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11	Análise, simulação e controle de um sistema de compensação de movimento utilizando um manipulador plataforma de stewart acionado por atuadores hidráulicos Valente, Vitor Tumelero January 2016 (has links) O mecanismo Plataforma de Stewart é um manipulador do tipo paralelo, com seis graus de liberdade, boa relação peso/carga e alta rigidez. Tais características conferem a este tipo de manipulador propriedades superiores de precisão em relação aos manipuladores seriais. Neste trabalho, o controle de um Manipulador Plataforma de Stewart (MPS) acionado por atuadores hidráulicos é estudado com o objetivo de compensação de movimentos para viabilização de transferência de cargas e pessoas em ambiente naval.Visando ao desenvolvimento de um protótipo experimental, o manipulador é estudado considerando a situação em que se encontra sobreposto a um segundo MPS que tem por objetivo simular o movimento da maré, sendo ambos MPS considerados desacoplados dinamicamente. Neste contexto, o estudo envolve a análise cinemática e dinâmica do manipulador incluindo, também, a dinâmica dos cilindros hidráulicos. Além disso, são estudadas unidades de medição inercial (IMU) utilizando-as como instrumento para medição do movimento da base a ser compensado. O projeto do controlador do sistema de atenuação de movimento faz uso da técnica de Torque Computado (TC). A análise de estabilidade, feita separadamente para o sistema mecânico e hidráulico, baseou-se da teoria de Lyapunov. Simulações realizadas considerando trajetórias similares às do movimento de um navio são utilizadas. Para compensação do movimento são utilizados, também, sinais provenientes de uma IMU. Por meio de simulação, comprova-se que o sistema proposto é capaz de compensar adequadamente os movimentos da base estudados. / The Stewart platform mechanism is a parallel manipulator with six degrees of freedom, high load/weight ratio and high stifness. These properties give them a better accuracy when compared to serial manipulators. This work focuses on study of electrohydraucally Stewart Platform Manipulators (MPS) to enable compensation of vessels motions for load and personell transfer in sea. Aimed at developing an experimental prototype, a second MPS is placed underneath the rst MPS to simulate vessels motions and so both manipulators are considered dynamically decoupled. In this sense, the kinematics and dynamics of this manipulator are presented, as well as a mathematical model of the hydraulic actuator. Furthermore, special attention is given to the study of inertial measurement units (IMU) which is used as an instrument for measuring the motion to be compensated. Controller design for the compensation system is developed considering compute torque theory which consider the system separated in two: mechanical and hydraulic. The Lyapunov criteria is used to guarantee closed loop stability for each subsystem. Simulations are performed considering similar vessel motions. Signals provided from a comercial IMU are used for motion compensation. The control compensation performance is veri ed by means of computer simulations. Manipuladores robóticos Atuador hidráulico Modelagem matemática Stewart platform Heave compensation Computed torque control Inertial measurement unit
12	Diseño de un controlador para un vehículo movil Machín, Sofía Valentina January 2017 (has links) El siguiente trabajo busca desarrollar y testear un controlador para un robot móvil con fines agrícolas. Enmarcado en un proyecto más grande, que actualmente desarrolla un prototipo de robot móvil con desplazamiento autónomo para colaborar en las tareas agropecuarias, este trabajo parte de las ecuaciones cinemáticas desarrolladas para este prototipo y desarrolla una estrategia de control mediante torque computado para el desplazamiento autónomo del vehículo en el medio y se realizan simulaciones de las mismas. Realizado este trabajo y obteniendo resultados certeros se deja todo pronto para continuar con la instancia experimental en el prototipo. / The following dissertation tries to develop and test a movil robot controller for agricultural purposes. Framed in a bigger proyect that is currently developing a mobile robot prototype with autonomous movement to help with agricultural work, this work starts in the kinematic equations developed for the prototype and develops a control strategy through computed torque control for the autonomous movement of the vehicle and simulations are performed of such computation. With this work finished and with the results obtained is ready to continue with the experimental instance in the prototype. Robôs móveis Simulação computacional Mobile robot Computed torque control Autonomous movement
