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ahmadi E S, Afshinmehr V, Ahmadi S B, Pilechiha P. Evaluation of Mortar Containing Micro-nano Ceramic Pigments in Construction and Conservation to Landscape Beauty and Urban Development. Urban Design Discourse
a Review of Contemporary Litreatures and Theories 2021; 2 (2) :63-84
URL: http://udd.modares.ac.ir/article-40-54027-en.html
a Review of Contemporary Litreatures and Theories 2021; 2 (2) :63-84
URL: http://udd.modares.ac.ir/article-40-54027-en.html
1- Graduated from Urban Engineering, Payame Noor University, Tehran-East
2- Assistant Professor, Faculty of Architecture and Urban Planning, Payame Noor University , vafshinmehr@yahoo.com
3- Researcher, Faculty of Art and Architecture, Tarbiat Modares University
4- Department of Architecture, Tarbiat Modares University
2- Assistant Professor, Faculty of Architecture and Urban Planning, Payame Noor University , vafshinmehr@yahoo.com
3- Researcher, Faculty of Art and Architecture, Tarbiat Modares University
4- Department of Architecture, Tarbiat Modares University
Abstract: (1472 Views)
Aims: Applying micro-nano structure and biocompatibility methods and technology to produce mortar containing coloured ceramic pigment is a step towards beautiful landscape and urban development.
Methods: The research method is a combination of quantitative and qualitative analysis. First, from the analytical-exploratory process, especially in the field of urban planning, and in the field of materials and metallurgy, from the development method, and finally for collecting and analysing information and achievements experimentally (all experimentally), the research reaches numerical results and finally by interpreting qualitative results. Moreover, a little, the research conclusion came to an end.
Findings: Based on the experimental results and the acceptable result of the tests related to the mortar containing micro-nano ceramic pigments that have compressive strength and permeability in cement without additives, the durability of the proposed materials is acceptable. Materials are sustainable in terms of urban development with economic, social, ecosystem benefits, and due to the diversity of colours, these materials are also used in the beautiful landscape.
Conclusion: Eventually, it concluded that using methods and micro-nano structured and biocompatible materials to produce mortar containing ceramic pigment (with coloured ceramic cement) can be a step towards a beautiful landscape urban development.
Methods: The research method is a combination of quantitative and qualitative analysis. First, from the analytical-exploratory process, especially in the field of urban planning, and in the field of materials and metallurgy, from the development method, and finally for collecting and analysing information and achievements experimentally (all experimentally), the research reaches numerical results and finally by interpreting qualitative results. Moreover, a little, the research conclusion came to an end.
Findings: Based on the experimental results and the acceptable result of the tests related to the mortar containing micro-nano ceramic pigments that have compressive strength and permeability in cement without additives, the durability of the proposed materials is acceptable. Materials are sustainable in terms of urban development with economic, social, ecosystem benefits, and due to the diversity of colours, these materials are also used in the beautiful landscape.
Conclusion: Eventually, it concluded that using methods and micro-nano structured and biocompatible materials to produce mortar containing ceramic pigment (with coloured ceramic cement) can be a step towards a beautiful landscape urban development.
Keywords: Colored Cement, Urban Construction, Biocompatible Materials, Development, Beautiful landscape.
Article Type: Original Research |
Subject:
Environment and Urban Climate
Received: 2021/04/7 | Accepted: 2021/07/14 | Published: 2021/09/1
Received: 2021/04/7 | Accepted: 2021/07/14 | Published: 2021/09/1
References
1. [1] pilechiha, peiman; Ahmadi, Seyed Badreddin; Gholi Nejad Pirbazari, Alireza; Ahmadi, Erfaneh Sadat. Research project: Construction of colored ceramic cement, for bonding and covering the facades of brick historical buildings, Cultural Heritage and Tourism Research Institute, Iran, (1399)
2. [2] Ahmadi, Erfaneh Sadat; Afshin Mehr, Vahid; .Ahmadi, Seyed Badraldin,; pilechiha, peiman. construction, protection and restoration with ceramic micro-nano pigment mortar for beautification and sustainable urban development, dissertation Urban Engineering, Payame Noor University, East Tehran Branch, Iran (1400)
3. [3] Olawumi TO, Chan DW. A scientometric review of global research on sustainability and sustainable development. Journal of cleaner production. 2018 May 10;183:231-50.
4. [4] Law of the Sixth Five-Year Development Plan of the Islamic Republic of Iran (2016) (cases approved in the open court of the Islamic Consultative Assembly).
5. [5] Button K. City management and urban environmental indicators. Ecological economics. 2002 Feb 1;40(2):217-33.
6. [6] Parhizkar A, Firouzbakht A. Iranian urban management outlook with emphasis on urban Sustainable development. territory. 2011 Dec 22;8(issue4):43-67.
7. [7] Afify NS. The evolution of green cladding technology for architectural facades and its role in achieving environmental integration. Journal of Environmental Treatment Techniques. 2021 Mar 1;9(2):548-58.
8. [8] Fresco LO, Kroonenberg SB. Time and spatial scales in ecological sustainability. Land use policy. 1992 Jul 1;9(3):155-68.
9. [9] Jalilisadrabad S, Bolboli S. Evaluation of Position of Materials Used in the Urban Facades Approach to Sustainable Urban Development. Naqshejahan-Basic studies and New Technologies of Architecture and Planning. 2017 Jul 10;7(2):49-57.
10. [10] Rahaei, O., Ghaemmaghami, P. Environment and Sustainable Strategies in Design of Future Buildings. Journal of Environmental Science and Technology, 2014; 15(2): 135-146.
