Reliability is an important engineering requirement for consistently delivering acceptable product performance through time. As time progresses, the product may fail due to time phenomena such as time-dependent operating conditions, component degradation, etc. The degradation of reliability with time may increase the lifecycle cost due to potential warranty costs, repairs, and loss of market share, affecting the sustainability of environmentally friendly products. In the design for lifecycle cost, we must account for product quality and time-dependent reliability. Quality is a measure of our confidence that the product conforms to specifications as it leaves the factory. Quality is time independent, and reliability is time dependent. This article presents a design methodology to determine the optimal design of time-dependent multiresponse systems by minimizing the cost during the life of the product. The conformance of multiple responses is treated in a series-system fashion. The lifecycle cost includes a production, an inspection, and an expected variable cost. All costs depend on quality and/or reliability. The key to our approach is the calculation of the so-called system cumulative probability of failure. For that, we use an equivalent time-invariant “composite” limit state and a niching genetic algorithm with lazy learning metamodeling. A two-mass vibratory system example and an automotive roller clutch example demonstrate the calculation of the cumulative probability of failure and the design for lifecycle cost.
1.
Zhao
, Y.
, Pandey
, V.
, Kim
, H.
, and Thurston
, D.
, 2009, “Varying Lifecycle Lengths Within a Portfolio for Product Take-Back
,” Proceedings of the ASME International Design Engineering Conferences
, San Diego, CA, Paper No. DETC2009-87625.2.
Mangun
, D.
, and Thurston
, D. L.
, 2002, “Incorporating Component Reuse, Remanufacture and Recycle Into Product Portfolio Design
,” IEEE Trans. Eng. Manage.
0018-9391, 49
(4
), pp. 479
–490
.3.
Geyer
, R.
, Van Wassenhove
, L. N.
, and Atasu
, A.
, 2007, “The Economics of Remanufacturing Under Limited Component Durability and Finite Product Life Cycles
,” Manage. Sci.
0025-1909, 53
(1
), pp. 88
–100
.4.
Srivastava
, S. K.
, 2007, “Green Supply-Chain Management: A State-of-the-Art Literature Review
,” Int. J. Manage. Rev.
1468-2370, 9
(1
), pp. 53
–80
.5.
Tu
, J.
, Choi
, K. K.
, and Park
, Y. H.
, 1999, “A New Study on Reliability-Based Design Optimization
,” ASME J. Mech. Des.
0161-8458, 121
(4
), pp. 557
–564
.6.
Du
, X.
, Sudjianto
, A.
, and Huang
, B. Q.
, 2005, “Reliability-Based Design With a Mixture of Random and Interval Variables
,” ASME J. Mech. Des.
0161-8458, 127
(6
), pp. 1068
–1076
.7.
Liang
, J.
, Mourelatos
, Z. P.
, and Nikolaidis
, E.
, 2007, “A Single-Loop Approach for System Reliability-Based Design Optimization
,” ASME J. Mech. Des.
0161-8458, 129
(12
), pp. 1215
–1224
.8.
McDonald
, M.
, and Mahadevan
, S.
, 2008, “Design Optimization With System-Level Reliability Constraints
,” ASME J. Mech. Des.
0161-8458, 130
(2
), pp. 021403
.9.
Du
, X.
, 2008, “Saddlepoint Approximation for Sequential Optimization and Reliability Analysis
,” ASME J. Mech. Des.
0161-8458, 130
(1
), pp. 011011
.10.
Kuschel
, N.
, and Rackwitz
, R.
, 2000, “Optimal Design Under Time-Variant Reliability Constraints
,” Struct. Safety
0167-4730, 22
(2
), pp. 113
–127
.11.
Streicher
, H.
, and Rackwitz
, R.
, 2004, “Time-Variant Reliability-Oriented Structural Optimization and a Renewal Model for Life-Cycle Costing
,” Probab. Eng. Mech.
0266-8920, 19
(1–2
), pp. 171
–183
.12.
Savage
, G. J.
, and Carr
, S. M.
