Service life | EPFL Graph Search

A product's service life is its period of use in service. Several related terms describe more precisely a product's life, from the point of manufacture, storage, and distribution, and eventual use. Service life has been defined as "a product's total life in use from the point of sale to the point of discard" and distinguished from replacement life, "the period after which the initial purchaser returns to the shop for a replacement". Determining a product's expected service life as part of business policy (product life cycle management) involves using tools and calculations from maintainability and reliability analysis. Service life represents a commitment made by the item's manufacturer and is usually specified as a median. It is the time that any manufactured item can be expected to be "serviceable" or supported by its manufacturer. Service life is not to be confused with shelf life, which deals with storage time, or with technical life, which is the maximum period during which it

Deformation and Damage in Lead-free Solder Joints

Milad Maleki

For environmental reasons, lead has been banned from microelectronic solder materials since the adoption of the RoHS legislation in 2006. A large number of investigations have lead to the development of new lead-free solder materials like the SnAgCu alloy which can satisfy most of the technological requirements. However, the long-time reliability of the lead-free candidates is still a crucial issue and in several cases, failure of electronic assemblies has been attributed to that of the solder joints. To overcome the present challenge in the soldering technology, the damage mechanisms occurring along the service life of lead-free solder joints like microstructure evolution, viscoplastic deformation as well as interfacial cracking must be better understood. The main scope of this thesis is to shed light on the complex interdependency of microstructures, deformation property and the interfacial fracture of solder joints in order to explain the change in the failure mode of solder joints from ductile to brittle interfacial fracture as well as the link between microstructural evolution and the change in the mechanical property of the solders. The first part of this research focused on characterization and macroscopic modeling of the fracture at the interface of SnAgCu solder and Cu substrate with a special attention on the viscoplastic nature of the bulk solder. For this purpose, the viscoplastic behavior of the solder joint was initially identified and the material parameters related to a unified constitutive viscoplastic model were determined. The interfacial fracture behavior of the joint was characterized by performing stable fracture tests at different strain rates. The results confirmed that the failure mode of the solder joint is a function of the loading rate. It was shown that an increase in the loading rate causes a decrease in the load-bearing capacity of the joint by enhancing the tendency to develop an interfacial failure. The interfacial crack propagation in the fracture tests were simulated by developing a detailed three-dimensional (3D) finite element (FE) model containing a cohesive interface and considering the viscoplastic behavior of the bulk solder. The influence of strain rate and viscoplasticity on the load-bearing capacity and failure behavior of the joint were pointed out by analyzing the simulation results. It was shown how the normal stress generated at the interface is limited by the significant viscoplastic relaxation developed in the bulk solder at low strain rates, while a large portion of the external work is transferred to the interface at higher rates which gives rise to interfacial fracture. The second part of this thesis focused on developing microstructure-based models in order to simulate the change in the macroscopic mechanical response of the SnAgCu solder caused by the microstructural evolution during thermal ageing. For this purpose, first, the 3D configurations of microstructures in different ageing conditions were visualized using a combination of synchrotron X-ray and FIB/SEM tomography techniques. Analyses showed that although the size and orientation of crystalline grains as well as morphology of dendrites in SnAgCu solder remain stable during ageing, two main morphological changes occur in the Ag3Sn and Cu6Sn5 intermetallic particles: spheroidizing of needle-shape intermetallics and coarsening due to bulk diffusion. The mechanical property of the solder and its phases at different ageing conditions were experimentally characterized. A significant decrease in the yield strength of the solder joint was identified because of thermal ageing and it was shown that the deformation behavior of the solder is governed by the morphometrics of the dispersed intermetallics. The link between the microstructures and the deformation behavior of solder was successfully simulated by developing a hybrid microstructure-based modeling approach. The average indirect strengthening of the intermetallics was modeled by incorporating the effects of geometrically necessary dislocation on the in-situ deformation behavior of the tin matrix. Subsequently, a micromechanical FE homogenization was considered to model the load-sharing behavior of the intermetallics. For this purpose, the tomographic images were directly used to generate 3D FE meshes of the actual microstructures and then the constitutive deformation behavior of the solder were determined by adopting two levels of numerical homogenization in the eutectic phase and over the whole joint. The decrease in the yield strength of solder due to ageing was explained through analyses of indicators in the models. It was demonstrated how the change in the morphometrics of intermetallics during ageing reduces the contribution of intermetallics in load-sharing as well as the in-situ strength of the matrix by causing a significant change in the strain distribution as well as particle size effects. The simulation results were experimentally verified and the capabilities as well as limitations of the developed approach were pointed out. Overall, the results of this research led to a proper understanding of the critical reliability issues in lead-free solders during isothermal ageing, i.e., microstructural coarsening and interfacial fracture. In addition, through this work, a set of methodologies for multi-scale modeling and experimental characterization of the damage and deformation in solder joints were developed and validated which can be extremely helpful for efficient use of the SnAgCu solders in electronic industry as well as designing new solder alloys with higher strength and better reliability for a safe transition to lead-free solders in critical applications.

