[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/sem.2015.56.5.707

Robust optimization of reinforced concrete folded plate and shell roof structure incorporating parameter uncertainty

Bhattacharjya, Soumya (Department of Civil Engineering, Indian Institute of Engineering Science and Technology)
Chakrabortia, Subhasis (Department of Civil Engineering, Indian Institute of Engineering Science and Technology)
Dasb, Subhashis (Department of Civil Engineering, Indian Institute of Engineering Science and Technology)

Publication Information

Structural Engineering and Mechanics / v.56, no.5, 2015 , pp. 707-726 More about this Journal

Abstract

There is a growing trend of considering uncertainty in optimization process since last few decades. In this regard, Robust Design Optimization (RDO) scheme has gained increasing momentum because of its virtue of improving performance of structure by minimizing the variation of performance and ensuring necessary safety and feasibility of constraint under uncertainty. In the present study, RDO of reinforced concrete folded plate and shell structure has been carried out incorporating uncertainty in the relevant parameters by Monte Carlo Simulation. Folded plate and shell structures are among the new generation popular structures often used in aesthetically appealing constructions. However, RDO study of such important structures is observed to be scarce. The optimization problem is formulated as cost minimization problem subjected to the force and displacements constraints considering dead, live and wind load. Then, the RDO is framed by simultaneously optimizing the expected value and the variation of the performance function using weighted sum approach. The robustness in constraint is ensured by adding suitable penalty term and through a target reliability index. The RDO problem is solved by Sequential Quadratic Programming. Subsequently, the results of the RDO are compared with conventional deterministic design approach. The parametric study implies that robust designs can be achieved by sacrificing only small increment in initial cost, but at the same time, considerable quality and guarantee of the structural behaviour can be ensured by the RDO solutions.

Keywords

robust design optimization; Monte Carlo simulation; folded plate structure; reinforced concrete shell; target reliability; parameter uncertainty;

Citations & Related Records

Times Cited By KSCI : 10 (Citation Analysis)

