Influence of Underfill on Ball Grid Array (BGA) Package Fatigue Life

Chilakamarthi, Geetha

21 May 2004

The influence of underfill material properties on the fatigue life of Ball Grid Array (BGA) packages that are subjected to thermal cycling is investigated in this study. A finite element model is created using Ansys by assuming the existence of an infinite array of solder interconnects, cylindrical in shape, surrounded by underfill material. Axial stresses in the interconnects are determined as a temperature loading is applied. The results show that these normal stresses are on the same order of magnitude as the hydrostatic compressive stresses induced in the solder upon underfill curing. Therefore it is concluded that for the range of underfill properties tested, these Mode I cyclic stresses need to be considered in the development of a fracture-based fatigue life model. In addition, a guideline is provided to aide researchers in designing experiments that will replicate loads on fractured specimens that are consistent with those seen in aerospace applications.

Mode I cyclic stress

underfill

BGA package

Zvýšení životnosti vývodu vysokotlakého adaptéru / Increasing lifetime of outlet on high-pressure adapter

Doležal, Jiří

January 2014

The goal this work is solve the case of customer complaint. The solved part is loaded by high pressure and extend the service life will be considered a number of possible solu-tions. Among them will be selected to best in terms of technical, economic, and rate of delivery.

PREDICTING THE DYNAMIC BEHAVIOR OF COAL MINE TAILINGS USING STATE-OF-PRACTICE GEOTECHNICAL FIELD METHODS

Salehian, Ali

01 January 2013

This study is focused on developing a method to predict the dynamic behavior of mine tailings dams under earthquake loading. Tailings dams are a by-product of coal mining and processing activities. Mine tailings impoundments are prone to instability and failure under seismic loading as a result of the mechanical behavior of the tailings. Due to the existence of potential seismic sources in close proximity to the coal mining regions in the United States, it is necessary to assess the post-earthquake stability of these tailings dams. To develop the aforementioned methodology, 34 cyclic triaxial tests along with vane shear tests were performed on undisturbed mine tailings specimens from two impoundments in Kentucky. Therefore, the liquefaction resistance and the residual shear strength of the specimens were measured. The laboratory cyclic strength curves for the coal mine specimens were produced, and the relationship between plasticity, density, cyclic stress ratio, and number of cycles to liquefaction were identified. The samples from the Big Branch impoundment were generally loose samples, while the Abner Fork specimens were dense samples, older and slightly cemented. The data suggest that the number of loading cycles required to initiate liquefaction in mine tailings, NL, decreases with increasing CSR and with decreasing density. This trend is similar to what is typically observed in soil. For a number of selected specimens, using the results of a series of small-strain cyclic triaxial tests, the shear modulus reduction curves and damping ratio plots were created. The data obtained from laboratory experiments were correlated to the previously recorded geotechnical field data from the two impoundments. The field parameters including the SPT blow counts (N1)60, corrected CPT cone tip resistance (qt), and shear wave velocity (vs), were correlated to the laboratory measured cyclic resistance ratio (CRR). The results indicate that in general, the higher the (N1)60 and the tip resistance (qt), the higher the CSR was. Ultimately, practitioners will be able to use these correlations along with common state-of-practice geotechnical field methods to predict cyclic resistance in fine tailings to assess the liquefaction potential and post-earthquake stability of the impoundment structures.

mine tailings

liquefaction

cyclic stress ratio

modulus reduction curves

cyclic triaxial test

Civil Engineering

Geology

Geotechnical Engineering

Mining Engineering

Assessment Of Soil

Unutmaz, Berna

01 December 2008

Although there exist some consensus regarding seismic soil liquefaction assessment of free field soil sites, estimating the liquefaction triggering potential beneath building foundations still stays as a controversial and difficult issue. Assessing liquefaction triggering potential under building foundations requires the estimation of cyclic and static stress state of the soil medium. For the purpose of assessing the effects of the presence of a structure three-dimensional, finite difference-based total stress analyses were performed for generic soil, structure and earthquake combinations. A simplified procedure was proposed which would produce unbiased estimates of the representative and maximum soil-structure-earthquake-induced iv cyclic stress ratio (CSRSSEI) values, eliminating the need to perform 3-D dynamic response assessment of soil and structure systems for conventional projects. Consistent with the available literature, the descriptive (input) parameters of the proposed model were selected as soil-to-structure stiffness ratio, spectral acceleration ratio (SA/PGA) and aspect ratio of the building. The model coefficients were estimated through maximum likelihood methodology which was used to produce an unbiased match with the predictions of 3-D analyses and proposed simplified procedure. Although a satisfactory fit was achieved among the CSR estimations by numerical seismic response analysis results and the proposed simplified procedure, validation of the proposed simplified procedure further with available laboratory shaking table and centrifuge tests and well-documented field case histories was preferred. The proposed simplified procedure was shown to capture almost all of the behavioral trends and most of the amplitudes. As the concluding remark, contrary to general conclusions of Rollins and Seed (1990), and partially consistent with the observations of Finn and Yodengrakumar (1987), Liu and Dobry (1997) and Mylonakis and Gazetas, (2000), it is proven that soil-structure interaction does not always beneficially affect the liquefaction triggering potential of foundation soils and the proposed simplified model conveniently captures when it is critical.

