Chaos control of a nonlinear oscillator with shape memory alloy using an optimal linear control: Part II: Nonideal energy source

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)

On non-ideal simple portal frame structural model: Experimental results under a non-ideal excitation

We present measurements of the non-linear oscillations of a portal frame foundation for a non-ideal motor. We consider a three-time redundant structure with two columns, clamped in their bases and a horizontal beam. An electrical unbalanced motor is mounted at mid span of the beam. Two non-linear phenomena are studied: a) mode saturation and energy transfer between modes; b) interaction between high amplitude motions of the structure and the rotation regime of a real limited power motor. The dynamic characteristics of the structure were chosen to have one-to-two internal resonance between the anti-symmetrical mode (sway motions) and the first symmetrical mode natural frequencies. As the excitation frequency reaches near resonance conditions with the 2nd natural frequency, the amplitude of this mode grows up to a certain level and then it saturates. The surplus energy pumped into the system is transferred to the sway mode, which experiences a sudden increase in its amplitude. Energy is transformed from low amplitude high frequency motion into high amplitude low frequency motion. Such a transformation is potentially dangerous.We consider the fact that real motors, such as the one used in this study, have limited power output. In this case, this energy source is said to be non-ideal, in contrast to the ideal source whose amplitude and frequency are independent of the motion of the structure. Our experimental research detected the Sommerfeld Effect: as the motor accelerates to reach near resonant conditions, a considerable part of its output energy is consumed to generate large amplitude motions of the structure and not to increase its own angular speed. For certain parameters of the system, the motor can get stuck at resonance not having enough power to reach higher rotation regimes. If some more power is available, jump phenomena may occur from near resonance to considerably higher motor speed regimes, no stable motions being possible between these two.

A contribution for nonlinear structural dynamics characterization of cantilever beams

Successful experiments in nonlinear vibrations have been carried out with cantilever beams under harmonic base excitation. A flexible slender cantilever has been chosen as a convenient structure to exhibit modal interactions, subharmonic, superharmonic and chaotic motions, and others interesting nonlinear phenomena. The tools employed to analyze the dynamics of the beam generally include frequency- and force-response curves. To produce force-response curves, one keeps the excitation frequency constant and slowly varies the excitation amplitude, on the other hand, to produce frequency-response curves, one keeps the excitation amplitude fixed and slowly varies the excitation frequency. However, keeping the excitation amplitude constant while varying the excitation frequency is a difficult task with an open-loop measurement system. In this paper, it is proposed a closed-loop monitor vibration system available with the electromagnetic shaker in order to keep the harmonic base excitation amplitude constant. This experimental setup constitutes a significant improvement to produce frequency-response curves and the advantages of this setup are evaluated in a case study. The beam is excited with a periodic base motion transverse to the axis of the beam near the third natural frequency. Modal interactions and two-period quasi-periodic motion are observed involving the first and the third modes. Frequency-response curves, phase space and Poincaré map are used to characterize the dynamics of the beam.

On the undamped free vibration of a mass interacting with a Hertzian contact stiffness

Three methods are used to determine the natural frequency of undamped free vibration of a mass interacting with a Hertzian contact stiffness. The exact value is determined using the first integral of motion. The harmonic balance method is used on a transformed equation for an approximate solution, and the multiple scales method is used on an approximate equation. The maximum initial displacement avoiding contact loss is also determined, and the corresponding exact natural frequency is also obtained analytically. The methods are evaluated by studying the free vibration of an elastic sphere on a flat rigid surface. © 2011 Elsevier Ltd © 2011 Elsevier Ltd. All rights reserved.

On the dynamic behaviour of a nonlinear system weakly connected to a linear single degree-of-freedom system

This paper discusses the dynamic behaviour of a nonlinear two degree-of-freedom system consisting of a harmonically excited linear oscillator weakly connected to a nonlinear attachment that behaves as a hardening Duffing oscillator. A system which behaves in this way could be a shaker (linear system) driving a nonlinear isolator. The mass of the nonlinear system is taken to be much less than that in the linear system and thus the nonlinear system has little effect on the dynamics of the linear system. Of particular interest is the situation when the linear natural frequency of the nonlinear system is less than the natural frequency of the linear system such that the frequency response curve of the nonlinear system bends to higher frequencies and thus interacts with the resonance frequency of the linear system. It is shown that for some values of the system parameters a complicated frequency response curve for the nonlinear system can occur; closed detached curves can appear as a part of the overall amplitude-frequency response. The reason why these detached curves appear is presented and approximate analytical expressions for the jump-up and jump-down frequencies of the system under investigation are given.