Reference
Cited By KSCI

1	Deb, K., Pratap, A., Agarwal, S. and Meyariva, T. (2002), "A fast and elitist multi-objective genetic algorithm: NSGA-II", IEEE Tran. Evol. Comput., 6(2), 182-197. DOI
2	Debbarma, R. and Chakraborty, S. (2015), "Robust design of liquid column vibration absorber in seismic vibration mitigation considering random system parameter", Struct. Eng. Mech., 53(6), 1127-1141 DOI
3	Doltsinis, I., Kang, Z. and Cheng, G. (2005), "Robust design of non-linear structures using optimization methods", Comput. Meth. Appl. Mech. Eng., 194(12-16), 1779-1795. DOI
4	Du, X. and Chen, W. (2000), "Towards a better understanding of modeling feasibility robustness in engineering design", ASME J. Mech. Des., 122(4), 385-394. DOI
5	Elishakoff, I. and Ren, Y. (2003), Finite Element Methods for Structures with Large Stochastic Variations, Oxford University Press, New York.
6	Ellingwood, B.R., Galambos, T.V., MacGregor, J.G. and Cornell, C.A. (1980), "Development of probability based load criterion for American National Standard A 58", NBS Special Publication 577, U.S. Department of Commerce, Washington, DC.
7	Ghosh, R., Chakraborty, S. and Bhattacharyya, B. (2001), "Stochastic sensitivity analysis of structures using first-order perturbation", 36, 291-296. DOI
8	Gunawan, S. and Azarm, S. (2005), "Multi-objective robust optimization using a sensitivity region concept", Struct. Multidisc. Optim., 29(1), 50-60. DOI
9	Hinton, E., O zakca, M. and Rao, N.V.R. (1995), "Free vibration analysis and shape optimization of variable thickness prismatic folded plates and curved shells Part I:finite strip formulation", J. Sound Vib., 181(4), 553-556. DOI
10	Hirschen, K. and Schafer, M. (2006), "A study on evolutionary multi-objective optimization for flow geometry design", Comput. Mech., 37, 131-141. DOI
11	Huang, B. and Du, X. (2007), "Analytical robustness assessment for robust design", Struct. Multidisc. Optim., 34(2), 123-137. DOI
12	IS 456 (2000), Plain And Reinforced Concrete - Code Of Practice Is An Indian Standard Code Of Practice For General Structural Use Of Plain And Reinforced Concrete, BIS, India.
13	IS 875, Part 3 (1987), Code Of Practice For Design Loads (Other Than Earthquake) For Buildings And Structures, Part 3: Wind Loads (Second Revision), BIS, India.
14	IS 2210 (1988), Criteria for Design of Reinforced Concrete Shell Structure and Folded Plates, BIS, India.
15	Kaveh, A., Bakhshpoori, T. and Afshari, E. (2015), "Hybrid PSO and SSO algorithm for truss layout and size optimization considering dynamic constraints", Struct. Eng. Mech., 54(3), 453-474 DOI
16	Kouchakzadeh, M.A. and Shakouri, M. (2015), "Analytical solution for axisymmetric buckling of joined conical shells under axial compression", Struct. Eng. Mech., 54(4), 649-664. DOI
17	Kripka, M. and Pravia, Z.M.C. (2013), "Cold-formed steel channel columns optimization with simulated annealing method", Struct. Eng. Mech., 48(3), 383-394. DOI
18	Kutylowski, R. and Rasiak, B. (2014), "Application of topology optimization to bridge girder design", Struct. Eng. Mech., 51(1), 39-66. DOI
19	Lakshmy, T.K. and Bhavikatti, S.S. (1995), "Optimum design of trough type folded plate roofs", Comput. Struct., 57(1), 125-130 DOI
20	Lakshmi, K. and Rao, A.R.M. (2012), "Multi-objective optimal design of laminate composite shells and stiffened shells", Struct. Eng. Mech., 43(6), 771-794. DOI
21	Lee, K. and Park, G. (2001), "Robust optimization considering tolerances of design variable", Comput. Struct., 79(1), 77-86. DOI
22	Martinez-Martin, F., Gonzalez-Vidosa, F., Hospitaler, A. and Yepes, V. (2013), "A parametric study of optimum tall piers for railway bridge viaducts", Struct. Eng. Mech., 45(6), 723-740. DOI
23	Mautea, K., Weickuma, G. and Eldre, M. (2009), "A reduced-order stochastic finite element approach for design optimization under uncertainty", Struct. Saf., 31(6), 450-459. DOI
24	Meng, Z., Peng, H., Li, G., Wang, B. and Zhang, K. (2015), "Non-probabilistic reliability-based design optimization of stiffened shells under buckling constraint", Thin Wall. Struct., 94, 325-333. DOI
25	Messac, A. and Ismail-Yahaya, A. (2002), "Multi objective robust design using physical programming", Struct. Multidis. Optim., 23(5), 357-371. DOI
26	Milasinovic, D.D. and Goles, D. (2012), "Finite strip modeling for optimal design of reinforced concrete folded plate structures", J. FACTA Universitatis, Series: Arch. Civil Eng., 10(3), 275-290. DOI
27	Papadopoulos, V. and Lagaros, N.D. (2009), "Vulnerability-based robust design optimization of imperfect shell structures", Struct. Saf. Optim. Uncert. Emph. Struct. Appl., Special Issue: Optimization, 31(6), 475-482