, 2002, “Interrelating Quality and Reliability in Engineering Systems
,” Qual. Eng.
0898-2112, 14
(1
), pp. 137
–152
.13.
Savage
, G. J.
, and Son
, Y. K.
, 2009, “Dependability-Based Design Optimization of Degrading Engineering Systems
,” ASME J. Mech. Des.
0161-8458, 131
, p. 011002
.14.
Andrieu-Renaud
, C.
, Sudret
, B.
, and Lemaire
, M.
, 2004, “The PHI2 Method: A Way to Compute Time-Variant Reliability
,” Reliab. Eng. Syst. Saf.
0951-8320, 84
(1
), pp. 75
–86
.15.
Monga
, A.
, and Zuo
, M. J.
, 1998, “Optimal System Design Considering Maintenance and Warranty
,” Comput. Oper. Res.
0305-0548, 25
(9
), pp. 691
–705
.16.
Wang
, Z. L.
, Du
, X.
, and Huang
, H. Z.
, 2008, “Reliability-Based Lifecycle Optimization With Maintenance Consideration
,” 14th ISSAT Conference on Reliability and Quality in Design
, Orlando, FL, Aug. 7–9.17.
Wang
, Z.
, Huang
, H. Z.
, and Du
, X.
, 2010, “Optimal Design Accounting for Reliability, Maintenance, and Warranty
,” ASME J. Mech. Des.
0161-8458, 132
(1
), pp. 011007
.18.
Rackwitz
, R.
, 1998, “Computational Techniques in Stationary and Non-Stationary Load Combination—A Review and Some Extensions
,” J. Struct. Eng.
0733-9445, 25
(1
), pp. 1
–20
.19.
Royset
, J. O.
, Der Kiureghian
, A.
, and Polak
, E.
, 2006, “Optimal Design With Probabilistic Objectives and Constraints
,” J. Eng. Mech.
0733-9399, 132
(1
), pp. 110
–118
.20.
Son
, Y. K.
, and Savage
, G. J.
, 2007, “Set Theoretic Formulation of Performance Reliability of Multiple Response Time-Variant Systems Due to Degradations in System Components
,” Qual. Reliab. Eng. Int.
, 23
(2
), pp. 171
–188
.21.
Chou
, C. Y.
, and Chen
, C. H.
, 2001, “On the Present Worth of Multivariate Quality Loss
,” Int. J. Prod. Econ.
0925-5273, 70
, pp. 279
–288
.22.
Son
, Y. K.
, Chang
, S. W.
, and Savage
, G. J.
, 2007, “Economic-Based Design of Engineering Systems With Degrading Components Using Probabilistic Loss of Quality
,” J. Mech. Sci. Technol.
1738-494X, 21
(2
), pp. 225
–234
.23.
Frangopol
, D. M.
, and Maute
, K.
, 2003, “Life-Cycle Reliability-Based Optimization for Civil and Aerospace Structures
,” Comput. Struct.
0045-7949, 81
, pp. 397
–410
.24.
Rackwitz
, R.
, and Fiessler
, B.
, 1978, “Structural Reliability Under Combined Random Load Sequences
,” Comput. Struct.
0045-7949, 9
(5
), pp. 489
–494
.25.
Zhao
, Y.
, and Ono
, T.
, 1999, “A General Procedure for First/Second-Order Reliability Method (FORM/SORM)
,” Struct. Safety
0167-4730, 21
(2
), pp. 95
–112
.26.
Cornell
, C. A.
, 1967, “Bounds on the Reliability of Structural Systems
,” J. Struct. Div.
0044-8001, 93
(ST1
), pp. 171
–200
.27.
Ditlevsen
, O.
, 1979, “Narrow Reliability Bounds for Structural Systems
,” J. Struct. Mech.
0360-1218, 7
(4
), pp. 453
–472
.28.
Bucher
, C. G.
, 1988, “Adaptive Sampling—An Iterative Fast Monte Carlo Procedure
,” Struct. Safety
0167-4730, 5
, pp. 119
–126
.29.
Cazuguel
, M.
, Renaud
, C.
