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Abstract
This paper presents mean fatigue lifetime prediction of a wire-bond structure model in power electronic module using a failure physics approach that integrates high fidelity modelling and reduced order modelling. Loading current with variable amplitudes is applied to a finite element model of simplified wirebond structures. The resulting accumulated fatigue damage due to random loads is predicted by using reduced order modelling based on failure physics, a cycle counting algorithm, and various nonlinear fatigue damage models widely used in the literature. The reduced order modelling approach based on failure physics uses prediction data for the electro-thermo-mechanical behaviour of the wire-bond design of a power module obtained through non-linear transient finite element simulations, in particular for the fatigue life-time of the aluminium wire attached to the silicon chip of the wire in the module. The reduced order models that capture the black box function of the accumulated plastic strain are used in predicting the mean fatigue life time of the wire bond structure under random loads. One of the widely used cycle counting algorithms, rainflow counting algorithm, is used to count cycles of the temperature profile at the specific point of the wire bond structure in a power electronic module. The cycle data from the rainflow algorithm mean life time of the wire bond structure are predicted with various cumulative fatigue models. Non-linear cumulative fatigue models such as damage curve approach (DCA), double linear damage rule (DLDR), and double damage curve approach (DDCA), and linear cumulative fatigue damage model such as Palmgren–Miner rule are used to predict the mean fatigue life of the wire bond structure, and the results are compared.
Keywords
Reduced order models
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Power module
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Kriging
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Radial basis
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Damage rule
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Pushparajah Rajaguru, Hua Lu, Chris Bailey.
Application of nonlinear fatigue damage models in power electronic module wirebond structure under various amplitude loadings.
Advances in Manufacturing, 2014, 2(3): 239-250 DOI:10.1007/s40436-014-0054-5
| [1] |
Held M, Jacob P, Nicoletti G, Scacco P, Poech MH. Fast power cycling test for insulated gate bipolar transistor modules in traction application’. Int J Electron, 1999, 86(10): 1193-1204.
|
| [2] |
Hua L, Bailey C, Yin C. Design for reliability of power electronics modules. Microelectron Reliab, 2009, 49: 1250-1255.
|
| [3] |
Ramminger S, Türkes P, Wachutka G. Crack mechanism in wire bonding joints’. Microelectron Reliab, 1998, 38: 1301-1305.
|
| [4] |
Ramminger S, Seliger N, Wachutka G. Reliability model for Al wire bonds subjected to heel crack failures. Microelectron Reliab, 2000, 40: 1521-1525.
|
| [5] |
Bielen J, Gommans JJ, Theunis F (2006) Prediction of high cycle fatigue in aluminum bond wires: a physics of failure approach combining experiments and multi-physics simulations. In: The 7th international conference on thermal, mechanical and multiphysics simulation and experiments in micro-electronics and micro-systems, 2006. EuroSime 2006. IEEE, New York, pp 1–7
|
| [6] |
Celnikier Y, Benabou L, Coquery G. Investigation of heel crack mechanism in Al connections for power electronics modules. Microelectron Reliab, 2011, 51: 965-974.
|
| [7] |
Hager C (2000) Lifetime estimation of aluminum wire bonds based on computational plasticity. Dissertation, Swiss Federal Institute of Technology, Hartung-Gorre
|
| [8] |
Van Driel WD, Van Silfhout RBR, Zhang GQ. Reliability of wirebonds in micro-electronic packages. Microelectron Int, 2008, 25(2): 15-22.
|
| [9] |
Meyyappan KN, Hansen P, McCluskey P (2003) Wire flexure fatigue model for asymmetric bond height. In: Proceedings of IPACK conference, Hawai, 2003
|
| [10] |
Shinohara K, Yu Q. Evaluation of fatigue life of semiconductor power device by power cycle test and thermal cycle test using finite element analysis. Engineering, 2010, 2: 1006-1018.