28	Pareto, V. (1906), "Manuale di Economica Politica", Societa Editrice Libraria, Milan, translated into English by A.S. Schwier as Manual of Political Economy, Eds. A.S. Schwier and A.N. Page, New York.
29	Sheikhi, M. and Ghoddosian, A. (2013), "A hybrid imperialist competitive ant colony algorithm for optimum geometry design of frame structures", Struct. Eng. Mech., 46(3), 403-416. DOI
30	Park, G.J., Lee, T.H., Lee, K. and Hwang, K.H. (2006), "Robust design: an overview", AIAA J., 44(1), 181-191. DOI
31	Sundaresan, S., Ishii, K. and Houser, D.R. (1995), "A robust optimization procedure with variations on design variables and constraints", Eng. Optim., 24(2), 101-117. DOI
32	Taguchi, G. (1993), On Robust Technology Development, Bringing Quality Engineering Upstream, ASME Press, New York.
33	Tejani, A. and Parikh, A.A. (2013), "Computer-aided wind load analysis on reinforced concrete folded plate", J. PARIPEX-Ind. J. Res., 3(4), 87-90.
34	Tomas, A. and Marti, P. (2010), "Shape and size optimisation of concrete shells", Eng. Struct, 32(6), 1650-1658. DOI
35	Varghese, P.C. (2013), Design of Reinforced Concrete Shells and Folded Plates, PHI Learning Pvt. Ltd., India.
36	Velimirovic, L., Radivojevic, G. and Kostic, D. (1998), "Analysis of hyperbolic paraboloids at small deformations", Sci. J. Facta Univ., Series: Arch. Civil Eng., 1(5), 627-636.
37	Wang, L. and Kodiyalam, S. (2002), "An efficient method for probabilistic and robust design with nonnormal distributions", Proc. 43rd AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials, Denever, Colorado.
38	Wang, W.M., Peng, Y.H., Hu, J. and Cao, Z.M. (2009), "Collaborative robust optimization under uncertainty based on generalized dynamic constraints network", Struct. Multidisc. Optim., 38(2), 159-170. DOI
39	Zang, C., Friswell, M.I. and Mottershead, J.E. (2005), "A review of robust optimal design and its application in dynamics", Comput. Struct., 83(4-5), 315-326. DOI
40	Wu, J., Lu, X.Y., Li, S.C., Zhang, D.L., Xu, Z.H., Li, L.P. and Xue, Y.G. (2015), "Shape optimization for partial double-layer spherical reticulated shells of pyramidal system", Struct. Eng. Mech., 55(3), 555-581. DOI
41	Bertagnoli, G., Giordano, L. and Mancini, S. (2013), "Skew reinforcement optimization in concrete shells subject to uncertain loading conditions", Proceedings of the Third International Conference on Soft Computing Technology in Civil, Structural and Environmental Engineering, Ed. Y. Tsompanakis, Civil-Comp Press, Stirlingshire, UK.
42	Abbasnia, R., Shayanfar, M. and Khodam, A. (2014), "Reliability-based design optimization of structural systems using a hybrid genetic algorithm", Struct. Eng. Mech., 52(6), 1099-1120. DOI
43	Bar-Yoseph, P. and Hersckovitz, I. (1989), "Analysis of folded plate structures", Thin Wall. Struct., 7(2), 139-158. DOI
44	Bergamini, A. and Biondini, F. (2004), "Finite strip modelling for optimal design of pre-stressed folded plate structures", J. Eng. Struct., 26(8), 1043-1054. DOI
45	Beyer, H. and Sendhoff, B. (2007), "Robust optimization- a comprehensive survey", Comput. Meth. Appl. Mech. Eng., 196(33-34), 3190-3218. DOI
46	Bhattacharjya, S. (2010), "Robust optimization of structure under uncertainty", PhD Dissertation, Bengal Engineering and Science University, Shibpur, India.
47	Bhattacharjya, S. and Chakraborty, S. (2011), "Robust optimization of structures subjected to stochastic earthquake with limited information on system parameter uncertainty", Eng. Optim., 43(12), 1311-1330. DOI
48	Chakraborty, S., Bhattacharjya, S. and Halder, A. (2012), "Sensitivity importance-based robust optimization of structures with incomplete probabilistic information", Int. J. Numer. Meth. Eng., 90(10), 1207-1320. DOI
49	Chen, W., Sahai, A., Messac, A. and Sundararaj, G. J. (2000), "Exploration of the effectiveness of physical programming in robust design", ASME J. Mech. Des., 122 (2), 155-162. DOI

	Xuyong Chen. (2017) Results in Physics Structural robust optimization design based on convex model / 7 , 3068
3	(2015) Geomechanics & engineering Spatial variability analysis of soil strength to slope stability assessment / 12 (3) , 483
4	(2015) Structural engineering and mechanics : An international journal DOProC-based reliability analysis of structures / 64 (4) , 413
6	(2018) Computers & concrete Modern computer simulation for the design of concrete catenary shell structures / 21 (6) , 661
6	(2019) Computers & concrete An efficient robust cost optimization procedure for rice husk ash concrete mix / 23 (6) , 433