Global ETD Search

81	A numerical study of micro flow and its applications on thermal energy conversion and water desalination. / CUHK electronic theses & dissertations collection January 2010 (has links) (1) A new model for the mass transfer in Direct Contact Membrane Distillation (DCMD) process is developed. The model is based on Direct Simulation Monte Carlo (DSMC) method. It avoids the over simplification of the resistance mechanisms and hence, give more accurate prediction. The model is validated by means of experiments. The influences of the main parameters in DCMD are also studied, including temperature difference between the feed side and the permeate side, the membrane's thickness and the pore size. Moreover, it is proposed to use aerogel as the membrane material. It is shown that the aerogel's hydrophobic property, low thermal conductivity and high porosity offer a much improved performance over the commonly used membrane material PTFE. The fresh water productivity can reach 10.0 kg/m2 per day. / (2) A new energy harvesting method for converting thermal energy to kinetic energy is proposed. This method is based on the rarefied gas phenomenon called Knudsen effect. By Knudsen effect, a gas flow can be generated from temperature difference. In order to generate Knudsen effect, a special material, aerogel, is used. It is a porous material full of holes of dozens of nanometers. Using Direct Simulation Monte Carlo (DSMC) simulation, it is shown that Knudsen effect still works under atmosphere pressure with aerogel material. Accordingly, a device is designed. Based on the numerical simulation, the device can generate about 70 W kinetic energy when driven by a solar panel with intensity of 1 kW/m2. / (3) A solar desalination system is designed. This system is based on a combination of Knudsen compressor and simple solar still. The Knudsen effect is generated from the aerogel driven by solar radiation. As a result, the system operates at lower pressure resulting in enhanced water evaporation process. Based on the simulation, the evaporation rate is significantly increased. It is found that in a typical summer day in tropic region like Hong Kong, such a system can generate about 5 kg fresh water per 1 m2 solar still per day. This number is about 30% higher than the simple direct solar still. Moreover, the proposed technology can be readily combined with other technologies such as condensation heat recovery to further improve the fresh water productivity. The optimal working condition is also studied. / Energy and water are two of the most important issues in the world today. The social and economic health of the world depends on sustainable supply of both energy and water. Especially, these two critical resources are always inextricably linked. To solve the emerging crisis of energy and water, renewable energy technologies is the key. On the other hand, recent advances in Micro-Electro-Mechanical Systems (MEMS) technology have opened new ways for us to use micro/nano scale physical and chemical effects. It is no doubted that the combination of the renewable energy technologies and micro/nano technologies will have great potential and there are plenty of room to explore. / The research presented in this thesis focuses on extending the micro scale effect to the macroscopic applications. Based on this idea, a new energy harvesting method and two new water desalination technologies are proposed, with computer simulations and experiment validations. These include: / Zhang, Peng. / Adviser: Ruxu Du. / Source: Dissertation Abstracts International, Volume: 72-04, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2010. / Includes bibliographical references (leaves 123-135). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. Ann Arbor, MI : ProQuest Information and Learning Company, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese. Energy conversion Energy harvesting Fluid mechanics Micromechanics Saline water conversion
82	Estudio experimental de un sistema tipo Wake Galloping para distintas geometrías generadoras de vórtices Bellei Pardo, Andrés January 2017 (has links) Ingeniero Civil Mecánico / El cosechamiento de energía, proveniente del inglés energy harvesting, es el proceso a través del cual se captura pequeñas cantidades de energía que de otro modo se perderían como calor, luz, sonido, vibración o movimiento. Esta energía puede ser utilizada en distintas aplicaciones, por ejemplo reinyectándose en sistemas que la estén perdiendo o reemplazando baterías en pequeños equipos electrónicos de baja potencia, tales como sensores de monitoreo remoto. En la presente memoria se estudia un sistema vibratorio del tipo wake galloping, con el objetivo de investigar experimentalmente el efecto de la geometría del generador de vórtices de sección cuadrada y tipo placa plana en la potencia obtenida. Para llevar a cabo dicho objetivo