|
| [11] |
Kostandyan EE, Sorensen J. Reliability assessment of solder joints in power electronic modules by crack damage model for wind turbine applications. Energies, 2011, 4: 2236-2248.
|
| [12] |
White M (2008) Microelectronics reliability: physics-of-failure based modeling and lifetime evaluation. http://nepp.nasa.gov. Assessed 6 July 2011
|
| [13] |
Yin CY, Lu H, Musallam M et al (2008) A physics-of-failure based prognostic method for power modules. In: Electronics packaging technology conference (EPTC) 2008, Singapore. IEEE, New York, pp 1190–1195
|
| [14] |
Fatemi A, Yang L. Cumulative fatigue damage and life prediction theories: a survey of the state of the art for homogeneous materials. Int J Fatigue, 1998, 20(1): 9-34.
|
| [15] |
Miner MA. Cumulative damage in fatigue. J Appl Mech, 1945, 12(3): 159-164.
|
| [16] |
Manson SS, Halford GR. Practical implementation of the double linear damage rule and damage curve approach for treating cumulative fatigue damage. Int J Fract, 1981, 17(2): 169-192.
|
| [17] |
Manson SS, Freche JC, Ensign CR (1967) Application of a double linear damage rule to cumulative fatigue. Paper from fatigue crack propagation, ASTM STP NO 415:384–412
|
| [18] |
Halford GR. Cumulative fatigue damage modeling: crack nucleation and early growth. Int J Fatigue, 1997, 19: S253-S260.
|
| [19] |
Nikolaidis E, Ghiocel DM, Singhal S. Engineering design reliability applications: for the aerospace, automotive and ship industries, 2007, Boca Raton: CRC Press
|
| [20] |
Lu H, Loh WS, Bailey C et al (2008) Computer modelling analysis of the globtop’s effects on aluminium wirebond reliability. In: 2nd Electronics system-integration technology conference (ESTC). IEEE, New York, pp 1369–1374
|
| [21] |
ANSYS T M (2009) Academic research advanced version 12.0. ANSYS T M, Canonsburg
|
| [22] |
Khan WA, Culham JR. Modelling of cylindrical pin-fin heat sinks for electronic packaging. IEEE Trans Compon Packag Technol, 2008, 31(3): 536-545.
|
| [23] |
Holman JP. Heat transfer, 2010, 10 New York: McGraw-Hill
|
| [24] |
Lee WW, Nguyen LT, Selvaduray GS. Solder joint fatigue models: a review and applicability to chip scale packages. Microelectron Reliab, 2000, 40: 231-244.
|
| [25] |
Syed A (2004) Accumulated creep starin and energy density based thermal fatigue life prediction models for SnAgCu solder joints. In: Proceedings of the 54th electronic components and technology conference, June, 2004, pp 737–746
|
| [26] |
Matsuishi M, Endo T (1968) Fatigue of metals subjected to varying stress. In: Paper presented to Japan Society of Mechanical Engineers, Fukuoka, Japan, pp 37–40
|
| [27] |
Downing SD, Socie DF. Simple rainflow counting algorithms. Int J Fatigue, 1982, 4: 31-40.
|
| [28] |
Standard A. E1049 (1985) Standard practices for cycle counting in fatigue analysis, Philadelphia
|
| [29] |
Stoyanov S, Rajaguru P, Bailey C (2010) Reduced order modelling for reliability optimisation of advanced micro-systems. In: 2nd International conference on engineering optimization, Lisbon, Portugal, 6–9 September
|
| [30] |
Cressie N. Statistics for spatial data, 1991, New York: Wiley.
|
| [31] |
Gumerov N, Duraiswami R. Fast radial basis function interpolation via preconditioned Krylov iteration. SIAM J Sci Comput, 2007, 29(5): 1876-1899.
|
| [32] |
Wang JG, Liu GR. A point interpolation meshless method based on radial basis function. Int J Numer Methods Eng, 2002, 54: 1623-1648.
|
