Integration of Radio Frequency Harvesting with Low Power Sensors

DeLong, Brock J.

17 September 2018

No description available.

Electrical Engineering

Electromagnetics

power harvesting

wireless power

WPT

medical devices

wireless power transfer

wireless power transmission

6.78MHz Omnidirectional Wireless Power Transfer System for Portable Devices Application

Feng, Junjie

11 January 2021

Wireless power transfer (WPT) with loosely coupled coils is a promising solution to deliver power to a battery in a variety of applications. Due to its convenience, wireless power transfer technology has become popular in consumer electronics. Thus far, the majority of the coupled coils in these systems are planar structure, and the magnetic field induced by the transmitter coil is in one direction, meaning that the energy power transfer capability degrades greatly when there is some angle misalignment between the coupled coils. To improve the charging flexibility, a three–dimensional (3D) coils structure is proposed to transfer energy in different directions. With appropriate modulation current flowing through each transmitter coil, the magnetic field rotates in different directions and covers all the directions in 3D space. With omnidirectional magnetic field, the charging platform can provide energy transfer in any direction; therefore, the angle alignment between the transmitter coil and receiver coil is no longer needed. Compensation networks are normally used to improve the power transfer capability of a WPT system with loosely coupled coils. The resonant circuits, formed by the loosely coupled coils and external compensation inductors or capacitors, are crucial in the converter design. In WPT system, the coupling coefficient between the transmitting coil and the receiving coil is subject to the receiver's positioning. The variable coupling condition is a big challenge to the resonant topology selection. The detailed requirements of the resonant converter in an omnidirectional WPT system are identified as follows: 1). coupling independent resonant frequency; 2). load independent output voltage; 3). load independent transmitter coil current; 4). maximum efficiency power transfer; 5). soft switching of active devices. A LCCL-LC resonant converter is derived to satisfy all of the five requirements. In consumer electronics applications, Megahertz (MHz) WPT systems are used to improve the charging spatial freedom. 6.78 MHz is selected as the system operation in AirFuel standard, a wireless charging standard for commercial electronics. The zero voltage switching (ZVS) operation of the switching devices is essential in reducing the switching loss and the switching related electromagnetic interference (EMI) issue in a MHz system; therefore, a comprehensive evaluation of ZVS condition in an omnidirectional WPT system is performed. And a design methodology of the LCCL-LC converter to achieve ZVS operation is proposed. The big hurdle of the WPT technology is the safety issue related to human exposure of electromagnetic fields (EMF). A double layer shield structure, including a magnetic layer and a conductive layer, is proposed in a three dimensional charging setup to reduce the stray magnetic field level. A parametric analysis of the double shield structure is conducted to improve the attenuation capability of the shielding structure. In an omnidirectional WPT system, the energy can be transferred in any direction; however the receiving devices has its preferred field direction based on its positioning and orientation. To focus power transfer towards targeted loads, a smart detection algorithm for identifying the positioning and orientation of receiver devices based on the input power information is presented. The system efficiency is further improved by a maximum efficiency point tracking function. A novel power flow control with a load combination strategy to charge multiple loads simultaneously is explained. The charging speed of the omnidirectional WPT system is greatly improved with proposed power flow control. / Doctor of Philosophy / Wireless power transfer (WPT) is a promising solution to deliver power to a battery in a variety of applications. Due to its convenience, wireless power transfer technology with loosely coupled coils has become popular in consumer electronics. In such system, the receiving coil embedded in the receiving device picks up magnetic field induced by the transmitter coil; therefore, energy is transferred through the magnetic field and contactless charging is achieved. Thus far, the majority of the coupled coils in these systems are planar structure, and the magnetic field induced by the transmitter coil is in one direction, meaning that the energy power transfer capability degrades greatly when there is some angle misalignment between the coupled coils. To improve the charging flexibility, a three–dimensional (3D) coils structure is proposed to transfer energy in different directions, also known as in omnidirectional manner. With omnidirectional magnetic field, the charging platform can provide energy transfer in any direction; therefore, the angle alignment between the transmitter coil and receiver coil is no longer needed. In a WPT system with loosely coupled coils, the energy transfer capability suffers from weak coupling condition. To improve the power transfer capability, the electrical resonance concept between the inductor and capacitor at the power transfer frequency is adopted. A novel compensation network is proposed to form a resonant tank with the loosely coupled coils and maximize the power transfer at the operating frequency. As for the WPT system with loosely coupled coils, the energy transfer capability is also proportional to the operating frequency. Therefore, Megahertz (MHz) WPT systems are used to improve the charging spatial freedom. 6.78 MHz is selected as the system operation in AirFuel standard, a wireless charging standard for commercial electronics. The zero voltage switching (ZVS) operation of the switching devices is essential in reducing the switching loss and the switching related electromagnetic interference (EMI) issue in a MHz system; therefore, a comprehensive evaluation of ZVS condition in an omnidirectional WPT system is performed. The big hurdle of the WPT technology is the safety concern related to human exposure of electromagnetic fields (EMF). Therefore, a double layer shield structure is first applied in a three dimensional charging setup to confine the electromagnetic fields effectively. The stray field level in our charging platform is well below the safety level required by the regulation agent. Although the energy can be transferred in an omnidirectional manner in the proposed charging platform, the energy should be directed to the target loads to avoid unnecessary energy waste. Therefore, a smart detection method is proposed to detect the receiver coil's orientation and focus the energy transfer to certain direction preferred by the receiver in the setup. The energy beaming strategy greatly improves the charging speed of the charging setup.