EPFL2012

Hygrothermal Ageing and Damage Characterization in Epoxies and in Epoxy-Glass Interfaces

Marco Lai

Nowadays, composite materials are increasingly used in high technology fields such as aerospace and automotive because of the combination of excellent mechanical performance and lightweight. For these characteristics, classical metal alloys are progressively replaced in primary structural components by reinforced polymer composites. The service life of such structural components is more and more increased thus raising questions on the composites' durability since it is well known that they are susceptible to long term aggressive environments. In fact, UV radiations, high temperature, solvents, fuel, humidity and water synergistically act with mechanical loads to reduce the resistance of composite materials. To address this problem two main approaches are used. On one hand, the macromechanical approach is used for the long term reliability of composite materials that experimentally is characterized by means of accelerated ageing tests that reproduce the service environments. On the other hand, the micromechanical approach is aimed at understanding the intimate degradation mechanisms triggered by the environmental conditions. This objective is partially accomplished by reducing the geometrical complexity of the material microstructure subdividing it into elementary unit cells. In this work, the combination of moderate high temperature and moisture is chosen as the ageing environment. The effects of the hygrothermal ageing on the properties of an epoxy resin are studied using a single fiber composite (SFC) unit cell. The reinforcement of the SFC is an optical glass fiber that presents, along a portion of its core, a fiber Bragg grating (FBG) sensor capable of gathering information about the deformation field inside the unit cell. This particular configuration allows to study evolution of the internal stress state during cure, at high temperatures and during the ageing process. The residual deformation field in the SFC is investigated by using a mixed experimental-numerical technique. A series of radial cuts are introduced into the SFC geometry while the induced strain perturbation is recorded by the embedded FBG sensor. This knowledge is used in an identification scheme in order to determine a shrinkage function capable of reproducing the initial deformation state in the axysimmetric configuration. The calculated deformation field is in good agreement with similar studies in litterature. The study of the thermomechanical response of the SFC allows to determine the resin's coefficient of thermal expansion. The procedure is validated in the case of an epoxy resin reinforced with different weight percent of SiO2 nanoparticles and rubber microparticles. It is shown that the method provides more stable results if compared to the classical TMA analysis. The resin response to the wet environment at 50°C is characterized firstly by means of a gravimetric analysis that led to the determination of the water diffusion kinetic parameters. Secondly, the mechanical property evolution as function of humidity is determined by means of tensile, multiple relaxation tests and microindentations. Lastly, the resin coefficient of moisture expansion is determined and displays a non linear trend. A residual-thermo-hygro mechanical model is built on the basis of the determined parameters showing excellent agreement with the recorded experimental data. Moreover, the hygrothermally induced fiber fracture is analyzed by means of the linear elastic fracture mechanics and the shear lag theory. Finally, the fiber-matrix debonding, triggered by the reinforcement failure, is characterized by the use of cohesive elements whose mechanical properties are varied as function of the concentration at the interface. The calculated redistribution of stresses after the fiber failure and the debonding kinetic reproduces accurately the recorded experimental behaviour.

