Capacitive power transfer for maritime electrical charging applications

Wireless power transfer can provide the convenience of automatic charging while the ships or maritime vehicles are docking, mooring, or in a sailing maneuver. It can address the challenges facing conventional wired charging technologies, including long charging and queuing time, wear and tear of the physical contacts, handling cables and wires, and electric shock hazards. Capacitive power transfer (CPT) is one of the wireless charging technologies that has received attention in on-road electric vehicle charging applications. By the main of electric fields, CPT offers an inexpensive and light charging solution with good misalignment performance. Thus, this study investigates the CPT system in which air and water are the separation medium for the electrical wireless charging of small ships and unmanned maritime vehicles. Unlike on-road charging applications, air or water can be utilized as charging mediums to charge small ships and unmanned maritime vehicles. Because of the low permittivity of the air, the air-gapped capacitive coupling in the Pico Farad range requires a mega-hertz operating frequency to transfer power over a few hundred millimeters. This study examines an air-gapped CPT system to transfer about 135 W at a separation distance of 50 mm, a total efficiency of approximately 83.9%, and a 1 MHz operating efficiency. At 13.56 MHz, the study tested a shielded air-gapped CPT system that transfers about 100 W at a separation distance of 30 mm and a total efficiency of about 87%. The study also examines the underwater CPT system by submerging the couplers in water to increase the capacitive coupling. The system can transfer about 129 W at a separation distance of 300 mm, a total efficiency of aboutapproximately%, and a 1.1 MHz operating efficiency. These CPT systems can upscale to provide a few kW for small ships and unmanned maritime vehicles. But they are still facing several challenges that need further investigations

Design and optimization for wireless-powered networks

Wireless Power Transfer (WPT) opens an emerging area of Wireless-Powered Networks (WPNs). In narrowband WPNs, beamforming is recognized as a key technique for enhancing information and energy transfer. However, in multi-antenna multi-sine WPT systems, not only the beamforming gain but also the rectifier nonlinearity can be exploited by a waveform design to boost the end-to-end power transfer efficiency. This thesis proposes and optimizes novel transmission strategies for two types of WPNs: narrowband autonomous relay networks and multi-antenna multi-sine WPT systems. The thesis starts by proposing a novel Energy Flow-Assisted (EFA) relaying strategy for a one-way multi-antenna Amplify-and-Forward (AF) autonomous relay network. In contrast to state-of-the-art autonomous relaying strategies, the EFA enables the relay to simultaneously harvest power from source information signals and a dedicated Energy Flow (EF) from the destination for forwarding. As a baseline, a Non-EFA (NEFA) strategy, where the relay splits power from the source signals, is also investigated. We optimize relay strategies for EFA and NEFA, so as to maximize the end-to-end rate and gain insights into the benefit of the EF. To transmit multiple data streams, we extend the EFA and the NEFA to a Multiple-Input Multiple-Output (MIMO) relay network. A novel iterative algorithm is developed to jointly optimize source precoders and relay matrices for the EFA and the NEFA, in order to maximize the end-to-end rate. Based on a channel diagonalization method, we also propose less complex EFA and NEFA algorithms. In the study of waveform designs for multi-antenna multi-sine WPT, large-scale designs with many sinewaves and transmit antennas, computationally tractable algorithms and optimal multiuser waveforms remain open challenges. To tackle these issues, we propose efficient waveform optimization algorithms to maximize the multiuser weighted-sum/minimum rectenna DC output voltage, assuming perfect Channel State Information at the Transmitter (CSIT). An optimization framework is developed to derive these waveform algorithms. Relaxing the assumption on CSIT, we propose waveform strategies for multi-antenna multi-sine WPT based on waveform selection (WS) and waveform refinement (WR), respectively. Applying the strategies, an energy transmitter can generate preferred waveforms for WPT from predesigned codebooks of waveform precoders, according to limited feedback from an energy receiver, which carries information on the harvested energy. Although the WR-based strategy is suboptimal for maximizing the average rectenna output voltage, it causes a lower overhead than the WS-based strategy. We propose novel algorithms to optimize the codebooks for the two strategies.Open Acces

A Novel Electric Insulation String Structure With High-Voltage Insulation and Wireless Power Transfer Capabilities

High-voltage insulation (HVI) strings are commonly used to hold high-voltage electric cables and electrically isolate them from the grounded transmission tower. In this paper, a novel concept of an electric insulation string with HVI and wireless power transfer (WPT) capabilities is presented. Based on the concept of the domino-resonator WPT system, this new structure consists of coil resonators embedded inside totally sealed insulation discs, which are then connected in series to form the new insulation string structure with the simultaneous HVI and WPT functions. This structure allows energy harvested from the ac magnetic field around the high-voltage cable to be transmitted wirelessly to power an online monitoring system in high-voltage transmission tower continuously, thereby reducing the storage requirements of the battery. The design and analysis of this new WPT structure based on the dimensions of commercially available HVI rod are included. Practical measurements obtained from a hardware prototype of about 25 W have been obtained to confirm the WPT capability of the proposal. An energy efficiency of more than 60% has been achieved for a transmission distance of 1.1 m over a wide range of load

Digital control of contactless battery charging system

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 1995.Includes bibliographical references (leaves 230-234).by Aaron M. Schultz.Ph.D

A micro-transponder for precision tracking of underwater targets

A prototype micro-transponder has been designed and built to track, in real-time, the positions of objects or animals within the water column. Commercially available data storage tags, which help monitor the behavior of underwater animals, do not provide real-time interrogation and data dissemination capabilities in a form factor and acoustic frequency band acceptable for active tracking applications. This prototype is 18.5 cm3 and weighs 43.7 g in air. It operates at an acoustic frequency of 160 kHz and uses a mixed-signal topology with low-power components and a microcontroller, which allows for firmware updates and addition of external sensors. It is powered by a lithium battery that provides enough energy for an 8-day deployment at a 1-second interrogation interval. Tests carried out in a tank confirmed the functionality of the design with coded replies being transmitted at source levels of 167 dB re 1 microPa at 1 m

A Universal Infrared Remote Control

This project consists of building a universal remote controller, which can be used to control any kind of device capable of communicating its user interface. The remote device works based on an infrared technology and allows the user to control any of the home appliances. The idea and design of this project are considered as a multicommunication between transmitter and receiver, because the remote control device combines many remotes into one and has an ability to control up to fifteen appliances that are commonly used at homes. Thetransmitter contains 15 independent inputs and has a carrier wave frequency of 38 kHz, which is the same for almost all infrared remote controls. Similarly, the receiver has 15 independent outputs, each of which can operate separately. The SAA3004 transmitter integrated circuit (IC), which is designed for infrared remote control systems, is used as a main IC on the remote control itself. As for receiver part, PIC16C55-XT/P is used as a microcontroller to control the infrared receiver operations due to the increased number of Input/Output pins. Both ICs are programmed accordingly to provide a multi- communication. A desktop lamp and fan are used as the example appliances to be remotely controlled. The control of these appliances is associated with ON/OFF switching application. Since a remote control has become a part of the everyday life, in this project, an infrared remote control system is designed to prove the universality of it

Application of the polar loop technique to UHF SSB transmitters

SIGLEAvailable from British Library Document Supply Centre- DSC:D68470/86 / BLDSC - British Library Document Supply CentreGBUnited Kingdo