Omnidirectional

Wireless power transfer

magnetic field

resonant converter

high frequency

soft-switching

shielding

Protection, Control, and Auxiliary Power of Medium-Voltage High-Frequency SiC Devices

Sun, Keyao

09 June 2021

Due to the superior characteristics compared to its silicon (Si) counterpart, the wide bandgap (WBG) semiconductor enables next-generation power electronics systems with higher efficiency and higher power density. With higher blocking voltage available, WBG devices, especially the silicon carbide (SiC) metal-oxide-semiconductor field-effect transistor (MOSFET), have been widely explored in various medium-voltage (MV) applications in both industry and academia. However, due to the high di/dt and high dv/dt during the switching transient, potential overcurrent, overvoltage, and gate failure can greatly reduce the reliability of implementing SiC MOSFETs in an MV system. By utilizing the parasitic inductance between the Kelvin- and the power-source terminal, a short-circuit (SC) and overload (OL) dual-protection scheme is proposed for overcurrent protection. A full design procedure and reliability analysis are given for SC circuit design. A novel OL circuit is proposed to protect OL faults at the gate-driver level. The protection procedure can detect an SC fault within 50 nanoseconds and protect the device within 1.1 microsecond. The proposed method is a simple and effective solution for the potential overcurrent problem of the SiC MOSFET. For SiC MOSFETs in series-connection, the unbalanced voltages can result in system failure due to device breakdown or unbalanced thermal stresses. By injecting current during the turn-off transient, an active dv/dt control method is used for voltage balancing. A 6 kV phase-leg using eight 1.7 kV SiC MOSFETs in series-connection has been tested with voltage balanced accurately. Modeling of the stacked SiC MOSFET with active dv/dt control is also done to summarize the design methodology for an effective and stable system. This method provides a low-loss and compact solution for overvoltage problems when MV SiC MOSFETs are connected in series. Furthermore, a scalable auxiliary power network is proposed to prevent gate failure caused by unstable gate voltage or EMI interference. The two-stage auxiliary power network (APN) architecture includes a wireless power transfer (WPT) converter supplied by a grounded low voltage dc bus, a high step-down-ratio (HSD) converter powered from dc-link capacitors, and a battery-based mini-UPS backup power supply. The auxiliary-power-only pre-charge and discharge circuits are also designed for a 6 kV power electronics building block (PEBB). The proposed architecture provides a general solution of a scalable and reliable auxiliary power network for the SiC-MOSFET-based MV converter. For the WPT converter, a multi-objective optimization on efficiency, EMI mitigation, and high voltage insulation capability have been proposed. Specifically, a series-series-CL topology is proposed for the WPT converter. With the optimization and new topology, a 120 W, 48 V to 48 V WPT converter has been tested to be a reliable part of the auxiliary power network. For the HSD converter, a novel unidirectional voltage-balancing circuit is proposed and connected in an interleaved manner, which provides a fully modular and scalable solution. A ``linear regulator + buck" solution is proposed to be an integrated on-board auxiliary power supply. A 6 kV to 45 V, 100 W converter prototype is built and tested to be another critical part of the auxiliary power network. / Doctor of Philosophy / The wide bandgap semiconductor enables next-generation power electronics systems with higher efficiency and higher power density which will reduce the space, weight, and cost for power supply and conversion systems, especially for renewable energy. However, by pushing the system voltage level higher to medium-voltage of tens of kilovolts, although the system has higher efficiency and simpler control, the reliability drops. This dissertation, therefore, focusing on solving the possible overcurrent, overvoltage, and gate failure issues of the power electronics system that is caused by the high voltage and high electromagnetic interference environment. By utilizing the inductance of the device, a dual-protection method is proposed to prevent the overcurrent problem. The overcurrent fault can be detected within tens of nanoseconds so that the device will not be destroyed because of the huge fault current. When multiple devices are connected in series to hold higher voltage, the voltage sharing between different devices becomes another issue. The proposed modeling and control method for series-connected devices can balance the shared voltage, and make the control system stable so that no overvoltage problem will happen due to the non-evenly distributed voltages. Besides the possible overcurrent and overvoltage problems, losing control of the devices due to the unreliable auxiliary power supply is another issue. This dissertation proposed a scalable auxiliary power network with high efficiency, high immunity to electromagnetic interference, and high reliability. In this network, a wireless power transfer converter is designed to provide enough insulation and isolation capability, while a switched capacitor converter is designed to transfer voltage from several kilovolts to tens of volts. With the proposed overcurrent protection method, voltage sharing control, and reliable auxiliary power network, systems utilizing medium-voltage wide-bandgap semiconductor will have higher reliability to be implemented for different applications.

