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Membrane Structures with Half-Costa Surface in YZ-Plane

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Abstract:

This paper presents the computational form-finding analysis of half-Costa tensioned membrane structure model in YZ-plane with different boundaries. The computational form-finding analysis is carried out based on nonlinear analysis method. The tensioned membrane structure in the form of half-Costa models in YZ-plane with different geometry have been found to converge with least square error of total warp and fill stress deviation. The outcome of this paper can serve as a reference in selecting satisfactory parameters to allow the performance increase of tensioned membrane structure in the form of half-Costa in YZ-plane respected to their boundary condition. These models will be selective forms of tensioned membrane structure for design engineers and architect to ponder on as it is a resource efficient structure hence preventing further damage to the environment.

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Frontiers of Composite Materials IV

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Periodical:

Materials Science Forum (Volume 995)

Pages:

222-228

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.995.222

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Online since:

June 2020

Authors:

Hooi Min Yee*, Abdul Malek Nurul Afiqah

Keywords:

Form-Finding, Half-Costa, Least Square Error, Nonlinear Analysis Method, Tensioned Membrane Structure

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© 2020 Trans Tech Publications Ltd. All Rights Reserved

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[1] B. Philipp, R. Wüchner and K.U. Bletzinger. Advances in the form-finding of structural membranes. Procedia Engineering, 155 (2016), pp.332-341.

DOI: 10.1016/j.proeng.2016.08.036

[2] J. Lipkovski and A. Lipkovski, Form-finding software and minimal surface equation: A comparative approach. Filomat, 29(10) (2015), pp.2447-2455.

DOI: 10.2298/fil1510447l

[3] H.M. Yee: A Computational Strategy for Form-Finding of Tensioned Fabric Structures using Nonlinear Analysis Method. PhD Thesis, Universiti Sains Malaysia, School of Civil Engineering, Nibong Tebal (2011).

DOI: 10.30880/jsmbe.2021.01.01.003

[4] H.M. Yee, K.K. Choong and J.Y. Kim: Form-Finding Analysis of Tensioned Fabric Structures using Nonlinear Analysis Method, Advanced Materials Research, 243-249 (2011), pp.1429-1434.

DOI: 10.4028/www.scientific.net/amr.243-249.1429

[5] H.M. Yee, J.Y. Kim and M. Mohd Noor: Tensioned fabric structures in oval form. Applied Mechanics and Materials, 405-408 (2013), pp.1008-1011.

DOI: 10.4028/www.scientific.net/amm.405-408.1008

[6] M. Mohd Noor, H.M. Yee, K.K. Choong and H. Abdul Hamid: Tensioned membrane structures in the form of egg shape. Applied Mechanics and Materials, 405-408 (2013), pp.989-992.

DOI: 10.4028/www.scientific.net/amm.405-408.989

[7] H.M. Yee and K.K. Choong: Form-finding of tensioned fabric structure in the shape of Möbius Strip. Iranica Journal of Energy & Environment 4 {(3) Geo-hazards and Civil Engineering)} (2013), pp.251-257.

DOI: 10.5829/idosi.ijee.2013.04.03.11

[8] H.M. Yee and M.A. Samsudin: Development and investigation of the Moebius Strip in tensioned membrane structures. WSEAS Transactions on Environment and Development, 10 (2014), pp.145-149.

[9] H.M. Yee and M.A. Samsudin: Mathematical and Computational Analysis of Moebius Strip, International Journal of Mathematics and Computers in Simulation, 8 (2014), pp.197-201.

[10] H.M. Yee, H. Abdul Hamid and M. Abdul Hadi: Computer investigation of tensioned fabric structure in the form of Enneper minimal surface. Applied Mechanics and Materials, 754-755 (2015), pp.743-746.

DOI: 10.4028/www.scientific.net/amm.754-755.743

[11] H.M. Yee, K.K. Choong and M. Abdul Hadi: Sustainable development of tensioned fabric green structure in the form of Enneper. International Journal of Materials, Mechanics and Manufacturing, 3 (2) (2015), pp.125-128.

DOI: 10.7763/ijmmm.2015.v3.180

[12] H.M. Yee and M. Abdul Hadi: Tensioned fabric structures with surface in the form of Chen-Gackstatter and Monkey Saddle. International Journal of Structural and Civil Engineering Research, 4 (4) (2015), pp.331-335.

DOI: 10.18178/ijscer.4.4.331-335

[13] M. Abdul Hadi, H.M. Yee, K. Abd Ghani and H. Abdul Hamid: Architectural tensioned fabric structure in Monkey Saddle form. International Journal of Control Theory and Applications, 9 (6) (2016), pp.2753-2758.

[14] M.H. Wan Ibrahim, M.N. Abdul Hadi and H.M. Yee: Form-Finding Using Nonlinear Analysis Method in Tensioned Fabric Structure in The Form of Handkerchief Surface, Journal of Physics, 995 (2018), pp.1-9.

DOI: 10.1088/1742-6596/995/1/012014

[15] H.M. Yee, A.P. Norman, A. Azura, N. Hamzah, N.I. Zainuddin and M.I.F. Rozli: Computational Form-Finding Analysis in the Shape of Bour's, WSEAS Transactions on Applied and Theoretical Mechanics, 13 (2018), pp.140-149.

[16] M.H. Wan Ibrahim, M.N. Abdul Hadi and H.M. Yee: Form-Finding of Thomsen Surface Using Nonlinear Analysis Method, Journal of Physics, 995 (2018), pp.1-8.

DOI: 10.1088/1742-6596/995/1/012017

[17] H.M. Yee and M.N. Abdul Hadi: Form-Finding with and without Cable Reinforced Thomsen Surface in Tensioned Fabric Structure, Journal of Physics, 1174 (2019), pp.1-7.

DOI: 10.1088/1742-6596/1174/1/012007

[18] N.E.A. Cunningham: Variational approach to the local uniqueness of minimal surfaces immersed in R(3). Computational and Applied Mathematics. Houston, Texas: A Bell & Howell Information Company (1998).

[19] E. Weisstein, (2017, March 17). MathWorld. Retrieved March 22, 2017, from Wolfram Mathworld: http://mathworld.wolfram.com.

DOI: 10.3888/tmj.10.3-3

[20] R. Wagner: Kinematics in Tensioned Structures. (O. Eugino, & B. KrÖplin, Eds.) Dordrecht: Springer Netherlands (2008).

[21] H.M. Yee and K.K. Choong: A computational mechanics using nonlinear analysis method in tensioned fabric structures. International Journal of Mechanics, 10 (2016), pp.261-265.