论文信息 - Effects of Printed Circuit Board Materials on Lead-free Interconnect Durability

Effects of Printed Circuit Board Materials on Lead-free Interconnect Durability

This study investigates the effects of printed circuit board (PCB) material on interconnect durability of lead free assemblies. The assemblies involve soldering various packages (array and peripheral) on to FR4, high glass transition temperature (Tg) FR4 and Polyimide (PI) printed circuit boards using Sn3Ag0.5Cu solder alloy. The glass transition temperature of these materials ranges from 130°C to 230°C. Thermomechanical properties, such as elastic modulus and thermal expansion coefficients, of the board materials vary considerably. These properties have a direct impact on the interconnect durability. In this paper, thermomechanical properties are experimentally determined and used for solder joint durability simulation. Two kinds of environmental loadings are simulated: temperature cycling and random vibration loading. The results show that PI board provides a better solder joint durability than FR4 and high TgFR4 under temperature cycling conditions. PI assembly has better durability than FR4 assembly under random vibration. The paper also presents the effect of temperature on the vibration response of the FR4 printed circuit board assemblies. The understanding of these changes can contribute to the study on interconnect durability under combined temperature cycling and vibration loading conditions.

[1] S. Manson. Fatigue: A complex subject—Some simple approximations , 1965 .

[2] Werner Engelmaier,et al. Solder Attachment Reliability, Accelerated Testing, and Result Evaluation , 1991 .

[3] G. Whitten. Lead-free solder implementation for automotive electronics , 2000, 2000 Proceedings. 50th Electronic Components and Technology Conference (Cat. No.00CH37070).

[4] A. Dasgupta,et al. Microthermomechanical Analysis of Lead-Free SN-3.9AG-0.6CU Alloys; Part I : Viscoplastic Constitutive Properties , 2001 .

[5] Abhijit Dasgupta,et al. Cyclic Mechanical Durability of Sn-3.9Ag-0.6Cu and Sn-3.5Ag Lead-Free Solder Alloys , 2002 .

[6] M. Osterman,et al. Plastic Ball-Grid-Arrays (PBGA): Are they ready for environmentally harsh Aerospace applications? , 2002 .

[7] L. Nguyen,et al. A structured approach to lead-free IC assembly transitioning , 2002, 27th Annual IEEE/SEMI International Electronics Manufacturing Technology Symposium.

[8] Results of comparative reliability tests on lead-free solder alloys , 2002, 52nd Electronic Components and Technology Conference 2002. (Cat. No.02CH37345).

[9] John H. Lau,et al. Design, materials and process for lead‐free assembly of high‐density packages , 2004 .

[10] Ming Xu,et al. Assessment of long-term reliability in lead-free assemblies , 2005, Proceedings of 2005 International Conference on Asian Green Electronics, 2005. AGEC..

[11] Michael Pecht,et al. Lead-free Electronics , 2006 .