SiC MOSFET

medium voltage

protection

active control

auxiliary power supply

wireless power transfer

switched capacitor converter

Implanted Antennas and Intra-Body Propagation Channel for Wireless Body Area Network

Ibraheem, Ali Ahmed Younis

25 November 2014

Implanted Devices are important components of the Wireless Body Area Network (WBAN) as a promising technology in biotelemetry, e-health care and hyperthermia applications. The design of WBAN faces many challenges, such as frequency band selection, channel modeling, antenna design, physical layer (PHY) protocol design, medium access control (MAC) protocol design and power source. This research focuses on the design of implanted antennas, channel modeling between implanted devices and Wireless Power Transfer (WPT) for implanted devices. An implanted antenna needs to be small while it maintains Specific Absorption Rate (SAR) and is able to cope with the detuning effect due to the electrical properties of human body tissues. Most of the proposed antennas for implanted applications are electric field antennas, which have a high near-zone electric field and, therefore, a high SAR and are sensitive to the detuning effect. This work is devoted to designing a miniaturized magnetic field antenna to overcome the above limitations. The proposed Electrically Coupled Loop Antenna (ECLA) has a low electric field in the near-zone and, therefore, has a small SAR and is less sensitive to the detuning effect. The performance of ECLA, channel model between implanted devices using Path Loss (PL) and WPT for implanted devices are studied inside different human body models using simulation software and validated using experimental work. The study is done at different frequency bands: Medical Implanted Communication Services (MICS) band, Industrial Scientific and Medical (ISM) band and 3.5 GHz band using ECLA. It was found that the proposed ECLA has a better performance compared to the previous designs of implanted antennas. Based on our study, the MICS band has the best propagation channel inside the human body model among the allowed frequency bands. The maximum PL inside the human body between an implanted antenna and a base station on the surface is about 90 dB. WPT for implanted devices has been investigated as well, and it has been shown that for a device located at 2 cm inside the human body with an antenna radius of 1 cm an efficiency of 63% can be achieved using the proposed ECLA. / Ph. D.

Electrically Small Antenna

Specific Absorption Rate

Electrically Coupled Loop Antenna

Path Loss

Wireless Power Transfer

Design of a Wireless Power Transfer System using Electrically Coupled Loop Antennas

