Volume 10, Issue 3 (2020)
Naqshejahan 2020, 10(3): 219-230 |
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Nasr T, Yarmahmoodi Z, Ahmadi S. The Effect of Kinetic Shell’s Geometry on Energy Efficiency Optimization Inspired by Kinetic Algorithm of Mimosa pudic. Naqshejahan 2020; 10 (3) :219-230
URL: http://bsnt.modares.ac.ir/article-2-41949-en.html
URL: http://bsnt.modares.ac.ir/article-2-41949-en.html
1- Department of Architecture, Faculty of Art & Architecture, Shiraz Branch, Islamic Azad University, Shiraz, Iran , nasr@iaushiraz.ac.ir
2- Department of Architecture, Faculty of Art & Architecture, Shiraz Branch, Islamic Azad University, Shiraz, Iran
3- Department of Architecture, Art & Architecture Faculty, Apadana Education Institute, Shiraz, Iran
2- Department of Architecture, Faculty of Art & Architecture, Shiraz Branch, Islamic Azad University, Shiraz, Iran
3- Department of Architecture, Art & Architecture Faculty, Apadana Education Institute, Shiraz, Iran
Abstract: (3342 Views)
Aims: Fixed vertical and horizontal canopies that are used in buildings give a low level of clean and inexpensive energy. Therefore, modern technology should use in constructing new buildings in order to have maximum use of this blessing. One of these technologies is kinetic canopies which they can put on the façade. This would result in optimal use of sunlight and also a dynamic design style. The purpose of the current study is to present a kinetic smart shell model inspired by the Mimosa pudica motion algorithm in order to optimize energy consumption.
Materials & Methods: This study is quantitative and simulation-modeling research that modeling of kinetic shell has done in the Rhino 6 software and Grasshopper and climate analysis has performed using the Ladybug plugins. The shell has been analyzed on the south facade of a building in the Shiraz climate.
Findings: In the current study, attempted to create one-degree-angle canopies in each of the horizontal constituents by optimizing the facade to achieve better performance and aesthetic form. The amount of radiation received in this analysis ranges from 0 to 50.16kwh/m2. Finally, a table on the analysis of the kinetic shell energy from 6 to 19 o'clock in August and the climate of Shiraz was presented.
Conclusion: Modeled smart shell can be used as a kinetic canopy that can optimize energy consumption compatable with Shiraz climate.
Materials & Methods: This study is quantitative and simulation-modeling research that modeling of kinetic shell has done in the Rhino 6 software and Grasshopper and climate analysis has performed using the Ladybug plugins. The shell has been analyzed on the south facade of a building in the Shiraz climate.
Findings: In the current study, attempted to create one-degree-angle canopies in each of the horizontal constituents by optimizing the facade to achieve better performance and aesthetic form. The amount of radiation received in this analysis ranges from 0 to 50.16kwh/m2. Finally, a table on the analysis of the kinetic shell energy from 6 to 19 o'clock in August and the climate of Shiraz was presented.
Conclusion: Modeled smart shell can be used as a kinetic canopy that can optimize energy consumption compatable with Shiraz climate.
Article Type: Original Research |
Subject:
Highperformance Architecture
Received: 2020/04/9 | Accepted: 2020/04/13 | Published: 2020/10/21
Received: 2020/04/9 | Accepted: 2020/04/13 | Published: 2020/10/21
References
1. Ghasemzadeh M, Aliyev F, Hasanova A. Silk road, an expression of green architecture "sustainability and confilict with climate change in architecture and urbanization of tourism areas". NAQSHEJAHAN. 2018;8(1):57-69. [Persian] [Link]
2. Moulaii M.M, Pilechiha P, Shadanfar A. Optimization of window proportions with an approach to reducing energy consumption in office buildings. NAQSHEJAHAN. 2019;9(2):117-23. [Persian] [Link]
3. Nasr T. Evaluation of renovation measures for urban deteriorated fabrics in Iran (in Comparison to global renovation experiences) in line with the objectives of sustainable development. J Reg Plan. 2017;7(27):181-98. [Persian] [Link]
4. Fallah H. Determining the most efficient window-to-wall ratio in southern façade of educational buildings in Kerman. NAQSHEJAHAN. 2019;9(2): 105-15. [Persian] [Link]
5. Nasr T, Rismani A, Bahadori M. The significance of natural components of Quranic life in Islamic-Iranian architecture (Case studies: residential architecture of Qajar, Zand, and Pahlavi Eras in Shiraz). NAQSHEJAHAN. 2017;7(3):47-62. [Persian] [Link]