, and Cognard
, J. Y.
, 2006, “Time-Variant Reliability of Nonlinear Structures: Application to a Representative Part of a Plate Floor
,” Qual. Reliab. Eng. Int.
0748-8017, 22
, pp. 101
–118
.30.
Hagen
, O.
, and Tvedt
, L.
, 1991, “Vector Process Out-Crossing as Parallel System Sensitivity Measure
,” J. Eng. Mech.
0733-9399, 117
(10
), pp. 2201
–2220
.31.
Ditlevsen
, O.
, and Madsen
, H. O.
, 1996, Structural Reliability Methods
, Wiley
, New York
.32.
Shinozuka
, M.
, 1964, “Probability of Failure Under Random Loading
,” J. Eng. Mech.
0733-9399, 90
, pp. 147
–171
.33.
Engelung
, S.
, Rackwitz
, R.
, and Lange
, C.
, 1995, “Approximations of First Passage Times for Differentiable Processes Based on Higher Order Threshold Crossings
,” Probab. Eng. Mech.
0266-8920, 10
(1
), pp. 53
–60
.34.
Schueller
, G. I.
, 1997, “A State-of-the-Art Report on Computational Stochastic Mechanics
,” Probab. Eng. Mech.
0266-8920, 12
(4
), pp. 197
–321
.35.
Sudret
, B.
, and Der Kiureghian
, A.
, 2000, “Stochastic Finite Element Methods and Reliability. A State-of-the-Art Report
,” University of California, Report No. UCB/SEMM-2000/08.36.
Aktas
, E.
, Moses
, F.
, and Ghosn
, M.
, 2001, “Cost and Safety Optimization of Structural Design Specifications
,” Reliab. Eng. Syst. Saf.
0951-8320, 73
, pp. 205
–212
.37.
Shir
, O. M.
, 2004, “Niching in Evolution Strategies
,” MS thesis, Leiden University, Netherlands.38.
Li
, J.
, and Mourelatos
, Z. P.
, 2009, “Time-Dependent Reliability Estimation for Dynamic Problems Using a Niching Genetic Algorithm
,” ASME J. Mech. Des.
0161-8458, 131
(7
), p. 071009
.39.
Aha
, D. W.
, 1997, “Editorial - Lazy Learning
,” Artif. Intell. Rev.
0269-2821, 11
(1–5
), pp. 1
–6
.40.
Atkeson
, C. G.
, Moore
, A. W.
, and Schaal
, S.
, 1997, “Locally Weighted Learning
,” Artif. Intell. Rev.
0269-2821, 11
(1–5
), pp. 11
–73
.41.
Birattari
, M.
, Bontempi
, G.
, and Bersini
, H.
, 1999, “Lazy Learning Meets the Recursive Least-Squares Algorithm
,” Advances in Neural Information Processing Systems 11
, M. S.
Kearns
, S. A.
Solla
, and D. A.
Cohn
, eds., MIT
, Cambridge, MA
, pp. 375
–381
.42.
Goldberg
, D. E.
, and Richardson
, J.
, 1987, “Genetic Algorithms With Sharing for Multimodal Function Optimization
,” Proceedings of the Second International Conference on Genetic Algorithms on Genetic Algorithms and Their Application
, pp. 41
–49
.43.
Singh
, A.
, Mourelatos
, Z. P.
, and Li
, J.
, 2009, “Design for Lifecycle Cost Using Time-Dependent Reliability
,” Proceedings ASME International Design Engineering Conferences
, San Diego, CA, Paper No. DETC2009-86587.44.
Xue
, W.
, and Pyle
, R.
, 2004, “Optimal Design of Roller One Way Clutch for Starter Drives
,” SAE Paper No. 2004-01-1151.45.
Choi
, H. R.
, Park
, M.
, and Salisbury
, E.
, 2000, “Optimal Tolerance Allocation With Loss Functions
,” ASME J. Manuf. Sci. Eng.
1087-1357, 122
, pp. 529
–535
.Copyright © 2010
by American Society of Mechanical Engineers
You do not currently have access to this content.