Chandrasekhar Nambiar, Shyam

01 July 2015

Wireless Power Transfer (WPT) has become quite popular over the recent years. This thesis presents some design challenges while developing a WPT system and describes a system-level methodology for designing an end-to-end system. A critical analysis of contemporary research is performed in the form of a literature survey of both academic and commercial research to understand their benefits and demerits. Some theoretical notes are presented on coupled-mode theory and coupled filter theory and the problems concerning WPT analyzed using these models. The need for higher power transfer efficiency (PTE) and power delivered to load (PDL) is studied using these models. The case for using magnetic antennas over electric antennas when surrounded by lossy media (specifically for the case of human body tissues at various frequencies) is made using some theoretical models and simulation results. An Electrically Coupled Loop Antenna (ECLA) is introduced, studied and designed for two main WPT applications, viz. free space transmission and that of powering implanted devices. An equivalent circuit is proposed to better understand the coupling effects of the antennas on a circuit level and to study the effect of various environmental and structural factors on the coupling coefficient. Some prototypes were created and measured for the two use cases of free space and implanted applications. In order to complete the system design, a negative resistance-based oscillator is designed and fabricated, that incorporates the antennas as a load and oscillates at the required frequency. Some changes in load conditions and power handling are studied by the use of two circuits for free-space (high-power) and implanted (low-power) applications. Finally, the salient points of the thesis are re-iterated and some future work outlined in the concluding chapter. / Master of Science

Wireless power transfer

Implanted antennas

Electrically Coupled Loop Antenna

Negative resistance oscillators

Wireless Power Transfer : Machine Learning Assisted Characteristics Prediction for Effective Wireless Power Transfer Systems / Trådlös kraftöverföring : Maskininlärning Assisterade egenskaper Förståelse för effektiva trådlösa kraftöverföringssystem

Al Mahmud, Shamsul Arefeen

January 2020

One of the main challenges in wireless power transfer (WPT) devices is performance degradation when the receiver’s position and characteristics vary. The variations in the system parameters such as load impedance and coupling strength in WPT devices affect performance characteristics such as output voltage and power. When the system parameters are different from the optimal operating conditions, the performances are degraded. Therefore, the load impedance and coupling strength must be monitored to do the necessary optimization and control. However, such control approaches require additional sensing circuits and a data communication link between transmitter- and receiver-sides. This study proposes a new machine learning (ML) assisted WPT system that predicts the power delivered to the receiver by only using measurements at the transmitter-side. In addition, a method is also proposed to estimate load impedance and coupling coefficient using machine learning approach. We study what parameters measurable at the transmitter-side can be used to predict the output power delivered to receivers at variable load impedance and coupling strengths. In the proposed method, the output power of an inductor-capacitor-capacitor (LCC)-Series tuned WPT system is successfully predicted only using the measured root-mean-square (RMS) of the input current. Random forest algorithm has shown best accuracy to estimate the output power based on transmitter-side parameters only. The proposed approach is experimentally validated using a laboratory prototype. Harmonic components of the input current are used to assess the load impedance and coupling coefficient successfully. Multi-output regression has the highest accuracy for estimating the load impedance and coupling coefficient. The proposed ML algorithm is also used to classify the turn-on and -off regimes to ensure high-efficient operation. / En av de viktigaste utmaningarna med trådlösa kraftöverföring enheter är degraderingen av prestandan när mottagarens position och egenskaper varierar. Variationerna av systemets parametrar, såsom belastningsmotstånd och kopplings styrka i WPT-anordning, påverkar prestanda egenskaperna såsom spänning och effekt. När system parametrarna skiljer sig från de optimala drifts förhållandena, försämras prestandan. Därför måste luftmotståndet och kopplings styrkan övervakas, för att göra nödvändig optimering och kontroll. Sådana styrmetoder kräver emellertid ytterligare avkännings kretsar, och en data kommunikationslänk mellan sändar- och mottagarsidan. Denna studie föreslår ett nytt maskininlärning assisterat WPT-system, som förutsäger kraften som levereras till mottagaren genom att endast använda mätningar på sändarsidan. Dessutom föreslås en metod för att detektera belastningsimpedans och kopplings koefficient med användning av maskin inlärningsmetoder. Vi studerar vilka parametrar som är mätbara på sändarsidan och som kan användas för att förutsäga utgången effekten som levereras till mottagare vid varierande belastningsmotstånd och kopplings nivåer. I den föreslagna metoden förutses framgångs effekten för ett induktor-kondensator-kondensator LCCserie avstämt WPT-system endast framgångsrikt med hjälp av det uppmätta effektivvärdet för ingångs strömmen. Slumpmässig skogsalgoritm har visat exceptionell noggrannhet för att uppskatta uteffekten endast baserat på sändarsidans parametrar. Den föreslagna metoden valideras experimentellt med användning av en laboratorium prototyp. Harmoniska komponenter i ingångs strömmen används för att framgångsrikt bedöma last motståndet och kopplings koefficienten. Multi-utgångsregression har verkat vara mycket exakt för att uppskatta belastningsimpedans och kopplingskoefficient. Den föreslagna maskininlärning algoritmen används också för att klassificera start-och-off-regimer för att säkerställa hög effektiv drift.