11. [11] Technical Committee of Occupational Health Limits of occupational exposure to pathogens. (2001) Tehran: University of Medical Sciences and Health Services
12. [12] Xun H. Sponge City Ecosystem and Application of Green Building Environmental Protection Materials. Ekoloji. 2019 May 27;28(108):675-80.
13. [13] Brookes AJ, Poole D, editors. Innovation in Architecture: A Path to the Future. Taylor & Francis; 2012 Dec 6.
14. [14] Momenian, Arezoo ,Meysam Zekavat، Color Palette in the City J Biochem Tech (2019) Special Issue (2): 86-93
15. [15] Jahanbakhsh, P, Nami, P. The Effect of Improvement of Building Facades on the Face of the City. (2013)Architecture and Sustainable Development Conference:1
16. [16] Cantino V, Giacosa E, Cortese D. A sustainable perspective in wine production for common-good management: the case of Fontanafredda biological “reserve”. British Food Journal. 2019 Feb 4.
17. [17] Berge B. The ecology of building materials. Routledge; 2009 Jun 4.
18. [18] Pacheco-Torgal F, Cabeza LF, Labrincha J, De Magalhaes AG. Eco-efficient construction and building materials: life cycle assessment (LCA), eco-labelling and case studies. woodhead Publishing; 2014 Feb 14.
19. [19] Estokova A, Porhincak M. Environmental analysis of two building material alternatives in structures with the aim of sustainable construction. Clean Technologies and Environmental Policy. 2015 Jan 1;17(1):75-83.
20. [20]Yousefi, M. Sustainable Materials in Architecture. Quarterly Engineering Arrangement of Qazvin; (2009) No 3 ,1 :37
21. [21] Olsen SI, Jørgensen MS. Environmental assessment of micro/nano production in a life cycle perspective. InMaterials Research Society Fall meeting )2006(. Materials Research Society.
22. [22] Addis B, Talbot R. Sustainable construction procurement: a guide to delivering environmentally responsible projects. (2009)
23. [23]Noorian, M, GodarziSoroush, M. Evaluation of traditional Iranian architecture with nature with approach of Sustainable Development.2nd Sustainable Architecture conference(2011) [internet]:74.Available at: www. Civilica.com
24. [24] Zandieh M, Parvardinejad S. Sustainable development and its concepts in residential architecture of Iran. Journal of Housing and Rural Environment of village. 2010(130).
25. [25] Ochsendorf JA. Sustainable engineering: The future of structural design. InStructures Congress 2005: Metropolis and Beyond 2005 (pp. 1-9).
26. [26]Ghorbanzadeh, M, Pilevar, A, Ghoddosi, S, Alinia, F. The Necessity and Utilization of Contemporary Residential Facade of the Principles of Vernacular Architecture. (2013)Architecture and Sustainable Development Conference:14
27. [27] Mofidi shemirani, M. Analyzing BIPV design method with sustainable design .International Journal of Architecture and urban planning ,IUST,Tehran; (2013)No-10:173 184.
28. [28]Gorji Mahlabani, Y, Hajabotalebi, E. Smart Material and Its Role in Architecture. (2009) First National Conference of New Construction tech:69.
29. [29] Pakzad, J, Souri, E. Architecture & urban design terms. (2007) Tehran: Shahidi issue:83.
30. [30]Roux, P. Sustainable Building Materials. Chicago: (2007) Green Building Council: 32-30.
31. [31] Huberman N, Pearlmutter D. A life-cycle energy analysis of building materials in the Negev desert. Energy and Buildings. 2008 Jan 1;40(5):837-48.
32. [32] McDonough W, Braungart M. Cradle to cradle: Remaking the way we make things. North point press; )2010( Mar 1.
33. [33]Parvizi, Elham, Mehrdad Karimi Consultant and Samad Negintej, Color in the City, Information Technology Management Press, and Center for Studying and Planning in Tehran(2012).
34. [34]Armaghan, M, Servatjo, H. Smart Materials in Elevation Sustainable Approach In Future. (2011) -2Second National Conference on Sustainable Architecture:9.
35. [35] ildarabadi, P., rahimi, M., Omidvar, P. Optimization of material consumption using novel technologies in construction industry and its influences on sustainable development considering CO2 emission mitigation. Journal of Environmental Science Studies, 2019; 4(1): 917-928.
36. [36] Mesri, M., ShahiniFar, M., mehrdanesh, G. Evaluating the quality of aesthetics and eliminating the inappropriate physical elements of urban constellation. Geography and Human Relationships, 2018; 1(3): 369-396.
37. [37] Moradpour R, Ahmadi SB, Parhizkar T, Ghodsian M, Taheri-Nassaj E. Study of the Effects of Ceramic Nano-Pigments in Cement Mortar Corrosion Caused by Chlorine Ions. International Journal of Civil and Environmental Engineering. 2014 Jan 10;7(3):263-8.
38. [38] Nasiri Hendeh Khaleh, E. Satisfaction of the citizens of the city with the beautification performance with the urban sustainability approach. , 2020; 11(42): 125-136.
39. [39] Bazazzadeh, H., Pilechiha, P., Nadolny, A., & Mahdavinejad, M. (2021). The Impact Assessment of Climate Change on Building Energy Consumption in Poland. Energies, 14(14), 4084. [Article] [DOI]
40. [40] Pilechiha, P., Mahdavinejad, M., & Beizaee, A. (2020). Simulation assisted design exploration to evaluate view and energy performance of window shading. [Article] [Google Scholar]
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