TA Foundations, Earthwork 715-787

Effects Of Soil Structure Interaction And Base Isolated Systems On Seismic Performance Of Foundation Soils

Soyoz, Serdar

01 July 2004

In this thesis primarily structural induced liquefaction potential was aimed to be analyzed. Also the effect of base isolation systems both on structural performance and liquefaction potential was studied. FLAC software was chosen for the analyses so that structure and soil could be modeled together. By these means the soil structure interaction effects were also examined. Four different structures and three different sites were analyzed under two different input motions. All the structures were also analyzed as base isolated. It was mainly found that depending on the structural type and for a certain depth the liquefaction potential could be higher under the structure than the one in the free field. Also it was concluded that base isolation systems were very effective for decreasing the story drifts, shear forces in the structure and liquefaction potential in the soil. It was also found that the interaction took place between structure, soil and input motions.

MECHANICAL CHARACTERIZATION – MONOTONIC MICRO-TENSILE, STRESS RELAXATION, AND STRAIN-CONTROLLED CYCLIC STRESS-STRAIN RESPONSES OF SINGLE ELECTROSPUN PVDF NANOFIBERS

Falola, Adekunle Samuel

29 August 2019

No description available.

Mechanical Engineering

Materials Science

Polymers

Single Electrospun Nanofibers

Mechanical Characterization

Stress Relaxation

Micro-Tensile

Cyclic Stress-Strain

Fatigue of Nanofibers

Electrospinning

Evaluating the thermal-mechanical coupling effect on rubber aging: a combined experimental and modeling approach

Guo, Xufeng

01 July 2020

No description available.

Mechanical Engineering

Materials Science

Chemical Engineering

rubber aging

thermal-mechanical coupling effect

cyclic stress

oxygen diffusion

kinetic-diffusion mode

Investigating the Mechanical Behavior of Conventionally Processed High Strength Aluminum Alloy 2024

Patel, Rishikumar M.

13 September 2018

No description available.

Engineering

Materials Science

Metallurgy

Aluminum Alloy 2024

conventional processing

microstructural characterization

tensile response

compression response

hardness response

shear response

Mechanical Strain-Mediated Syndecan Regulation and Its Effects on Adhesion of Vascular Smooth Muscle Cells

Julien, Mathéau A.

19 January 2005

An injured vascular system has a substantial impact on an individuals overall health, and an understanding of the mechanisms that underlie blood vessel pathophysiology is required for the development of rational and effective treatment strategies. The phenotypic modulation of smooth muscle cells (SMC) during vascular injury, characterized by altered adhesion, migration and synthetic behavior, plays an important role in the eventual outcome. Specifically, the ability of SMCs to adhere to and remodel their extracellular environment via regulation of the syndecan class of cell adhesion molecules dictates the response of the vascular wall to local injury. The effect of in vitro syndecan-4 regulation on SMC adhesion was investigated through the use of a glass microsphere centrifugation assay, and an antisense-mediated reduction in gene expression was found to correlate with decreased adhesive strength. Regulation of syndecan-1, syndecan-2, and syndecan-4 gene expression was observed experimentally by mechanical strain of SMCs. Using real-time polymerase chain reaction (PCR), the kinetics of both static and cyclic mechanical strain were found to modify the gene expression in a time and strain magnitude-dependent manner unique to each syndecan. In particular, the responses of syndecan-4 were acute, but transient, while the evolution of syndecan-1 and syndecan-2 regulation was delayed by comparison. Mechanical strain also modulated syndecan-4 protein expression and ectodomain shedding, as measured by Western immunoblotting, and this effect was found, through selective inhibition, to be at least in part dependent on mitogen-activated protein (MAP) kinase signaling. In particular, intact extracellular signal-regulated MAP kinase (ERK) 1/2 and c-Jun NH2-terminal kinase / stress-activated protein kinase (JNK/SAPK) signaling pathways were found to be required for the observed strain-induced shedding. These findings offer a better understanding of syndecan function in response to mechanical strain and suggest potential new mechanisms by which physical forces may modulate vascular SMC behavior and regulation during normal physiology, pathologic conditions, and engineered arterial substitute development.