Wireless power transfer

Machine learning

Coupling strength estimation

Load impedance estimation

Trådlös kraftöverföring

maskininlärning

uppskattning av kopplingsstyrka

uppskattning av belastningsimpedans

Elektroteknik och elektronik

Silicon nanowire field-effect transistors for the detection of proteins

Mädler, Carsten

05 November 2016

In this dissertation I present results on our efforts to increase the sensitivity and selectivity of silicon nanowire ion-sensitive field-effect transistors for the detection of biomarkers, as well as a novel method for wireless power transfer based on metamaterial rectennas for their potential use as implantable sensors. The sensing scheme is based on changes in the conductance of the semiconducting nanowires upon binding of charged entities to the surface, which induces a field-effect. Monitoring the differential conductance thus provides information of the selective binding of biological molecules of interest to previously covalently linked counterparts on the nanowire surface. In order to improve on the performance of the nanowire sensing, we devised and fabricated a nanowire Wheatstone bridge, which allows canceling out of signal drift due to thermal fluctuations and dynamics of fluid flow. We showed that balancing the bridge significantly improves the signal-to-noise ratio. Further, we demonstrated the sensing of novel melanoma biomarker TROY at clinically relevant concentrations and distinguished it from nonspecific binding by comparing the reaction kinetics. For increased sensitivity, an amplification method was employed using an enzyme which catalyzes a signal-generating reaction by changing the redox potential of a redox pair. In addition, we investigated the electric double layer, which forms around charges in an electrolytic solution. It causes electrostatic screening of the proteins of interest, which puts a fundamental limitation on the biomarker detection in solutions with high salt concentrations, such as blood. We solved the coupled Nernst-Planck and Poisson equations for the electrolyte under influence of an oscillating electric field and discovered oscillations of the counterion concentration at a characteristic frequency. In addition to exploring different methods for improved sensing capabilities, we studied an innovative method to supply power to implantable biosensors wirelessly, eliminating the need for batteries. A metamaterial split ring resonator is integrated with a rectifying circuit for efficient conversion of microwave radiation to direct electrical power. We studied the near-field behavior of this rectenna with respect to distance, polarization, power, and frequency. Using a 100 mW microwave power source, we demonstrated operating a simple silicon nanowire pH sensor with light indicator.

Physics

Biosensor

Ion sensitive field-effect transistor

Nanowire

Point-of-care diagnostics

Split ring resonator

Wireless power transfer

Estudo e projeto de um sistema de transferência de energia elétrica sem fio com compensação capacitiva e baseado no transformador de bobinas em espirais planas fracamente acopladas. / Study and design of a wireless power transfer system with capacitive compensation based on weakly coupled transformer made of flat spiral coils.

