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Abstract

The selection of an appropriate geometric form is one of the critical factors in the design of space frame structures. Historically, the domes and arches in Iranian architectural monuments represent remarkable technical achievements, due to the geometric potential of their arched designs. However, previous studies on these structures have mainly concentrated on rehabilitation initiatives. This research, for the first time, seeks to use the formal features of arches and domes of traditional Iranian architecture to enhance contemporary structures made of modern materials. By incorporating the advantages of these historical arches into the design of lattice space domes, structural efficiency, and material utilization are anticipated to improve. To achieve this, the geometry of diamatic single-layer domes was designed based on seven commonly used arch types in traditional Iranian architecture. In addition, a diamatic dome is also modeled based on the spherical arch, which is commonly employed in space domes. The geometry of these space domes was first modeled in AutoCAD software. Then, the models were analyzed using the linear elastic method. Finally, the structural design of these space domes was performed using the LRFD method in SAP2000 software. The comparative analysis and design results demonstrate that arches such as Se-Bakhshi, Panj-O-Haft, Hasht-O-Panj, Se-Ghesmati, and Shakhbozi enable covering the same span with reduced material usage. Additionally, arches like Patopa and Shabdari offer the potential to construct taller domes with nearly equivalent material requirements.

Keywords

Space frame structures lattice space domes Iranian arches geometric design diamatic domes

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References

Coutinho

. A genetic algorithm for topology optimization of dome structures. In: 2nd international conference on engineering optimization, Lisbon, Portugal, 6–9 September 2010. Lisbon: Univessidade de Lisboa.

Kamyab Moghadas

Salajegheh

. Size optimization of nonlinear scallop domes by an enhanced particle swarm algorithm. Int J Civ Eng 2013; 11(2): 77–89.

Seyedpoor

Salajegheh

, et al Optimal design of arch dams subjected to earthquake loading by a combination of simultaneous perturbation stochastic approximation and particle swarm algorithms. Appl Soft Comput 2011; 11(1): 39–48.

Guided genetic algorithm for dome optimization against instability with discrete variables. J Constr Steel Res 2017; 139: 149–156.

Tooranpoor

Ebrahimi

. Comparative study to comprehend the characteristics of Iranian and Turkish arches and vaults from 6000 BC to AD 1000 (pre-Islamic to early Islam). Archaeol Bulg 2024; 2: 41–70.

Khodadadi

Nooshin

Bozorgmehri

, et al Modern lattice domes based on the traditional Iranian masonry domes. Int J Space Struct 2012; 27: 231–246.

Aghdam

Saad

Azab

, et al Deformability of single layer diamatic space frame Domes under non-symmetrical snow load and earthquake shaking. Results Eng 2023; 17: 100884.

Hejazi

Pourabedin

. Performance of Persian brick masonry discontinuous double-shell domes against earthquakes. Eng Fail Anal 2021; 119: 104994.

Pavlovic

Reccia

Cecchi

. A procedure to investigate the collapse behavior of masonry domes: some meaningful cases. Int J Archit Heritage 2016; 10(1): 67–83.

10.

Jaiswal

Tupe

. Analysis of geodesic dome structure. Int Res J Eng Technol 2022; 9(6): 3517.

11.

Abraham

Chandran

. Study of dome structures with specific focus on monolithic and geodesic domes for housing. Int J Emerging Technol and Adv Eng 2016; 6(8): 173–182.

12.

Efstathiadis

Symeonidou

Tzimtzimis

, et al Parametric design and mechanical characterization of a selective laser sintering additively manufactured biomimetic ribbed dome inspired by the chorion of lepidopteran eggs. Biomimetics 2024; 10(1): 1.

13.

Feizolahbeigi

Ramirez

Lourenço

. Seismic assessment of a dome structure with minarets as secondary elements: the case of Soltaniyeh dome in Iran. Structures 2024; 63: 106408.

14.

Nodargi

Bisegna

. Collapse capacity of masonry domes under horizontal loads: a static limit analysis approach. Int J Mech Sci 2021; 212: 106827.

15.

Çarbaş

Saka

. A harmony search algorithm for optimum topology design of single layer Lamella domes. In: Topping

BHV

Papadrakakis

(eds) Proceedings of the ninth international conference on computational structures technology. Stirlingshire, Scotland: Civil-Comp Press, 2008, Paper ID:50.

16.

Çarbaş

. Optimum topological design of geometrically nonlinear single layer lamella domes using harmony search method. MSc. Dissertations & Theses. Middle East Technical University, Ankara-Turkey, 2008.

17.

Çarbaş

Saka

. Optimum design of single layer network domes using harmony search method. Asian J Civ Eng 2009; 10(1): 97–112.

18.

Çarbaş

Saka

. Optimum topology design of various geometrically nonlinear latticed domes using improved harmony search method. Struct Multidisc Optim 2012; 45: 377–399.

19.

Çarbaş

. Artificial bee colony based optimum design of reticulated domes to LRFD-AISC. In: Proceedings of 27th the IIER international conference, St. Petersburg, Russia, 5 June 2015. India: International Institute of Engineers and Researchers-TheIIER.

20.

Carbas

Artar

. Comparative seismic design optimization of spatial steel dome structures through three recent metaheuristic algorithms. Front Struct Civ Eng 2022; 16: 57–74.

21.

Veladi

Beig Zali

. Optimum design of single-layer dome structures using a hybrid charged system search and teaching-learning-based optimization. Int J Optim Civ Eng 2021; 11(3): 497–513.

22.

Abdollahi

Poursha

Abedi

. Seismic response modification factors of single-layer diamatic dome structures. Eng Struct 2024; 310: 118091.

23.

Aminkhani

Basim

Abedi

. The effects of mechanical imperfections on the stability behavior of double-layer Scallop domes. Structures 2024; 69:107311.

24.

Alizadeh

Shekastehband

. Wind-induced instability analysis of large-span single-layer lattice domes, Thin-Walled Struct 2022; 181: 110109.

25.

Jafarzadeh

Poursha

Abedi

. Seismic design parameters of double-layer diamatic domes. Soil Dyn Earthquake Eng 2024; 186: 108951.

26.

Raeeszadeh

Mofid

. Revival of forgotten arts: principles of traditional architecture in Iran, narrated by Master Hossein Lorzadeh. 6th ed. Tehran, Iran: Mowla Publications, 2019.

27.

Zomorshidi

. Arches and vaults in Iranian architecture. 1st ed. Tehran, Iran: Iran Urban Development and Revitalization Corporation, 2008.

28.

Godard

. Athar-e iran. 1st ed. Paris, France: Iranian Archaeological Service, 1936, p.188.

29.

Vazna

Zarrin

. Sensitivity analysis of double layer Diamatic dome space structure collapse behavior. Eng Struct 2020; 212: 110511.

30.

ASCE/SEI. Minimum design loads and associated criteria for buildings and other structures. 7–22 ed. Reston, VA: American Society of Civil Engineers/Structural Engineering Institute, 2022.

31.

Standard

. Iranian code of practice for seismic resistant design of buildings, standard no. 2800. 4th Revision ed. IR 2800 Standard. Tehran, Iran: Building and Housing Research Center, 2016.

32.

AISC. Specification for structural steel buildings (AISC 360-22). Chicago: American Institute of Steel Construction, 2022.

Evaluation of traditional Iranian architectural arcs for optimum geometry design of single-layer diamatic lattice space domes

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