981 resultados para Direct drive rotational friction welding
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Trabalho apresentado na Conferência CPE-POWERENG 2016, 29 junho a 01 de julho 2016, Bydgoszcz, Polónia
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Direct-drive linear reciprocating compressors offer numerous advantages over conventional counterparts which are usually driven by a rotary induction motor via a crank shaft. However, to ensure efficient and reliable operation under all conditions, it is essential that motor current of a linear compressor follows a sinusoidal current command with a frequency which matches the system resonant frequency. The design of a high-performance current controller for linear compressor drive presents a challenge since the system is highly nonlinear, and an effective solution must be low cost. In this paper, a learning feed-forward current controller for the linear compressors is proposed. It comprises a conventional feedback proportional-integral controller and a feed-forward B-spline neural network (BSNN). The feed-forward BSNN is trained online and in real time in order to minimize the current tracking error. Extensive simulation and experiment results with a prototype linear compressor show that the proposed current controller exhibits high steady state and transient performance. © 2009 IEEE.
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This paper describes a design methodology to achieve optimal performance for a short-stroke single-phase tubular permanent-magnet motor which drives a reciprocating vapor compressor. The steady-state characteristic of the direct-drive linear-motor compressor system is analyzed, an analytical formula for predicting iron loss is presented, and a motor-design procedure which takes into account the effect of compressor loads under nominal operating condition is formulated. It is shown that the motor efficiency can be optimized with respect to two leading dimensional ratios. Experimental results validate the proposed design methodology. Copyright © 2010 IEEE.
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Direct-drive linear reciprocating compressors offer numerous advantages over conventional counterparts which are usually driven by a rotary induction motor via crank shaft However, to ensure efficient and reliable operation under all conditions, it is essential that the motor current of the linear compressor follows a sinusoidal command profile with a frequency which matches the system resonant frequency. This paper describes a hybrid current controller for the linear compressors. It comprises a conventional proportional-integral (PI) controller, and a B-spline neural network compensator which is trained on-line and in real-time in order to minimize the current tracking error under all conditions with uncertain disturbances. It has been shown that the hybrid current controller has a superior steady-state and transient performance over the conventional carrier based PI controller. The performance of the proposed hybrid controller has been demonstrated by extensive simulations and experiments. It has also been shown that the linear compressor operates stably under the current feedback control and the piston stroke can be adjusted by varying the amplitude of the current command. © 2007 IEEE.
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A two degrees of freedom (2-DOF) actuator capable of producing linear translation, rotary motion, or helical motion would be a desirable asset to the fields of machine tools, robotics, and various apparatuses. In this paper, a novel 2-DOF split-stator induction motor was proposed and electromagnetic structure pa- rameters of the motor were designed and optimized. The feature of the direct-drive 2-DOF induction motor lies in its solid mover ar- rangement. In order to study the complex distribution of the eddy current field on the ferromagnetic cylinder mover and the motor’s operating characteristics, the mathematical model of the proposed motor was established, and characteristics of the motor were ana- lyzed by adopting the permeation depth method (PDM) and finite element method (FEM). The analytical and numerical results from motor simulation clearly show a correlation between the PDM and FEM models. This may be considered as a fair justification for the proposed machine and design tools.
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The direct drive point absorber is a robust and efficient system for wave energy harvesting, where the linear generator represents the most complex part of the system. Therefore, its design and optimization are crucial tasks. The tubular shape of a linear generator’s magnetic circuit offers better permanent magnet flux encapsulation and reduction in radial forces on the translator due to its symmetry. A double stator topology can improve the power density of the linear tubular machine. Common designs employ a set of aligned stators on each side of a translator with radially magnetized permanent magnets. Such designs require doubling the amount of permanent magnet material and lead to an increase in the cogging force. The design presented in this thesis utilizes a translator with buried axially magnetized magnets and axially shifted positioning of the two stators such that no additional magnetic material, compared to single side machine, is required. In addition to the conservation of magnetic material, a significant improvement in the cogging force occurs in the two phase topology, while the double sided three phase system produces more power at the cost of a small increase in the cogging force. The analytical and the FEM models of the generator are described and their results compared to the experimental results. In general, the experimental results compare favourably with theoretical predictions. However, the experimentally observed permanent magnet flux leakage in the double sided machine is larger than predicted theoretically, which can be justified by the limitations in the prototype fabrication and resulting deviations from the theoretical analysis.