Passive vibration isolation using axially loaded curved beams

A nonlinear spring element of a vibration isolator should ideally possess high static and low dynamic stiffness. A buckled beam may be a good candidate to fulfil this requirement provided its internal resonance frequencies are high enough to achieve a wide frequency range of isolation. If a straight beam is used, there is a singularity in the force-displacement characteristic. To smooth this characteristic and eliminate the singularity at the buckling point, beams with initial constant curvature along their length are investigated here as an alternative to the buckled straight beam. Their force displacement characteristics are compared with different initial curvature and with a straight buckled beam. The minimum achievable dynamic stiffness with its corresponding static stiffness is compared for different initial curvatures. A case study is considered where the beams are optimized to isolate a one kilogram mass and to achieve a natural frequency of 1 Hz, considering small amplitudes of vibration. Resonance frequencies of the optimized beams for different curvature are presented. It is shown that an order of magnitude reduction in stiffness compared with a linear spring is achievable, while the internal resonance frequencies of the curved beam are high enough to achieve an acceptable frequency range of isolation.

Um estudo da dinâmica fracamente não-linear de um sistema nanomecânico

Pós-graduação em Matemática - IBILCE

Implementação e testes de campo de um ESP digital

Neste trabalho é apresentado o desenvolvimento e os resultados da implementação e testes em campo de um estabilizador de sistema de potência (ESP) projetado com técnica de controle digital para fins de amortecimento de modos de oscilação eletromecânica observáveis em sinais de potência elétrica medido em uma unidade hidro-geradora, de 350 MVA da Usina Hidrelétrica de Tucuruí. É apresentada e aplicada a metodologia de identificação de modelos paramétricos lineares do tipo auto regressivo com entradas exógenas (ARX), para estimação de modelos com capacidade de capturar a informação relevante (amortecimento e freqüência natural) dos modos eletromecânicos dominantes do sistema. De posse do modelo paramétrico ARX, é efetuada então a síntese da lei de controle digital amortecedor para o ESP, através da técnica de deslocamento radial dos pólos da função de transferência de malha fechada. Para a síntese da lei de controle digital, utilizou-se uma estrutura canônica do tipo RST. Para os testes de campo, a lei de controle amortecedor do ESP digital foi codificada em linguagem C e embarcada em um protótipo cujo hardware é baseado em microcontrolador modelo DSPIC 30F3014, o qual incorpora um grande número de periféricos para aquisição e comunicação de dados. Para avaliar o desempenho do ESP digital desenvolvido, testes experimentais foram realizados em uma unidade geradora de 350 MVA da casa de força número 1, da UHE de Tucuruí. O estabilizador desenvolvido atua através da modulação da referência de tensão do regulador automático de tensão da respectiva unidade geradora, de acordo com as oscilações observadas através da medida de potência elétrica no estator do gerador. Os resultados de testes de campo mostraram um excelente desempenho do ESP digital no amortecimento de um modo eletromecânico, de freqüência natural de aproximadamente 1,7 Hz, observado nos teste de campo realizado.

Estratégias de controle de ordem fracionária aplicadas ao amortecimento de oscilações eletromecânicas em sistemas elétricos de potência

