Solder Joint Reliability

Solder Joint Reliability
The solder joint reliability study will help indicate which solder type and surface finish combination provides the best mechanical strength to a system of electrical components after a series of repeated thermal shock cycles. This study will also create a finite element analysis model of solder joints in electrical components, and will model the effects of thermal cycles over time.

Sponsors
This Capstone design project is sponsored by the Micron Foundation and the Electrical Engineering Department at the University of Idaho.

Problem Statement
The focus of the project will aim towards validating the solder joint bond strength at a point between a printed circuit board (PCB) and the electronic package that would be mounted to it. Using the known strengths of the materials, performing a thermal cycle testing sequence, and measuring the force required to break the solder joint bonds will predict which solder type performs the best in electronic packaging. This will allow future electronic packages to have a longer lifespan and will reduce costs to manufacturers.

Design Goals
The goal of our design project is to design a realistic finite element simulation of electrical components soldered using solder balls. This simulation will illustrate where fatigue and creep properties of the solder propagate cracks within solder joints that fix the electrical to the printed circuit board(PCB).

To help increase the accuracy of the finite element analysis our group will perform thermal cycling to compare the interaction effects of the 5 solder types and 4 surface finishes on bond strength of solder after a component endures similar conditions to Joint Electron Device Engineering Council (JEDEC) K-standard thermal cycling and is subjected to a shear strength test.

Design Specifications
To achieve a realistic model of electronic components soldered using solder balls we will establish material properties for the specific solder composition, and PCB surface finish used and enter our data into the computer simulation program Abaqus.

Background Research

 * As organic solder preservatives (OSP’s) are becoming an increasingly preferred choice in the electronic industry due to cost savings and more environmentally friendly compositions, it is crucial to component longevity to understand the interaction effects of lead-free solder and surface finish. With an increase in device complexity (including expansion into the mobile market), companies are concerned with solder joint reliability in manufacturing products that withstand thermal expansion and stress from physical impact.

Fracture propagation due to thermal expansion and mechanical shock occur in personal devices such as laptops, cell phones and other mobile electronic technology in the solder ball grid arrays (BGA’s).


 * The difference between the thermal expansion coefficients of the ceramic printed circuit boards and the metal solder balls is the cause of fracture propagation and a major contributor to solder joint failure.

Experimental Design
With our project we are experimentally testing the interaction effects between differing solder compositions and printed circuit board surface finishes.

Specimens will be tested according to JEDEC K-standard thermal cycling. Thermal temperature ranges is 0[C] -125[C] to an accuracy of +/-10[C]. Therefore, the thermal shock machine will be programmed to quickly shift between those 2 temperatures to stress the test specimens for 250 cycles. This thermal cycling will be representative of true JEDEC thermal cycling where the intermetallic layers between the solder pad and solder ball diffuse over time and create brittle sections across the contact surface. It is within these layers that crack propagation occurs and threatens the longevity of the component.

After the thermal shock test has been completed, each specimen will be subjected to a shear strength test to determine the reliability of the post-stressed solder joint combinations. The shear strength testing machine is capable of applying a maximum load of 10kgf (98.1N) to the edge of a component surface. To design the BGA size, a shear stress machine will operate near a loading of 5kgf which will allow the machine to operate in the middle range of performance. At this loading, a 6x6 BGA will fail near the target loading of 5kgf (within a small percent error).