chaipanich, A. (2008). Microstructure and characterizations of Portland-Carbon Nanotubes Pastes, Advanced Materials Research,Vols. 55- 57, pp. 549-552.
Kalvandi, M., (1386). NANO Technology And Usage Of This Technology On Civilization.
Chakoli, A. (1389). Influence of CNTs on Physical and Mechanical properties of Nano Composites. 1st National Conference Of Nano Science And Nano Technology.
Farokhzad, R., Ghodrati Amiri, G., Mohebi, B. and Ghafory-Ashtiany, M., 2016. Multi-Damage Detection for Steel Beam Structure. Journal of Rehabilitation in Civil Engineering, 4(2), pp.25-44.
Lau, K.T., Hui, D., (2002). The Revolutionary Creation of New Advanced Materials-Carbon Nanotube Composites, Composite Part B, Vol. 33, pp. 263-277.
L. Ci, B. Wei,C.Xu,J.Liang,D.Wu,S.Xie,W.Zhou,Y.Li,Z.Liu,D.Tang,J.Cryst. Growth233 (2001)823–828.
Farokhzad, R., Mahdikhani, M., Bagheri, A., & Baghdadi, J. (2016). Representing a logical grading zone for self-consolidating concrete. Construction and Building Materials, 115, 735-745.
J.M. Bonard, M. Croci, C. Klinke, R.Kurt, O.Noury, N.Weiss, Carbon40 (2002) 1715–1728.
Ismaili, Jamshid; Andalibi, Keyvan & Kasai, Jamil, (2015), "Investigation of the Effect of Nano Alumina Addition on the Mechanical Properties of Concrete", 10th International Congress of Civil Engineering, Faculty of Civil Engineering, University of Tabriz, Tabriz.
Chaipanich, A., Nochaiya, T., Wangle, W., and Tolkittikul, P. (2010). Compressive strength and microstructure of carbon nanotubes-fly ash cement composites. Materials Science and Engineering A Vol. 527, pp. 1063-1067.
Jelokhani Niaraki, R., & Farokhzad, R. (2017). Prediction of mechanical and fresh properties of self-consolidating concrete (SCC) using multi-objective genetic algorithm (MOGA). Journal of Structural Engineering and Geo-Techniques, 7(2), 1-13.
Li, F., Liu, L., Yang, Z. and Li, S., 2020. Physical and mechanical properties and micro characteristics of fly ash-based geopolymer paste incorporated with waste Granulated Blast Furnace Slag (GBFS) and functionalized Multi-Walled Carbon Nanotubes (MWCNTs). Journal of Hazardous Materials, 401, p.123339.
Jung, M., Lee, Y.S., Hong, S.G. and Moon, J., 2020. Carbon nanotubes (CNTs) in ultra-high performance concrete (UHPC): Dispersion, mechanical properties, and electromagnetic interference (EMI) shielding effectiveness (SE). Cement and Concrete Research, 131, p.106017.