Neste trabalho é proposta uma nova metodologia de projeto de estabilizadores de sistemas de potência baseada em teoria de sistemas de ordem fracionária (ESP-OF). A estratégia é baseada em uma generalização do projeto de compensadores do tipo rede avançoatraso (lead-lag) para o domínio de funções de transferência de ordem fracionária. Uma nova variável de projeto, a qual define a ordem da dinâmica fracionária do controlador, é sintonizada para se obter um compromisso entre um bom desempenho no amortecimento do modo eletromecânico dominante e uma robustez ampliada do ESP-OF. O desempenho do ESP-OF foi avaliado experimentalmente, em um sistema de potência em escala reduzida, localizado no Laboratório de Sistemas de Potência da Universidade Federal do Pará. A referida planta de teste apresenta uma estrutura típica do tipo gerador síncrono conectado a um barramento infinito e exibe um modo dominante de oscilação eletromecânica, de amortecimento extremamente reduzido, cujo valor da frequência natural é em torno de 1,2 Hz. O ESP-OF foi então projetado para ampliar o amortecimento relativo desse modo alvo, para toda a faixa de operação admissível. Para fins de implementação prática, primeiramente foram realizados testes experimentais para a identificação de um modelo nominal da planta, sob a forma de uma função de transferência pulsada, para uso na fase de projeto. O modelo obtido experimentalmente foi então validado e posteriormente utilizado tanto para o projeto do ESP-OF quanto para o projeto de um ESP convencional (utilizado para fins de comparação de desempenho). As leis de controle amortecedor do ESP-OF foram calculadas, convertidas para a forma de equações a diferenças e, subsequentemente, embarcadas em sistema digital baseado em microcontrolador DSPIC. Diversos testes de resposta ao impulso foram realizadas sob diferentes condições operacionais. As respectivas respostas dinâmicas dos sinais de saída da planta (desvio de potencia ativa) e do esforço de controle foram registradas para fins de análise. Os resultados experimentais mostraram que o ESP fracionário apresentou um desemprenho dinâmico e robustez similar em comparação com o desempenho obtido por um ESP convencional, para toda a faixa de operação investigada.

An investigation into the simultaneous use of a resonator as an energy harvester and a vibration absorber

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

Análise dinâmica de mecanismo articulado de suspensão com não-linearidade na rigidez devido à geometria e à excitação por desbalanceamento rotativo na condição não ideal

Pós-graduação em Engenharia Mecânica - FEB

On the contact stiffness and nonlinear vibration of an elastic body with a rough surface in contact with a rigid flat surface

Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP)

The dynamic behavior of a cantilever beam coupled to a non-ideal unbalanced motor through numerical and experimental analysis

An excitation force that is not influenced by the system state is said to be an ideal energy source. In real situations, a direct and feedback coupling between the excitation source and the system must always exist at a certain level. This manifestation of the law of conservation of energy is known as the Sommerfeld effect. In the case of obtaining a mathematical model for such a system, additional equations are usually necessary to describe the vibration sources with limited power and its coupling with the mechanical system. In this work, a cantilever beam and a non-ideal DC motor fixed to its free end are analyzed. The motor has an unbalanced mass that provides excitation to the system which is proportional to the current applied to the motor. During the coast up operation of the motor, if the drive power is increased slowly, making the excitation frequency pass through the first natural frequency of the beam, the DC motor speed will remain the same until it suddenly jumps to a much higher value (simultaneously its amplitude jumps to a much lower value) upon exceeding a critical input power. It was found that the Sommerfeld effect depends on some system parameters and the motor operational procedures. These parameters are explored to avoid the resonance capture in the Sommerfeld effect. Numerical simulations and experimental tests are used to help gather insight of this dynamic behavior. (C) 2014 Elsevier Ltd. All rights reserved.

Projeto de controladores para a maximização de sistemas de captação de energia considerando excitação não ideal

Pós-graduação em Engenharia Mecânica - FEIS

On energy harvesting form time-limited excitations: simulations and case study

Linear resonant harvesters have been the most common type of generators used to scavenge energy from mechanical vibrations. When subject to harmonic excitation, good performance is achieved once the device is tuned so that its natural frequency coincides with the excitation frequency. In such a situation, the average power harvested in a cycle is proportional to the cube of the excitation frequency and inversely proportional to the suspension damping, which is sought to be very low. However, a very low damping involves a relatively long transient in the system response, where the classical formulation adopted for steady-state regimes do not hold. This paper presents an investigation into the design of a linear resonant harvester to scavenge energy from time-limited harmonic excitations involving a transient response, which could be more likely in some practical situations. An application is presented considering train-induced vibrations.