Alexandre Hotz Moret

26 October 2018

Recentemente os sistemas de transferência de energia sem fio WPT (do inglês Wireless Power Transfer) têm sido amplamente estudados com o propósito de alimentar eficientemente diversos tipos de cargas através de técnicas específicas, dentre elas destaca-se a transferência capacitiva de potência CPT (do inglês Capacitive Power Transfer) e a transferência indutiva de potência IPT (do inglês Inductive Power Transfer), sendo esta última objeto deste estudo. Em um sistema de transferência indutiva de potência a carga é alimentada através de um transformador fracamente acoplado. Em função do elevado espaçamento entre as bobinas primária e secundária, da ausência de núcleo magnético, ou o emprego do núcleos divididos e separados por um grande entreferro, o transformador apresenta alta reatância de dispersão e baixa reatância de magnetização, o que resulta em elevadas correntes, baixa eficiência e regulação da tensão ruim quando houver variação da carga. Com o intuito de aumentar a eficiência e melhorar a regulação de tensão (ou corrente) são aplicadas compensações capacitivas em ambos os lados do transformador, elevando o número de elementos reativos, o que dificulta a compreensão do seu comportamento. Adicionalmente, as diversas configurações geométricas possíveis para a construção das bobinas dificultam a otimização do projeto de transferência indutiva de potência. Esta dissertação analisa e compara as estratégias de compensação série-série (SS) e série-paralela (SP) sob diversos pontos de vista, identificando pontos de operação relevantes nos quais o sistema atua como uma fonte de corrente ou de tensão em malha aberta, modela os elementos que constituem um sistema de transferência indutiva de potência para alcançar à eficiência requisitada. Adicionalmente este trabalho lista os impactos na fonte e na carga quando do desvio das condições nominais de operação e dá diretrizes que permitem escolher os elementos de um sistema IPT. Na sequência esta dissertação propõe as diretrizes para a construção do transformador com valores predefinidos de fator de qualidade, indutâncias próprias e fator de acoplamento. Por fim, o presente trabalho dimensiona e confecciona alguns sistemas IPT a partir de uma lista de especificações, usando uma metodologia de projeto baseada em fórmulas aproximadas e a valida experimentalmente. / Recently Wireless Power Transfer (WPT) is widely studied in order to efficiently feed many different kinds of loads using specific techniques, such as Capacitive Power Transfer (CPT) and Inductive Power Transfer (IPT). IPT system relies on large air gap and loosely coupled transformer which will be studied in this work. Due to the large separation between the primary and secondary coils, the absence of a magnetic core, or the presence of split cores the transformer presents large leakage inductances, resulting in poor voltage regulation against load variation. Moreover, the low magnetizing inductance results in high magnetizing currents, reducing the overall efficiency. In order to improve the WPT performance, capacitive compensation techniques are applied in both sides of the transformer. Series compensation is commonly used at the primary side of the WPT transformer while Series or Parallel compensation is eligible to the secondary side. In addition, the loosely coupled transformer must be designed, in spite of the complex relationship between the various electrical and geometrical parameters of the coils that complicates the transformer construction and its optimization. This work compares Series-Series and Series-Parallel compensation strategies based on a simple approach, comprehensively highlighting the pro and cons of each one. Also the open loop operation in voltage source and current source modes, and the effect of the gap length for both compensation strategies are discussed. Moreover, the elements that constitute an inductive power transfer system are modeled in order to achieve the required efficiency. This research also proposes some guidance to build the transformer with high figure-of-merit and coupling. Finally, the present work designs and builds few IPT systems that satisfies a set of specifications, based on a simplified design procedure. The proposed design methodology is experimentally validated.

Energia elétrica (Transferência)

Transformadores e reatores

Inductive Power Transfer (IPT).

Series-parallel compensation

Series-series compensation

Wireless Power Transfer (WPT)

Estudo de compensação de desalinhamentos de bobinas em um sistema de transmissão de energia sem fios

Murliky, Lucas

January 2017

A transferência de energia sem fio (WPT) rege um importante papel no carregamento de aparelhos remotos. Em um acoplamento indutivo ressonante há várias topologias de sistemas WPT que podem ser implementados para realizar a transferência de energia. Neste trabalho é utilizado uma topologia que utiliza quatro capacitores de compensação para realizar o ajuste da potência entregue a carga, onde estes capacitores são calculados através das fixações dos demais parâmetros do circuito elétrico. Quando o sistema WPT é projetado, uma distância fixa entre as bobinas é almejada, todavia há incertezas e movimentos que podem provocar a alteração desta distância. Há várias técnicas na literatura que buscam realizar a sintonia do acoplamento indutivo para compensar estes desalinhamentos gerado entre as bobinas. Este trabalho apresenta um método multivariável para maximização da potência entregue a carga em um sistema de transferência sem fio. O método proposto utiliza os conceitos de um capacitor variável e a variação de frequência a fim de variar a potência entregue a carga. Os resultados experimentais obtidos para os fatores de acoplamento magnético k > 0;3 mostraram que controlando a frequência e uma capacitância da rede de compensação o desempenho do sistema é melhor que os casos onde apenas uma dessas variáveis é controlada. / Wireless power transfer (WPT) plays an important rule in charging remote devices. In a resonant inductive coupling there are several topologies of WPT systems that can be implemented to perform the energy transfer. In this work, a topology is used that uses four capacitors of compensation to realize the adjustment of the power delivered to load, where these capacitors are calculated through the xations of the other parameters of the electric circuit. When the WPT system is designed, a xed distance between coils is desired, however there are uncertainties and movements that may cause this distance to change. There are several techniques in the literature that seek to realize the tuning of the inductive coupling to compensate for these misalignments generated between the coils. This work presents a multivariable method to maximize the power delivered to the load in a wireless transfer system. The proposed method uses the concepts of a variable capacitor and the frequency variation in order to vary the power delivered to the load. The experimental results obtained for the magnetic coupling factors k > 0:3 showed that controlling the frequency and capacitance of the compensation network system performance is better than the cases where only one of these variables is controlled.

