[en] NONLINEAR AND CHAOTIC DYNAMICS OF MECHANICAL SYSTEMS WITH SHAPE MEMORY / [pt] DINÂMICA NÃO-LINEAR E CAÓTICA DE SISTEMAS MECÂNICOS COM MEMÓRIA DE FORMA

MARCELO AMORIM SAVI

08 March 2018

[pt] Motivado por aplicações na àrea de materiais e estruturas inteligentes, este trabalho apresenta resultados de um estudo sobre a resposta dinâmica de sistemas mecânicos contendo elementos com memória de forma Inicialmente é realizada uma revisão crítica de algumas teorias formenológicas que procuram descrever os efeitos de memória de forma e pseudoelasticidade associados a transformações martensíticas tamoelásticas. Duas destas teorias são utilizadas na modelagem de uma mola helicoidal. O comportamento dinâmico de um oscilador com memória de forma é investigado. Verifica-se que o sistema pode responder caoticamente sob determinadas condições. É também apresentado um método, baseado na técnica dos Elementos Finitos, para a análise estática e dinâmica não-linear de estruturas reticuladas com memória de forma. Resultados de simulações numéricas ilustram a complexidade do comportamento destas estruturas. / [en] Motivated by recent developments in the field of intelligent structures and materials, the present work reports results from an investigation on the dynamical behavior of mechanical systems containing elements with shape memory. Initially, three phenomenologieal theories that attempt to describe shape memory and pseudoelastic effects in metallic alloys that undergo thermoelastic martensitic transfomations are reviewed. Two of these theories are used to model and helical spring. The dynamic response of an oscillator with shape memory spring is investigated. It is shown tlm the system may behave chaotically under certain conditions. A method based on the Finite Element techinique, which can be applied to model the non-linear static and dynamic behavior of adaptive trusses with shape memory elements is also presented. Results of numerical simulations illustrate the complex behavior of these structures.

[pt] MEMORIA DE FORMA

[en] SHAPE MEMORY

[pt] PSEUDOELASTICIDADE

[en] PSEUDOELASTIC EFFECTS

Crystal growth, guest ordering and ferroelastic properties of urea inclusion compounds

Rush, Jeremy Richard

January 1900

Doctor of Philosophy / Department of Chemistry / Mark D. Hollingsworth / The ferroelastic urea inclusion compound (UIC) of 2,10-undecanedione/urea exhibits a striking pseudoelastic memory effect. Although pseudoelasticity is possible for UICs containing only 2,10-undecanedione, introduction of a structurally similar guest impurity (2-undecanone) gives rise to rubber-like behavior, a form of pseudoelasticity. This phenomenon depends on both the crystal strain and the concentration of monoketone: above 13-14% 2-undecanone, pseudoelastic behavior is observed reliably, even at strains as high as 2.4%. The dramatic change in ferroelastic behavior over a small range of impurity content indicates that this is a critical threshold phenomenon. Because the impurity concentration has such a dramatic effect on domain switching, it was important to determine the sector-dependent patterns of incorporation of this relaxive impurity. Preliminary HPLC analyses of guest populations suggest that preferential incorporation of monoketone guests occurs between nonequivalent growth sectors, and that these patterns can be rationalized using a symmetry specific growth model. Birefringence mapping and HPLC studies of optically anomalous UICs containing mixtures of 2,9-decanedione and 2-decanone (which possess trigonal metric symmetry) suggest analogous patterns in guest incorporation and/or ordering that can also be rationalized. Although crystals of 2,9-decanedione/urea exhibit no ferroelastic strain at ambient temperature, they exhibit a proper ferroelastic phase transition near -170[degrees]C. It is proposed that differential perfection of domains gives rise to pseudoelasticity in UICs, and that relaxive impurities play an important role in the energetics of this process. Because ultrafast video studies of domain reversion kinetics demonstrate no clear correlation of observed rates with impurity content, it is proposed that the relaxive impurities facilitate spontaneous domain reversion by annealing stressed defect sites that would otherwise lead to irreversible or plastic domain switching. Following earlier work using synchrotron white beam X-ray topography, the driving force for domain reversion is thought to involve the presence of nanoscopic twins whose strain is epitaxially mismatched with neighboring daughter domains. The behavior of these nanoscopic twins was monitored with in-situ X-ray diffraction studies of stressed crystals, and this has led to a more thorough understanding of the role of these nanoscopic twins in the ferroelastic domain switching and rubber-like behavior in this class of materials.

ferroelastic domain switching

pseudoelastic memory effect

rubber-like behavior

guest impurity

preferential incorporation

symmetry specific growth model

Chemistry, Organic (0490)

Synchrotron Radiation X-Ray Diffraction of Nickel-Titanium Shape Memory Alloy Wires During Mechanical Deformation

Zhang, Baozhuo

12 1900

Shape memory alloys (SMAs) are a new generation material which exhibits unique nonlinear deformations due to a phase transformation which allows it to return to its original shape after removal of stress or a change in temperature. It shows a shape memory effect (martensitic condition) and pseudoelasticity (austenitic condition) properties depends on various heat treatment conditions. The reason for these properties depends on phase transformation through temperature changes or applied stress. Many technological applications of austenite SMAs involve cyclical mechanical loading and unloading in order to take advantage of pseudoelasticity, but are limited due to poor fatigue life. In this thesis, I investigated two important mechanical feature to fatigue behavior in pseudoelastic NiTi SMA wires using high energy synchrotron radiation X-ray diffraction (SR-XRD). The first of these involved simple bending and the second of these involved relaxation during compression loading. Differential scanning calorimetry (DSC) was performed to identify the phase transformation temperatures. Scanning electron microscopy (SEM) images were collected for the initial condition of the NiTi SMA wires and during simple bending, SEM revealed that micro-cracks in compression regions of the wire propagate with increasing bend angle, while tensile regions tend to not exhibit crack propagation. SR-XRD patterns were analyzed to study the phase transformation and investigate micromechanical properties. By observing the various diffraction peaks such as the austenite (200) and the martensite (100), (110), and (101) planes, intensities and residual strain values exhibit strong anisotropy depending upon whether the sample is in compression or tension during simple bending. This research provides insight into two specific mechanical features in pseudoelastic NiTi SMA wires.

bending

pseudoelastic

synchrotron X-ray diffraction

shape memory alloy wires

Engineering, Materials Science

Synchrotron radiation.

Shape memory alloys.

Nickel-titanium alloys.

Nízkocyklová únava pseudoelastické slitiny NiTi / Low cycle fatigue of pseudoelastic NiTi alloy

Kaňová, Monika

January 2013

This work is focused on study of mechanical properties of NiTi alloy which shows pseudoelastic and shape memory behaviour. Functional and structural fatigue of the material is examined. The main aim of this work was to perform and to evaluate a series of fatigue tests. The material was supplied in the form of wire which was gripped in the machine using special grips. In the first part of the experiment, tensile tests are evaluated and the reproducibility of measurements is demonstrated. Then, a series of cyclic tests was performed. Results were analysed together with previous measurements. One part of discussion concerned changes of the hysteresis loops during cycling and their dependence on strain rate. The fatigue life curves were plotted. It was found that these curves have non-standard shapes. The reasons for this are explained in the work.