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Transportbandsyteme werden im Bereich der Intralogistik zur Förderung von Stück- sowie leichten Schüttgütern eingesetzt. Der Antrieb der Transportbänder erfolgt dabei üblicherweise kraftschlüssig über die Antriebstrommel. Der Einsatz von Lineardirektantrieben ermöglicht als Antriebsalternative die Erzeugung der Vorschubkräfte und die Krafteinleitung in das Transportband über der Länge des Lineardirektantriebs verteilt. Dadurch lässt sich die Transportbandvorspannung erheblich reduzieren und damit auch ein leichteres und kostengünstigeres Transportband im Vergleich zu konventionellen Antriebskonzepten verwenden. Basierend auf vorherigen Untersuchungen wurde ein Lineardirektantrieb auf Basis eines Hybridmotors entwickelt, welcher die Vorteile permanentmagneterregter Maschinen mit denen der Reluktanzmotorprinzipien vereint. Auf Grundlage der durch Simulation ermittelten Kraftentfaltkungscharakteristik des Linearmotors auf die Läuferelemente wurden verschiedene Konzepte zur Befestigung dieser Läuferelemente entwickelt, untersucht und erprobt. Aufgrund der Elastizität von Transportbändern sind zudem alternative Führungskonzepte erforderlich, da geometrische Abweichungen der am Transportband befestigten Läuferelemente zu hohen Verlusten durch Reibung führen. Unterschiedliche Führungskonzepte, belegt durch Messungen, geben einen Ausblick auf den linearmotorischen Antrieb.
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Ce mémoire présente la conception, le contrôle et la validation expérimentale d’une boussole haptique servant à diriger les utilisateurs aux prises avec une déficience visuelle, et ce, dans tous les environnements. La revue de littérature décrit le besoin pour un guidage haptique et permet de mettre en perspective cette technologie dans le marché actuel. La boussole proposée utilise le principe de couples asymétriques. Son design est basé sur une architecture de moteur à entraînement direct et un contrôle en boucle ouverte étalonné au préalable. Cette conception permet d’atteindre une vaste plage de fréquences pour la rétroaction haptique. Les propriétés mécaniques de l’assemblage sont évaluées. Puis, l’étalonnage des couples permet d’assurer que le contrôle en boucle ouverte produit des couples avec une précision suffisante. Un premier test avec des utilisateurs a permis d’identifier que les paramètres de fréquence entre 5 et 15 Hz combinés avec des couples au-delà de 40 mNm permettent d’atteindre une efficacité intéressante pour la tâche. L’expérience suivante démontre qu’utiliser une rétroaction haptique proportionnelle à l’erreur d’orientation améliore significativement les performances. Le concept est ensuite éprouvé avec dix-neuf sujets qui doivent se diriger sur un parcours avec l’aide seule de cette boussole haptique. Les résultats montrent que tous les sujets ont réussi à rencontrer tous les objectifs de la route, tout en maintenant des déviations latérales relativement faibles (0:39 m en moyenne). Les performances obtenues et les impressions des utilisateurs sont prometteuses et plaident en faveur de ce dispositif. Pour terminer, un modèle simplifié du comportement d’un individu pour la tâche d’orientation est développé et démontre l’importance de la personnalisation de l’appareil. Ce modèle est ensuite utilisé pour mettre en valeur la stratégie d’horizon défilant pour le placement de la cible intermédiaire actuelle dans un parcours sur une longue distance.