se plantean los siguientes objetivos específicos: implementar modificaciones al montaje experimental existente y validar el procedimiento experimental reproduciendo curva de aceleración y frecuencia versus velocidad del viento para el generador de vórtices cilíndrico de sección circular, estimar la potencia obtenida usando como generador de vórtices un cilindro de sección cuadrada y estimar la potencia obtenida usando como generador de vórtices una placa plana. Este sistema, a escala pequeña, puede aprovecharse por ejemplo en túneles de trenes subterráneos, alimentando sensores de monitoreo remotos, pudiendo clasificarse como un sistema de cosechamiento de energía. Las variables en estudio para cada geometría fueron: la velocidad del viento, y la razón de aspecto en distancia X=L⁄D, donde D es el diámetro del cilindro móvil y L es la distancia entre dicho cilindro y el generador de vórtices. Para el cilindro de sección cuadrada además se varía el ángulo de inclinación del mismo con respecto al flujo incidente. Se midió experimentalmente la aceleración del cuerpo vibratorio por medio de acelerómetros instalados al centro del mismo. A partir de los resultados obtenidos, se encuentra que la potencia máxima alcanzada es de ≈312 [mW], utilizando como generador de vórtices un cilindro cuadrado rotado en 12°, a una razón de distancia X=3 y a una velocidad de viento de 7 [m/s]. Para todos los generadores de vórtices estudiados, la máxima potencia se alcanza a la mayor velocidad de viento utilizada: 7 [m/s]. Aunque no es posible establecer un patrón que determine qué distancia X maximiza las potencias obtenidas, se observa sin embargo una tendencia en que los mayores valores de potencia se agrupan en el rango 5≤X≤7 para todos los generadores de vórtices. Energía mecánica Ensayos de vibración Energy harvesting Wake Galloping
83	Antennas and Metamaterials for Electromagnetic Energy Harvesting Almoneef, Thamer 03 August 2012 (has links) The emergence of microwave energy harvesting systems, commonly referred to as rectenna or Wireless Power Transfer (WPT) systems, has enabled numerous applications in many areas since their primary goal is to recycle the ambient microwave energy. In such systems, microstrip antennas are used as the main source for collecting the electromagnetic energy. In this work, a novel collector based on metamaterial particles, in what is known as a Split Ring Resonator (SRR), to harvest electromagnetic energy is presented. Such collectors are much smaller in size and more efficient than existing collectors (antennas). A feasibility study of SRRs to harvest electromagnetic energy is conducted using a full wave simulator (HFSS). To prove the concept, a 5.8 GHz SRR is designed and fabricated and then tested using a power source, an Infiniium oscilloscope and a commercially available patch antenna array. When excited by a plane wave with an H-field normal to the structure, a voltage build up of 611 mV is measured across a surface mount resistive load inserted in the gap of a single loop SRR. In addition, a new efficiency concept is introduced, taking into account the microwave-to-AC conversion efficiency which is missing from earlier work. Finally, a 9X9 SRR array is compared with a 2X2 patch antenna array, both placed in a fixed footprint. The simulation results show that the array of SRRs can harvest electromagnetic energy more efficiently and over a wider bandwidth range. metamaterials Energy Harvesting Rectenna Wireless power transfer Electrical and Computer Engineering
84	Modeling, Analysis and Experimental Validation of a Three Degree of Freedom Electromagnetic Energy Harvester Chen, Yan January 2012 (has links) Vibration energy harvesting devices have been widely used to power many electronic self-sustainable devices. The aim of this study is to introduce an alternative design to an existing electromagnetic energy harvesting devices to improve the power production of the unit. This thesis presents a multiple degree of freedom compared design and it has demonstrated higher power efficiency over a wider range of frequencies. The power outputs for both the previous single degree of freedom and the current designs are compared and the developed models are validated against their experimental values. Finally, the numerical model is used to find an optimal arrangement to produce the maximum power for the unit. Energy Harvesting Electromagnetic Low Frequency Multiple degree of freedom Mechanical Engineering
