The Application of Spherical Bend Testing to Predict Safe Working Manufacturing Process Strains

摘要

The increased temperatures associated with lead free processes have produced significant challenges for PWB laminates. Newly developed laminates have different curing processes, are commonly filled with ceramic particles or micro-clays and can have higher Tg values. These changes designed to reduce Z-axis expansion and improve the materials resistance to thermal excursions through primary attach and rework operations have also produced harder resin systems with reduced fracture toughness. Celestica has undertaken an extensive "Spherical Bend Test" program to assess lead (Pb) free compatible materials and area array packages. This work has confirmed "Pad crater / Pad Lift" as the dominant failure mode in Pb-free materials in agreement with observations from multiple streams of field returned product. This work discusses the multiple phases of testing and the implications for mechanical reliability of Pb-free product. The initial phase was designed to confirm or refute the established relationship between strain rate and safe working strain in Pb-free materials. The second phase studied the effect of extended thermal excursions for an extensively used standard loss laminate material. The third phase was designed to directly compare standard loss laminate materials and has confirmed the impact of filled resin systems identified by other investigators This new work seems to confirm the relationship between board thickness and safe working strain established by in IPC/JEDEC-9704: "Printed Wiring Board Strain Gage Test Publication". Data is only available for a limited number of package designs but these selected packages are believed to generate conservative strain limits for manufacturing process guidelines. The design of the most recent test plan was intended to generate data that would allow investigators to generalize the effect of package compliance on the safe working strain of the assembly by correlation of test data from multiple packages to an existing simplified mechanical model. Assembly processing, test methods and results will be documented in addition to discussion on resultant data, failure　analysis, distribution parameters. The effectiveness and predictive range possible from the simplified model will also be　discussed.