Vascular graft

Mitogen activated protein kinase

Tissue engineering

Ectodomain shedding

Cell adhesion

Smooth muscle

Cyclic strain

Cyclic stress

Biomechanics

Syndecan

Heparan sulfate proteoglycan

Vascular smooth muscle

Blood-vessels Pathophysiology

Cell physiology

Strains and stresses

Erfassung der Einflüsse Temperatur und Porosität für Magnesium-Druckgusslegierungen im Örtlichen Konzept

Fuhrmann, Katrin

12 July 2011

Mg-Druckgusslegierungen sind aufgrund ihrer geringen Dichte potenzielle Leichtbauwerkstoffe. Ihre Festigkeitseigenschaften werden durch erhöhte Temperatur und die druckgussprozessbedingte Porosität maßgeblich beeinflusst. Zur Auslegung zyklisch belasteter Mg-Druckgussbauteile für eine begrenzte Betriebsdauer kann das Örtliche Konzept verwendet werden. Im Örtlichen Konzept nimmt das zyklische Werkstoffverhalten eine zentrale Rolle ein. Es umfasst das zyklische Verformungsverhalten und das zyklische Ermüdungsverhalten. Zur Beschreibung des zyklischen Werkstoffverhaltens werden die zyklische Spannungs-Dehnungs-Kurve für das Verformungsverhalten und die Dehnungswöhlerlinie für das Ermüdungsverhalten verwendet. Ziel der vorliegenden Arbeit ist es, die Einflüsse Temperatur und Porosität auf das zyklische Werkstoffverhalten der Mg-Druckgusslegierungen AZ91 und AM50 quantitativ zu erfassen. Dazu wird ein objektives Regressionsverfahren ermittelt, mit dem die zyklische Spannungs-Dehnungs-Kurve und die Dehnungs-Wöhler-Linie gemeinsam unter Einhaltung der Kompatibilitätsbedingungen aus den Daten einer Versuchsreihe regressiert werden können. Desweiteren wird eine Methodik entwickelt, mit der Ansätze zur quantitativen Erfassung von Einflüssen auf das zyklische Werkstoffverhalten aus Versuchsdaten abgeleitet werden können. Diese Methodik wird zur Untersuchung der Einflüsse Temperatur und Porosität auf das zyklische Werkstoffverhalten der Mg-Druckgusslegierungen AZ91 und AM50 angewendet. Die Untersuchungsergebnisse und deren Validierungen werden in dieser Arbeit vorgestellt. / Die-cast magnesium alloys are potential light-weight materials due to their low density. Their mechanical properties are significantly affected by elevated temperatures and by porosity, which die castings are especially prone to. The local strain approach can be used for dimensioning cyclically loaded magnesium die castings for a limited service life. The central role of this approach is assigned to the cyclic material behaviour. The cyclic material behaviour includes the cyclic deformation behaviour and the cyclic fatigue behaviour. It is characterized by the stress-strain curve for the cyclic deformation behaviour and by the strain-life curve for the cyclic fatigue behaviour. In the present work the aim is to describe the influence of elevated temperatures and of porosity on the cyclic material behaviour quantitatively. Therefore, a method is developed, which allows an objective and combined regression of the stress-strain curve and the strain-life curve for one test series. Furthermore, a methodology is developed, for deriving a formulation from experimental data to describe an arbitrary influence on the cyclic material behaviour quantitatively. This methodology is used to study the influences of elevated temperature and of porosity on the cyclic material behaviour of the die-cast magnesium alloys AZ91 and AM50. The results of the investigations and their validation are presented in this treatise.

Magnesium

Örtliches Konzept

erhöhte Temperatur

Porosität

zyklische Spannungs-Dehnungskurve

Dehnungswöhlerlinie

magnesium

local strain approach

elevated temperatures

porosity

cyclic stress-strain-curve

cyclic strain-life-curve

ddc:620

rvk:ZM 3200