85	Evaluating vehicular-induced vibrations of typical highway bridges for energy harvesting applications Reichenbach, Matthew Craig 18 June 2012 (has links) Highway bridges are vital links in any transportation network. Identifying the possible safety problems in the approximately 600,000 bridges across the U.S. is generally accomplished through labor-intensive, visual inspections. Wireless monitoring technology seeks to improve current practices by supplementing the visual inspections with real-time evaluation of bridges. To be economically feasible, wireless sensor networks should be able to (a) operate independent of the power grid, and (b) achieve a service life of at least ten years. Novel energy harvesting approaches have been investigated to fulfill these two criteria. In particular, the feasibility of a vibration energy harvester as a long-term power source was assessed. The goal of the research was to process measured acceleration data and analyze the vibrational response of typical highway bridges under truck loads. The effects of ambient temperature, truck traffic patterns, and harvester position on the power content of the vibrations were explored, as well as the effects of linear and nonlinear harvesters. This thesis presents the results of evaluating the response of five steel bridges in Texas and Oregon for energy harvesting applications. / text Steel bridges Vibration Energy harvesting Structural health monitoring
86	Photovoltaic (PV) and fully-integrated implantable CMOS ICs Ayazianmavi, Sahar 12 July 2012 (has links) Today, there is an ever-growing demand for compact, and energy autonomous, implantable biomedical sensors. These devices, which continuously collect in vivo physiological data, are imperative in the next generation patient monitoring systems. One of the fundamental challenges in their implementation, besides the obvious size constraints and the tissue-to-electronics biocompatibility impediments, is the efficient means to wirelessly deliver power to them. This work addresses this challenge by demonstrating an energy-autonomous and fully-integrated implantable sensor chip which takes advantage of the existing on-chip photodiodes of a standard CMOS process as photovoltaic (PV) energy-harvesting cells. This 2.5 mm × 2.5 mm chip is capable of harvesting [mu]W’s of power from the ambient light passing through the tissue and performing real-time sensing. This system is also MRI compatible as it includes no magnetic material and requires no RF coil or antennae. In this dissertation, the optical properties of tissue and the capabilities of the CMOS integrated PV cells are studied first. Next, the implementation of an implantable sensor using such PV devices is discussed. The sensor characterizing and the in vitro measurement results using this system, demonstrate the feasibility of monolithically integrated CMOS PV-driven implantable sensors. In addition, they offer an alternative method to create low-cost and mass-deployable energy autonomous ICs in biomedical applications and beyond. / text Energy harvesting CMOS Photovoltaic cell Neuromorphic Implantable device Sub-threshold
87	Rotating dynamics of pendula systems for energy harvesting from ambient vibrations Najdecka, Anna January 2013 (has links) This thesis has been motivated by the idea of harvesting the energy from ambient vibrations via nonlinear dynamics of the parametric pendulum. It aims to cover those aspects of the pendulum dynamics, which are relevant for energy extraction purposes and have not been addressed in previous studies. A simple system like parametric pendulum can experience variety of responses. One of them is rotary motion, which is characterised by significantly higher kinetic energy than oscillations and thus has a potential of delivering more energy, when subjected to the parametric excitation. Initially, a preliminary study on the dynamics of parametric pendulum has been conducted. This involved comparison of oscillatory and rotary responses with a view to application in energy harvesting, numerical continuation of rotary solutions and developing a control method for initiating and maintaining the desired response. As a next step, different forcing configurations have been considered, including pendulum excited along a tilted axis and a combined excitation, where pendulum additionally performs rocking action. The influence of the forcing arrangement on the lower limit of stability of rotary motion has been examined. The vibrations which can be observed in the environment are rarely perfectly harmonic. To provide more realistic results, the response of the pendulum under noisy excitation has been studied. Different types of noise have been considered and their influence on the pendulum rotation examined. One of the major energy sources, which could be utilised are the oscillating ocean surfaces. Therefore, a stochastic model of the sea wave has been constructed and the response of the pendulum system studied under parametric excitation by a wave profile. Finally, taking into account the imbalanced forces which rotating pendulum exerts on the supporting base, the model has been extended to a system of two pendulums. Synchronization in such a system was studied. The influence of the synchronization mode on the rotation of the pendulums and on the stability of supporting structure was considered. All of the numerical results presented in this thesis have been verified experimentally to ensure good correspondence. 620