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Synchronous machines with an AC converter are used mainly in large drives, for example in ship propulsion drives as well as in rolling mill drives in steel industry. These motors are used because of their high efficiency, high overload capacity and good performance in the field weakening area. Present day drives for electrically excited synchronous motors are equipped with position sensors. Most drives for electrically excited synchronous motors will be equipped with position sensors also in future. This kind of drives with good dynamics are mainly used in metal industry. Drives without a position sensor can be used e.g. in ship propulsion and in large pump and blower drives. Nowadays, these drives are equipped with a position sensor, too. The tendency is to avoid a position sensor if possible, since a sensor reduces the reliability of the drive and increases costs (latter is not very significant for large drives). A new control technique for a synchronous motor drive is a combination of the Direct Flux Linkage Control (DFLC) based on a voltage model and a supervising method (e.g. current model). This combination is called Direct Torque Control method (DTC). In the case of the position sensorless drive, the DTC can be implemented by using other supervising methods that keep the stator flux linkage origin centered. In this thesis, a method for the observation of the drift of the real stator flux linkage in the DTC drive is introduced. It is also shown how this method can be used as a supervising method that keeps the stator flux linkage origin centered in the case of the DTC. In the position sensorless case, a synchronous motor can be started up with the DTC control, when a method for the determination of the initial rotor position presented in this thesis is used. The load characteristics of such a drive are not very good at low rotational speeds. Furthermore, continuous operation at a zero speed and at a low rotational speed is not possible, which is partly due to the problems related to the flux linkage estimate. For operation in a low speed area, a stator current control method based on the DFLC modulator (DMCQ is presented. With the DMCC, it is possible to start up and operate a synchronous motor at a zero speed and at low rotational speeds in general. The DMCC is necessary in situations where high torque (e.g. nominal torque) is required at the starting moment, or if the motor runs several seconds at a zero speed or at a low speed range (up to 2 Hz). The behaviour of the described methods is shown with test results. The test results are presented for the direct flux linkage and torque controlled test drive system with a 14.5 kVA, four pole salient pole synchronous motor with a damper winding and electric excitation. The static accuracy of the drive is verified by measuring the torque in a static load operation, and the dynamics of the drive is proven in load transient tests. The performance of the drive concept presented in this work is sufficient e.g. for ship propulsion and for large pump drives. Furthermore, the developed methods are almost independent of the machine parameters.
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An acceleration compensated transducer was developed to enable the direct measurement of skin friction in hypervelocity impulse facilities. The gauge incorporated a measurement and acceleration element that employed direct shear of a piezoelectric ceramic. The design integrated techniques to maximize rise time and shear response while minimizing the affects of acceleration, pressure, heat transfer, and electrical interference. The arrangement resulted in a transducer natural frequency near 40 kHz. The transducer was calibrated for shear and acceleration in separate bench tests and was calibrated for pressure within an impulse facility. Uncertainty analyses identified only small experimental errors in the shear and acceleration calibration techniques. Although significant errors were revealed in the method of pressure calibration, total skin-friction measurement errors as low as +/-7-12% were established. The transducer was successfully utilized in a shock tunnel, and sample measurements are presented for flow conditions that simulate a flight Mach number near 8.
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Friction stir welding (FSW) is now well established as a welding process capable of joining some different types of metallic materials, as it was (1) found to be a reliable and economical way of producing high quality welds, and (2) considered a "clean" welding process that does not involve fusion of metal, as is the case with other traditional welding processes. The aim of this study was to determine whether the emission of particles during FSW in the nanorange of the most commonly used aluminum (Al) alloys, AA 5083 and AA 6082, originated from the Al alloy itself due to friction of the welding tool against the item that was being welded. Another goal was to measure Al alloys in the alveolar deposited surface area during FSW. Nanoparticles dimensions were predominantly in the 40- and 70-nm range. This study demonstrated that microparticles were also emitted during FSW but due to tool wear. However, the biological relevance and toxic manifestations of these microparticles remain to be determined.
