Intel E6700 Mechanical Design Guidelines - Page 69

LGA775 Socket Heatsink Loading Appendix A LGA775 Socket Heatsink Loading A.1 A.2 A.3 LGA775 Socket Heatsink Considerations Heatsink clip load is traditionally used for: • Mechanical performance in mechanical shock and vibration  Refer to Section 6.7.1 for the information on the structural design strategy for the reference design • Thermal interface performance  Required preload depends on TIM  Preload can be low for thermal grease In addition to mechanical performance in shock and vibration and TIM performance, LGA775 socket requires a minimum heatsink preload to protect against fatigue failure of socket solder joints. Solder ball tensile stress is originally created when, after inserting a processor into the socket, the LGA775 socket load plate is actuated. In addition, solder joint shear stress is caused by coefficient of thermal expansion (CTE) mismatch induced shear loading. The solder joint compressive axial force (Faxial) induced by the heatsink preload helps to reduce the combined joint tensile and shear stress. Overall, the heatsink required preload is the minimum preload needed to meet all of the above requirements-Mechanical shock and vibration and TIM performance AND LGA775 socket protection against fatigue failure. Metric for Heatsink Preload for ATX/uATX Designs Non-Compliant with Intel® Reference Design Heatsink Preload Requirement Limitations Heatsink preload by itself is not an appropriate metric for solder joint force across various mechanical designs and does not take into account for example (not an exhaustive list): • Heatsink mounting hole span • Heatsink clip/fastener assembly stiffness and creep • Board stiffness and creep • Board stiffness is modified by fixtures like backing plate, chassis attach, and so forth. Thermal and Mechanical Design Guidelines 69