88	外力を受ける非線形振動子のエネルギー収集特性 / Energy Harvesting Characteristics of Nonlinear Oscillators under Excitation 窪田, まど華 23 March 2015 (has links) Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第18991号 / 工博第4033号 / 新制\|\|工\|\|1621 / 31942 / 京都大学大学院工学研究科電気工学専攻 / (主査)教授引原隆士, 教授土居伸二, 教授小林哲生 / 学位規則第4条第1項該当 energy harvesting nonlinear dynamics synchronization coupled oscillator stochastic resonance 500
89	Harvesting wind energy using a galloping piezoelectric beam Mahadik, Rohan Ram 12 July 2011 (has links) Galloping of structures such as transmission lines and bridges is a classical aeroelastic instability that has been considered as harmful and destructive. However, there exists potential to harness useful energy from this phenomenon. The study presented in this paper focuses on harvesting wind energy that is being transferred to a galloping beam. The beam has a rigid prismatic tip body. Triangular and D-section are the two kinds of cross section of the tip body that are studied, developed and tested. Piezoelectric sheets are bonded on the top and bottom surface of elastic portion of the beam. During galloping, vibrational motion is input to the system due to aerodynamic forces acting on the tip body. This motion is converted into electrical energy by the piezoelectric (PZT) sheets. A potential application for this device is to power wireless sensor networks on outdoor structures such as bridges and buildings. The relative importance of various parameters of the system such as wind speed, material properties of the beam, electrical load, beam natural frequency and aerodynamic geometry of the tip body is discussed. A model is developed to predict the dynamic response, voltage and power results. Experimental investigations are performed on a representative device in order to verify the accuracy of the model as well as to study the feasibility of the device. A maximum output power of 1.14 mW was measured at a wind velocity of 10.5 mph. / text Galloping Vibration Piezoelectric Cantilever beam Wind energy Energy harvesting Aerodynamic
90	DIGITALLY CONTROLLED ENERGY HARVESTING POWER MANAGEMENT SYSTEM DICKSON, ANDREW 20 March 2012 (has links) This thesis discusses a power electronics module (PEM) that is used to extract power from a human energy harvesting generator according to the user’s desired input power, and stores all of the extracted energy into an appropriately sized battery while staying within the charging limitations of the battery. The PEM can temporarily store the peak power produced by the generator allowing the reduction in the size of the battery required to the average power production level of the generator. The battery’s safety and longevity is maintained by charging them at the constant current and constant voltage rate. The design of the two-stage PEM, the requirements of the Energy Storage Capacitor (ESC) and battery size are discussed. The two controllers that control the PEM are explained and the different operating modes of the controllers are reviewed. A two-stage prototype digitally controlled average current mode control Boost converter and average current mode controlled Buck converter were designed and experimental waveforms were captured to test and validate the control theories used in the PEM. A Voltage Adaptive Gain compensator was used to optimize the closed loop response of both the Boost and Buck converters over their respective output and input voltage ranges. The DC efficiency of the prototype was measured with the peak efficiency of the Boost converter equal to 93% and the peak efficiency of the Buck converter measured at 93.7%. The total PEM system efficiency was measured at 87.9% at an input power level of 10 watts. The AC efficiency of the PEM was also measured with a peak efficiency of 91% with Vin = 15 V at Rin = 60 Ω. The software considerations for an embedded system, including power consumption and timing of real time events are reviewed. A software flow chart and timing diagram are provided to help visualize the sequence of the code. A design chart for selection of the size and voltage rating of the ESC was created. An experimental comparison of a single stage design without energy storage capability and the current PEM design was performed, with a power limited source, in order to show the effectiveness of the PEM and controllers at maximizing the power extraction from the generator. The PEM design was able to extract 50% more power than the single stage converter without energy storage capability. / Thesis (Master, Electrical & Computer Engineering) -- Queen's University, 2012-03-20 01:25:20.986 power electronics digital control Voltage Adaptive Gain energy harvesting

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