6. Rasuli M, Shahbazi Y, Matini MR. Horizontal and vertical movable drop-down shades performance in double skin façade of office buildings; Evaluation and parametric simulation. NAQSHEJAHAN. 2019;9(1):23-31. [Persian] [Link]
7. Mirmasoumi FS, Salavati M, Ahmadi F. Isfahan green dwelling, the reflection of energy use optimization on quality of life. NAQSHEJAHAN. 2018;8(3):195-204. [Persian] [Link]
8. Noroozian N. Localization pattern for assessment of energy efficiency in buildings in Tehran. NAQSHEJAHAN. 2016;6(3):63-74. [Persian] [Link]
9. Medi H, Imani M. Biomimic technology and nature inspiration. NAQSHEJAHAN. 2018;8(1):47-55. [Persian] [Link]
10. Motallaei S, Heidari Sh. Breathing wall modeling to absorb indoor pollutants in the living room of a house inspired by the buffer zones of traditional architecture in hot and arid climate of Iran. NAQSHEJAHAN. 2018;8(1):1-7. [Persian] [Link]
11. Abasi M, Tahbaz M, Vafaee R. Introducing an innovative variable building layers system (V.B.L.S). NAQSHEJAHAN. 2015;5(2):43-54. [Persian] [Link]
12. Ghodsi M, Daneshjoo K, Mofidi Shemirani SM. Impact of geometric indicators on residential thermal behavior in hot arid climate (Case study: Yazd). NAQSHEJAHAN. 2018;8(3):143-8. [Persian] [Link]
13. Ahmadnejad Karimi M, Asefi M, haghparast F. Propose of movement pattern for curved retractable roofs with using of movable bars. NAQSHEJAHAN. 2016;6(3):27-37. [Persian] [Link]
14. Mahdavinejad M, Fakhari M. Stablishment of optimum designing pattern in buildings roof shape based on energy loss. NAQSHEJAHAN. 2013;3(2):35-42. [Persian] [Link]
15. Moulaii MM, Pourjafar MR, Bemanian MR. Introduction of interactive architecture and its role in the adaption of architecture. NAQSHEJAHAN. 2016;5(4):61-70. [Persian] [Link]
16. Ganji Kheybari A, Diba D, Mahdavinejad M, Shahcheraghi A. Algorithmic Design of "Palekane" in order to increase efficiency of daylight in buildings. Armanshahr Archit Urban Dev. 2015;8:35-52. [Persian] [Link]
17. Mahdavinejad M. High-performance architecture: Search for future legacy in contemporary Iranian architecture. Armanshahr Archit Urban Dev. 2017;9(17):129-38. [Persian] [Link]
18. Kamran Kasmaei H, Daneshjou K, Mofidi Shemirani SM. Gilan native habitat assessment body-centered sustainable by Sachs and energy simulation software. NAQSHEJAHAN. 2017;7(2):58-77. [Persian] [Link]
19. Hood SD, Mahmoodi Zarandi M, Kamyabi S. Optimal placement of shadow tools of double-skin facade with the aim of achieving thermal comfort in hot climate. NAQSHEJAHAN. 2018;8(3):171-7. [Persian] [Link]
20. Knippers J, Nickel K, Speck T, editors. Biomimetic research for architecture and building construction, biological design and integrative structures. Berlin: Springer; 2016. [Link] [DOI:10.1007/978-3-319-46374-2]
21. Mahdavinejad M, Shahri Sh. Contemporization of Tehran Traditional architecture by parametric algorithm. HOVIATSHAHR. 2015;8(20):35-48. [Persian] [Link]
22. Rahbar M, Mahdavinejad M, Bemanian M, Davaie Markazi AH, Hovestadt L. Generating synthetic space allocation probability layouts based on trained conditional-GANs. Appl Artif Intell. 2019;33(8):689-705. [Link] [DOI:10.1080/08839514.2019.1592919]
23. Azcón-Bieto J, Talón M. Fundamentosde Fisiología Vegetal [Fundamentals of plant physiology]. Barcelona: McGraw-Hill Interamericana; 2000. [Spanish] [Link]
24. Ahmad H, Sehgal S, Mishra A, Gupta R. Mimosa pudica L. (Laajvanti): An overview. Pharmacogn Rev. 2012;6(12):115-24. [Link] [DOI:10.4103/0973-7847.99945]
25. Johnson K, Narasimhan G, Krishnan C. Mimosa pudica Linn-a shyness princess: A review of its plant movement, active constituents, uses and pharmacological activity. Int J Pharm Sci Res. 2014;5(12):5104-18. [Link]
26. Sanaye MM, Joglekar CS, Pagare NP. Mimosa- A brief overview. J Pharmacogn Phytochem. 2015;4(2):182-7. [Link]
27. Gage G. Electrical experiments with plants that count and communicate [Internet]. New York: TED; 2017 [cited 2020 September 8]. Available from: https://bit.ly/2Fkq0UY [Link]
28. De Luccia T. Mimosa pudica, dionaea muscipula and anesthetics. Plant Signal Behav. 2012;7(9):1163-7. [Link] [DOI:10.4161/psb.21000]
29. Schleicher S, Lienhard J, Poppinga S, Speck T, Knippers J. A methodology for transferring principles of plant movements to elastic systems in architecture. Comput Aided Des. 2015;60:105-17. [Link] [DOI:10.1016/j.cad.2014.01.005]
30. Mahdavinejad M, Refalian G. Parametric algorithms for unity of architecture and construction. Iran Sci Assoc Archit Environ Des. 2011;2(2):61-7. [Persian] [Link]
31. Joseph B, George J, Mohan J. Pharmacology and traditional uses of Mimosa pudica. Int J Pharm Sci Drug Res. 2013;5(2):41-4. [Link]
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