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Este é um projeto I&D interno do INEGI, com as unidades DPS e LOME, que tem em vista a utilização de componentes disponíveis no INEGI para o estudo de um equipamento capaz de efetuar soldaduras por Friction Stir Welding. O equipamento já conta com controlo numérico para um sistema de três eixos e os respetivos motores, ficando assim encarregue de tirar o máximo proveito possível destes componentes. Este equipamento terá como finalidade munir o INEGI com um equipamento capaz de dar resposta a eventuais projetos externos/internos bem como para fins de investigação para a melhoria da qualidade do processo de soldadura. A conceção deste equipamento tem a particularidade das condições envolventes do processo nomeadamente os esforços desenvolvidos durante o processo de soldadura, em particular a força vertical (eixo da ferramenta) que é necessária fazer de forma a evitar a ascensão de material da junta de soldadura. A soldadura por Friction Stir Welding, é um processo de soldadura relativamente actual, desenvolvido em 1991 por Wayne Thomas pelo The Welding Institute que se sobrepõe aos métodos de soldadura convencionais, uma vez que não necessita de levar o/os materiais acima da sua temperatura de fusão, sendo um processo de soldadura no estado solido, o material não chega a fundir. Este processo consiste na utilização de uma ferramenta em rotação que que se desloca ao longo da junta de soldadura, que uma vez a fricção gerada entre a ferramenta e o material base gera calor que promove o aquecimento e quase fusão do material base. A ligação do material dá-se aquando a passagem da ferramenta na junta, misturando os materiais. Com o recurso a este método de fabrico é possível efetuar soldaduras com grande qualidade em materiais considerados de difícil soldabilidade pelos métodos convencionais, como por exemplo o Alumínio. Neste projecto foram estudadas varias soluções, contactados vários fornecedores e com o seu feedback foi desenvolvido o equipamento. Este projecto consiste essencialmente na análise estrutural e selecção de equipamentos. O equipamento final resultou de uma série de iterações e ideias de forma a optimizar toda estrutura para a magnitude dos esforços envolvidos, obtendo no final um equipamento capaz de cumprir os requisitos. No final prevêse um equipamento com a capacidade de suportar esforços verticais de 50
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Dissertação para a obtenção do grau de Mestre em Engenharia Mecânica
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Synchronous motors are used mainly in large drives, for example in ship propulsion systems and in steel factories' rolling mills because of their high efficiency, high overload capacity and good performance in the field weakening range. This, however, requires an extremely good torque control system. A fast torque response and a torque accuracy are basic requirements for such a drive. For large power, high dynamic performance drives the commonly known principle of field oriented vector control has been used solely hitherto, but nowadays it is not the only way to implement such a drive. A new control method Direct Torque Control (DTC) has also emerged. The performance of such a high quality torque control as DTC in dynamically demanding industrial applications is mainly based on the accurate estimate of the various flux linkages' space vectors. Nowadays industrial motor control systems are real time applications with restricted calculation capacity. At the same time the control system requires a simple, fast calculable and reasonably accurate motor model. In this work a method to handle these problems in a Direct Torque Controlled (DTC) salient pole synchronous motor drive is proposed. A motor model which combines the induction law based "voltage model" and motor inductance parameters based "current model" is presented. The voltage model operates as a main model and is calculated at a very fast sampling rate (for example 40 kHz). The stator flux linkage calculated via integration from the stator voltages is corrected using the stator flux linkage computed from the current model. The current model acts as a supervisor that prevents only the motor stator flux linkage from drifting erroneous during longer time intervals. At very low speeds the role of the current model is emphasised but, nevertheless, the voltage model always stays the main model. At higher speeds the function of the current model correction is to act as a stabiliser of the control system. The current model contains a set of inductance parameters which must be known. The validation of the current model in steady state is not self evident. It depends on the accuracy of the saturated value of the inductances. Parameter measurement of the motor model where the supply inverter is used as a measurement signal generator is presented. This so called identification run can be performed prior to delivery or during drive commissioning. A derivation method for the inductance models used for the representation of the saturation effects is proposed. The performance of the electrically excited synchronous motor supplied with the DTC inverter is proven with experimental results. It is shown that it is possible to obtain a good static accuracy of the DTC's torque controller for an electrically excited synchronous motor. The dynamic response is fast and a new operation point is achieved without oscillation. The operation is stable throughout the speed range. The modelling of the magnetising inductance saturation is essential and cross saturation has to be considered as well. The effect of cross saturation is very significant. A DTC inverter can be used as a measuring equipment and the parameters needed for the motor model can be defined by the inverter itself. The main advantage is that the parameters defined are measured in similar magnetic operation conditions and no disagreement between the parameters will exist. The inductance models generated are adequate to meet the requirements of dynamically demanding drives.
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A direct-driven permanent magnet synchronous machine for a small urban use electric vehicle is presented. The measured performance of the machine at the test bench as well as the performance over the modified New European Drive Cycle will be given. The effect of optimal current components, maximizing the efficiency and taking into account the iron loss, is compared with the simple id=0 – control. The machine currents and losses during the drive cycle are calculated and compared with each other.
