Structural optimization of electronic packages using DOE / Strukturoptimering av elektronik med DOE

Johansson, Robin

January 2020

The reliability of a mechanical system containing electronic packages is highly affectedby the environment the system is stationed in. The difference and fluctuationsbetween the ambient temperature and the operating temperature of the electronicpackage cause accumulation of inelastic strains in the package components thusdecreasing the service life. The most common failure modes of an electronic packagehas been identified from inspection of malfunctioning machines as cracks in the solderjoint and delamination between the glue and the die. Knowledge regarding therelationships between parameters affecting these failure modes, which are importantand which are not, is of high interest when developing new and existing products. SAAB AB would like to develop a methodology using design exploration to allow forevaluation of electronic packages using nonlinear finite element methods. A surrogate model was created and parameterized with HyperMorph to be used forthree linear static variations of design of experiments, where both the performance ofthe methods themselves and the relative importance of the parameters were ofinterest. A connectivity condition was also implemented to allow for relativemovement between components while keeping the mesh intact. The designexploration was executed using a Taguchi design, a Modified extensive latticesequence design and a fractional factorial design where the three methods werecompared as well as the parameter significance analysed. An optimization was thenperformed to find the optimal parameter settings within the allowed bounds to beused where a nominal model and an optimized model are evaluated with animplemented creep law. The fatigue life of the two models were then estimated. / Tillförlitligheten hos ett mekaniskt system med elektroniska kretsar påverkas starkt av miljön systemet används i. Skillnader och fluktuationer mellan omgivningens temperatur och arbetstemperaturen för de elektroniska kretsarna orsakar ackumulering av inelastiska töjningar, därmed förkortas det mekaniska systemets livstid. Dem vanligaste fel-moderna för en elektronisk krets har identifierats genom inspektion av felande maskiner som sprickbildning i lödfogarna och delaminering mellan processorn och dess lim. Kunskap hur förhållandet mellan parametrar som påverkar dessa fel-moder, vilka som är viktiga och vilka som inte är viktiga är av högt intresse vid utveckling av nya och redan existerande produkter. SAAB AB vill utveckla en metodik som utnyttjar statistisk försöksplanering för analyserande av elektroniska kretsar med hjälp av olinjära finita element metoder för att kunna spegla dess beteende på ett realistiskt sätt. En surrogatmodell skapades och parametriserades med hjälp av HyperMorph för att användas inom tre statiskt linjära varianter av statistisk försöksplanering, där både metodens prestanda och den relativa påverkan från parametrarna var av intresse. Ett kontaktvillkor implementerades för att tillåta relativ rörelse mellan komponenter samtidigt som nätet av finita element hölls intakt. Försöksplaneringsimuleringar utfördes med en Taguchi design, en Modified extensive lattice sequence design och en fractional factorial design, där de tre metoderna jämfördes mot varandra samt analyserades vad gäller respektive parametersignifikansen. Med optimering fanns sedan en optimal modell för att kunna jämföras med en nominell modell där en kryplag implementerades i lödfogen. Livslängden beräknades sedan för båda modeller.

Design of experiments

DOE

Structural optimization

Electronic packages

DOE

Försöksplanering

Strukturoptimering

Applied Mechanics

Teknisk mekanik

Topology optimization : A comparison between the SIMP and BESO methods using open-source software.

Hagnell, Christian, Saidi Mosanen, Kiavosh

January 2021

Structural optimization is a useful tool for engineers and designers in construction technology as well asvehicle and mechanical engineering. With structure optimization, a computer can, with the help of finiteelement analysis, calculate the smallest possible amount of material needed to meet the requirements onthe part to be produced.The purpose of this report is to use two different implementations for finite element calculations fortopology optimization of a beam. Results from the optimizations will then be 3D printed with differentsettings. The beam will be tested for displacement, stress and strain in a universal testing machine. Theresults from the experiment will be compared with computed simulations of the same beam.For the structural optimization, two methods are used and compared: Solid Isotropic Material withPenalization and Bidirectional Evolutionary Structural Optimization. A total of eight beams, four fromeach method, were printed with a 3D printer with two different positions on the printer bed and withdifferent degrees of infill ratios. These were tested with a machine that could register both pressure anddeformation and were filmed to be able to see the strain. The deformation of the beams was alsosimulated in a software computer program to see what deformation difference there was betweenexperiment and reality.It turned out that the beams that were printed behaved anisotropic even though solid plastic should beincluded among isotropic materials. The deformation of the model looked like the finite elementcalculation, but the actual deformation was significantly larger than what was calculated by the computersoftware.

Strukturoptimering

SIMP

BESO

statiskt obestämd balk

3D utskrift

bärande balk

öppen källkod

FreeCAD

Python

Civil Engineering

Samhällsbyggnadsteknik