EPFL2011

Residual stress characterization in a single fibre composite specimen by using FBG sensor and the OLCR technique

Fabiano Colpo

The purpose of this thesis is to characterize internal strains in polymeric materials due to consolidation. In view of this, optical Fiber Bragg Grating sensors are an excellent non-destructive tool for internal strain characterization and damage detection in composite materials and structures. Fiber Bragg Gratings (FBG), have become increasingly used in engineering applications because of their inherent advantages with respect to traditional sensors. They can provide an important tool in experimental mechanics to perform key experiments that are difficult or impossible with other standard techniques. In this respect, they are ideally suited as strain measuring devices in composites, where they can be embedded non-invasively during fabrication. In view of this, the main goal of this thesis is the development of an experimental methodology to characterize the residual stresses that are generally present in many materials and is a complex problem to solve in micro-mechanics. The work is presented in three interrelated parts. Long-gauge-FBGs (Bragg grating of ∼ 24 mm) are introduced in cylindrical specimens of epoxy. In this configuration the fiber is simultaneously a reinforcement and a sensor in a single fiber composite. Because the epoxy matrix shrinks during the polymerization process, the optical sensor undergoes substantial non-uniform strain along the fiber. The response of the FBG to a non-uniform strain distribution is investigated by using an Optical Low-Coherence Reflectometry (OLCR) based technique which allows a direct reconstruction of the optical period along the grating without any a priori assumption about the strain field. A comparison with the most common reconstruction inverse technique T-Matrix is also proposed, showing that it generally introduces greater errors without ensuring the uniqueness of the solution. The OLCR permits in fact the direct measurement of the axial evolution of the residual strain along the core of the reinforcing fiber, thus providing important information on the internal state of stress of the specimen at a given stage of its preparation and, later on, during its service life. In addition, the measured strain distribution evolves along the fiber direction following a fourth-order function, which clearly presents a plateau over a 20 mm range at the center of the specimen. In particular, the maximum strain level reached after the matrix solidification is –2000 με which increases up to –6000 με at the end of the post-curing process of the resin. This value is consistent with the volume reduction of the free resin provided by the producer and equal to 2 %. This strain corresponds to -450 MPa axial compressive stress on the embedded reinforcing fiber. The implementation of FBG sensors to study the changes in the stress field when a crack is present in the sample is addressed next. Bragg wavelength distributions have been measured as a function of the depth of machined circular cracks in the radial direction of the cylinder. Three different crack depths (namely 7.5 mm, 11 mm and 12 mm) have been machined in the central section of the specimen. First, these measurements give an indication about the zone of influence of the reinforcing fiber on the residual stresses and, secondly, they permit the characterization of the effect of a mechanically induced crack on the initial residual stress state. In particular, only the stress relaxation due to the introduction of the deepest transversal crack significantly affects the FBG response with a related wavelength variation of 3 nm. These data are used as input to deduce the radial evolution of the stress field by adapting and improving the Crack Compliance (C.C.M) inverse Method to retrieve the stress field within a composite starting from a measurement of strain. A rigorous analytical approach to predict the residual stress field is described and verified numerically and experimentally. A very good agreement is found between experimental and numerical values, thus proving the reliability of the experimental approach. As last topic in this work, the response of a long FBG to the transverse crack propagation is monitored experimentally by using the OLCR and modeled numerically. Firstly, a Compact-Tension specimen submitted to a cyclic fatigue test is chosen with the FBG glued on its back-face and normal to the crack direction. A simple analytical model predict the FBG response as the crack advances. Secondly, long- FBG is embedded in a Compact-Tension specimen of the same dimensions. In particular when the natural crack overpasses the fiber, the grating can be used to measure the bridging forces between fracture surfaces and/or to measure the relative opening of the crack. Reconstruction of the FBG signal with T-matrix indicate problems associated to stress distributions due to highly non-uniform strain field. In this way, the FBG becomes the excellent candidate to study a number of interesting problems in the field of the fracture mechanics applications.

EPFL2006