13	Torque Modeling and Control of a Variable Compression Engine / Momentmodellering och momentreglering av en variabelkompressionsmotor Bergström, Andreas January 2003 (has links) <p>The SAAB variable compression engine is a new engine concept that enables the fuel consumption to be radically cut by varying the compression ratio. A challenge with this new engine concept is that the compression ratio has a direct influence on the output torque, which means that a change in compression ratio also leads to a change in the torque. A torque change may be felt as a jerk in the movement of the car, and this is an undesirable effect since the driver has no control over the compression ratio. </p><p>The aim of this master's thesis work is to develop a torque control strategy for the SAAB variable compression engine. Where the main control objective is to make the output torque behave in a desirable way despite the influence of compression ratio changes. </p><p>The controller is developed using a design method called Internal Model Control, which is a straightforward way of both configuring a controller and determining its parameters. The controller has been implemented and evaluated in a real engine, and has proved to be able to reduce the effect of compression ratio disturbance.</p> Technology Torque control SVC Variable compression IMC MVEM TEKNIKVETENSKAP TECHNOLOGY TEKNIKVETENSKAP
14	Knock Intensity and Torque Control on an SVC Engine / Reglering av Knackintensitet och Utmoment på en SVC Motor Sinnerstad, Klara January 2004 (has links) <p>Knock is a phenomenon that limits how effciently an engine can operate. Severe knock is harmful to the engine and must therefore be avoided. Controlling the knock intensity is complicated by a phenomenon called cycle to cycle variations. Because of these variations, the knock intensity must be considered a stochastic variable and the control is made on a mean value from a large number of cycles. </p><p>The SVC (Saab Variable Compression) concept adds the compression ratio as an extra degree of freedom. At Vehicular systems, research is done on how to put this additional variable to its best use. </p><p>A controller is developed that control the engine to a desired knock intensity and torque, using the ignition angle and the pedal position. The controller is implemented as two separate controllers in Matlab and Simulink. These are merged together with a Stateflow chart. A confidence interval calculation is implemented for the mean value of the knock intensity. A program is also developed to process a large number of operating points and make measurements in all of them. </p><p>The conclusion is that the basic construction of the controller and the script are fi;lling their functions but that there are some improvements left to be done. The controller is rather slow and the calculations of the confi;dence interval needs further refi;nement.</p> Technology SVC Knock control Torque control Variable compression State&#64258 ow TEKNIKVETENSKAP TECHNOLOGY TEKNIKVETENSKAP
15	A Study of the Torque Control on Manufacturing End-face of the Optical Fiber Cao, Chien-Liang 04 September 2007 (has links) The mechanical grinding processes is the most popular way to fabricate the end face of optical fibers, although there are some other methods like chemical etching and leaser machining. In cases of fabricate the wedge type and wedge-cone type optical fiber end faces, the mechanical grinding is the typical way. Professor Y. C. Tsai¡¦s research group has successfully fabricated the optical fiber with elliptical-cone-type end-face in a single grinding process by adopting a mechanism with eccentric mass on the commercial optical fiber grinding machine. In this study, a torque motor is equipped on the commercial optical fiber grinding machine for controlling the normal pressure between the optical fiber and the grinding film during the grinding process. While the optical fiber rotating, the normal pressure, as well as the material removed rate and the final shape of the optical fiber, can be controlled in different periodical mode shapes by applying different voltages with different periodical mode shapes. The merit of this system is its capability of fabricating fiber with elliptical-cone-shape and polygon-cone-shape (polyhedron-tip) end faces in a single grinding process that will increase the efficiency and the accuracy of grinding. It is believed the grinding machine system developed in this study can be successfully applied for fabricating the optical fiber lenses as well as different types of micro probes for other applications. End-face Torque Control Grinding Processes Grinding Machine Optical Fiber Micro Probe