Acoplamento indutivo

Comunicação sem fio

Engenharia de sistemas

Sistema de transmissão

Wireless power

Tuning method

Misalignment

Dynamic wireless power transfer

Estudo e projeto de um sistema de transferência de energia elétrica sem fio com compensação capacitiva e baseado no transformador de bobinas em espirais planas fracamente acopladas. / Study and design of a wireless power transfer system with capacitive compensation based on weakly coupled transformer made of flat spiral coils.

Moret, Alexandre Hotz

26 October 2018

Recentemente os sistemas de transferência de energia sem fio WPT (do inglês Wireless Power Transfer) têm sido amplamente estudados com o propósito de alimentar eficientemente diversos tipos de cargas através de técnicas específicas, dentre elas destaca-se a transferência capacitiva de potência CPT (do inglês Capacitive Power Transfer) e a transferência indutiva de potência IPT (do inglês Inductive Power Transfer), sendo esta última objeto deste estudo. Em um sistema de transferência indutiva de potência a carga é alimentada através de um transformador fracamente acoplado. Em função do elevado espaçamento entre as bobinas primária e secundária, da ausência de núcleo magnético, ou o emprego do núcleos divididos e separados por um grande entreferro, o transformador apresenta alta reatância de dispersão e baixa reatância de magnetização, o que resulta em elevadas correntes, baixa eficiência e regulação da tensão ruim quando houver variação da carga. Com o intuito de aumentar a eficiência e melhorar a regulação de tensão (ou corrente) são aplicadas compensações capacitivas em ambos os lados do transformador, elevando o número de elementos reativos, o que dificulta a compreensão do seu comportamento. Adicionalmente, as diversas configurações geométricas possíveis para a construção das bobinas dificultam a otimização do projeto de transferência indutiva de potência. Esta dissertação analisa e compara as estratégias de compensação série-série (SS) e série-paralela (SP) sob diversos pontos de vista, identificando pontos de operação relevantes nos quais o sistema atua como uma fonte de corrente ou de tensão em malha aberta, modela os elementos que constituem um sistema de transferência indutiva de potência para alcançar à eficiência requisitada. Adicionalmente este trabalho lista os impactos na fonte e na carga quando do desvio das condições nominais de operação e dá diretrizes que permitem escolher os elementos de um sistema IPT. Na sequência esta dissertação propõe as diretrizes para a construção do transformador com valores predefinidos de fator de qualidade, indutâncias próprias e fator de acoplamento. Por fim, o presente trabalho dimensiona e confecciona alguns sistemas IPT a partir de uma lista de especificações, usando uma metodologia de projeto baseada em fórmulas aproximadas e a valida experimentalmente. / Recently Wireless Power Transfer (WPT) is widely studied in order to efficiently feed many different kinds of loads using specific techniques, such as Capacitive Power Transfer (CPT) and Inductive Power Transfer (IPT). IPT system relies on large air gap and loosely coupled transformer which will be studied in this work. Due to the large separation between the primary and secondary coils, the absence of a magnetic core, or the presence of split cores the transformer presents large leakage inductances, resulting in poor voltage regulation against load variation. Moreover, the low magnetizing inductance results in high magnetizing currents, reducing the overall efficiency. In order to improve the WPT performance, capacitive compensation techniques are applied in both sides of the transformer. Series compensation is commonly used at the primary side of the WPT transformer while Series or Parallel compensation is eligible to the secondary side. In addition, the loosely coupled transformer must be designed, in spite of the complex relationship between the various electrical and geometrical parameters of the coils that complicates the transformer construction and its optimization. This work compares Series-Series and Series-Parallel compensation strategies based on a simple approach, comprehensively highlighting the pro and cons of each one. Also the open loop operation in voltage source and current source modes, and the effect of the gap length for both compensation strategies are discussed. Moreover, the elements that constitute an inductive power transfer system are modeled in order to achieve the required efficiency. This research also proposes some guidance to build the transformer with high figure-of-merit and coupling. Finally, the present work designs and builds few IPT systems that satisfies a set of specifications, based on a simplified design procedure. The proposed design methodology is experimentally validated.

Energia elétrica (Transferência)

Inductive Power Transfer (IPT).

Series-parallel compensation

Series-series compensation

Transformadores e reatores

Wireless Power Transfer (WPT)