16	Design and Simulation of Field Oriented Control and Direct Torque Control for a Permanent Magnet Synchronous Motor with Positive Saliency Kronberg, Anders January 2012 (has links) The researchers at the Department of Electricity at Uppsala University has recently entered the field of electric motor design, however no real knowledge of motor control of salient pole permanent magnet motors exists in the department. This thesis will present a general description of the control method of motors that exist today, this has been done by reviewing existing literature. The literature review has shown that there are at least three control methods with a significant different in their control approach, Scalar-, Field Oriented- and Direct Torque- Control. The two last methods were chosen by the author as the most useful and was implemented and simulated together with the newly developed motor in MATLAB Simulink to evaluate their performance. The simulation results show that there is no difference in performance of the two methods, but they show a difference in efficiency. The results show that it's worth to develop both methods further, mainly for reducing the torque and current ripple. This result was not expected according to literature, which suggests that the Field Oriented Control has a lower torque ripple. This could be caused by the choice of hysteresis control for inverter switching, instead of more sophisticated methods with a proportional integral derivative controller (PID) together with Sinusoidal Pulse Width Modulation (SPWM) or Space Vector Modulation (SVM). field oriented control direct torque control salient pole saliency permanent magnet motor
17	Torque Modeling and Control of a Variable Compression Engine / Momentmodellering och momentreglering av en variabelkompressionsmotor Bergström, Andreas January 2003 (has links) The SAAB variable compression engine is a new engine concept that enables the fuel consumption to be radically cut by varying the compression ratio. A challenge with this new engine concept is that the compression ratio has a direct influence on the output torque, which means that a change in compression ratio also leads to a change in the torque. A torque change may be felt as a jerk in the movement of the car, and this is an undesirable effect since the driver has no control over the compression ratio. The aim of this master's thesis work is to develop a torque control strategy for the SAAB variable compression engine. Where the main control objective is to make the output torque behave in a desirable way despite the influence of compression ratio changes. The controller is developed using a design method called Internal Model Control, which is a straightforward way of both configuring a controller and determining its parameters. The controller has been implemented and evaluated in a real engine, and has proved to be able to reduce the effect of compression ratio disturbance. Technology Torque control SVC Variable compression IMC MVEM TEKNIKVETENSKAP TECHNOLOGY TEKNIKVETENSKAP
18	Knock Intensity and Torque Control on an SVC Engine / Reglering av Knackintensitet och Utmoment på en SVC Motor Sinnerstad, Klara January 2004 (has links) Knock is a phenomenon that limits how effciently an engine can operate. Severe knock is harmful to the engine and must therefore be avoided. Controlling the knock intensity is complicated by a phenomenon called cycle to cycle variations. Because of these variations, the knock intensity must be considered a stochastic variable and the control is made on a mean value from a large number of cycles. The SVC (Saab Variable Compression) concept adds the compression ratio as an extra degree of freedom. At Vehicular systems, research is done on how to put this additional variable to its best use. A controller is developed that control the engine to a desired knock intensity and torque, using the ignition angle and the pedal position. The controller is implemented as two separate controllers in Matlab and Simulink. These are merged together with a Stateflow chart. A confidence interval calculation is implemented for the mean value of the knock intensity. A program is also developed to process a large number of operating points and make measurements in all of them. The conclusion is that the basic construction of the controller and the script are fi;lling their functions but that there are some improvements left to be done. The controller is rather slow and the calculations of the confi;dence interval needs further refi;nement. Technology SVC Knock control Torque control Variable compression State&#64258 ow TEKNIKVETENSKAP TECHNOLOGY TEKNIKVETENSKAP
19	Diseño de un controlador para un vehículo movil Machín, Sofía Valentina January 2017 (has links) El siguiente trabajo busca desarrollar y testear un controlador para un robot móvil con fines agrícolas. Enmarcado en un proyecto más grande, que actualmente desarrolla un prototipo de robot móvil con desplazamiento autónomo para colaborar en las tareas agropecuarias, este trabajo parte de las ecuaciones cinemáticas desarrolladas para este prototipo y desarrolla una estrategia de control mediante torque computado para el desplazamiento autónomo del vehículo en el medio y se realizan simulaciones de las mismas. Realizado este trabajo y obteniendo resultados certeros se deja todo pronto para continuar con la instancia experimental en el prototipo. / The following dissertation tries to develop and test a movil robot controller for agricultural purposes. Framed in a bigger proyect that is currently developing a mobile robot prototype with autonomous movement to help with agricultural work, this work starts in the kinematic equations developed for the prototype and develops a control strategy through computed torque control for the autonomous movement of the vehicle and simulations are performed of such computation. With this work finished and with the results obtained is ready to continue with the experimental instance in the prototype. Robôs móveis Simulação computacional Mobile robot Computed torque control Autonomous movement
20	Estudo da concepção de um robô paralelo de três graus de liberdade Almeida, Mateus Vagner Guedes de January 2018 (has links) O mecanismo 3-RPS é um mecanismo paralelo que possui três graus de liberdade: rolagem, arfagem e elevação. Tem vantagem em relação ao custo em comparação com o manipulador Plataforma de Stewart em aplicações onde não são necessários seis graus de liberdade e, por ser um mecanismo paralelo, possui maior relação peso/capacidade de carga que robôs seriais. No presente trabalho, um estudo é realizado para a concepção de um robô do tipo 3-RPS. O estudo aborda a cinemática, a dinâmica e estratégia de controle para o robô. Um controle por torque computado é aplicado a um modelo virtual em ambiente CAD em escala 1:1 desenvolvido com o intuito de testar a estratégia de controle elaborada a partir da realização de simulações computacionais do sistema por completo. Ao todo foram realizadas sete simulações para diferentes condições de trajetórias desejadas. No Caso I executou-se primeiramente um sistema idealizado onde o erro de regime tendeu a zero para um comportamento subamortecido. Os ganhos calculados no Caso I idealizado foram aplicados então no Caso I com o modelo virtual onde verificou-se que os ganhos calculados não foram suficientes para garantir a trajetória desejada do robô. Com os ganhos aumentados em cem vezes, verificou-se que o erro de regime ficou na ordem de 0,22 mm, sendo o valor considerado aceitável. Nas simulações subsequentes, o erro de regime nos Casos II e III foram também de 0,22 mm e nos Casos IV, V, VI e VII o erro máximo de trajetória não ultrapassou os 0,22 mm estipulados. / The 3-RPS mechanism is a parallel mechanism that has three degrees of freedom: roll, pitch and heave. It has a cost advantage compared to the Stewart Platform manipulator in applications where six degrees of freedom are not required and, because it is a parallel mechanism, has a higher weight / load ratio than serial robots. In the present work, a study is carried out for the design of a 3-RPS robot. The study addresses the kinematics, dynamics and control strategy for the robot. A computed torque control is applied to a 1:1 scale virtual CAD model developed with the purpose of testing the control strategy elaborated from the computational simulations of the entire system. Seven simulations were performed for different conditions of desired trajectories. In Case I, an idealized system was first run where the regime error tended to zero for an underdamped behavior. The calculated gains in Case I idealized were then applied in Case I with the virtual model where it was verified that the calculated gains were not enough to guarantee the desired trajectory of the robot. With gains increased by one hundred times, it was found that the regime error was 0.22 mm, and the value was considered acceptable. In the subsequent simulations, the regime error in Cases II and III were also 0.22 mm and in Cases IV, V, VI and VII the maximum error of trajectory did not exceed the stipulated 0.22 mm. Desenvolvimento de produto Robôs paralelos 3-RPS Parallel Robot Computed Torque Control Dynamics Kinematics

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