Receiving Coil Analysis of Wireless Power Transmission with Inductive Coupling

In this work, an advanced drone battery charging system is developed. The system is composed of a drone charging station with multiple power transmitters and a receiver to charge the battery of a drone. A resonance inductive coupling-based wireless power transmission technique is used. With limits of wireless power transmission in inductive coupling, it is necessary that the coupling between a transmitter and receiver be strong for efficient power transmission; however, for a drone, it is normally hard to land it properly on a charging station or a charging device to get maximum coupling for efficient wireless power transmission. Normally, some physical sensors such as ultrasonic sensors and infrared sensors are used to align the transmitter and receiver for proper coupling and wireless power transmission; however, in this system, a novel method based on the hill climbing algorithm is proposed to control the coupling between the transmitter and a receiver without using any physical sensor. The feasibility of the proposed algorithm was checked using MATLAB. A practical test bench was developed for the system and several experiments were conducted under different scenarios. The system is fully automatic and gives 98.8% accuracy (achieved under different test scenarios) for mitigating the poor landing effect. Also, the efficiency η of 85% is achieved for wireless power transmission. The test results show that the proposed drone battery charging system is efficient enough to mitigate the coupling effect caused by the poor landing of the drone, with the possibility to land freely on the charging station without the worry of power transmission loss.

Download Full-text

Static and Dynamic Charging System for a Four-Wheeler Electric Vehicle by Inductive Coupling Wireless Power Transmission System

10.1109/gecost52368.2021.9538752 ◽

2021 ◽

Author(s):

Md. Hasin Mahtab Moon ◽

Dewan Mahnaaz Mahmud ◽

Istiaque Ahamed ◽

Shad Bin Kabir ◽

Mohammad Abdul Mannan

Keyword(s):

Electric Vehicle ◽

Power Transmission ◽

Transmission System ◽

Inductive Coupling ◽

Wireless Power ◽

Wireless Power Transmission ◽

Charging System ◽

Power Transmission System ◽

Dynamic Charging

Download Full-text

Wireless Power Transfer Approaches for Medical Implants: A Review

Signals ◽

10.3390/signals1020012 ◽

2020 ◽

Vol 1 (2) ◽

pp. 209-229

Author(s):

Mohammad Haerinia ◽

Reem Shadid

Keyword(s):

Power Transmission ◽

Ultrasonic Method ◽

Inductive Coupling ◽

Operating Frequency ◽

Power Transfer ◽

Wireless Power ◽

Wireless Power Transmission ◽

Implantable Medical Devices ◽

Design Elements ◽

Power Transfer Efficiency

Wireless power transmission (WPT) is a critical technology that provides an alternative for wireless power and communication with implantable medical devices (IMDs). This article provides a study concentrating on popular WPT techniques for IMDs including inductive coupling, microwave, ultrasound, and hybrid wireless power transmission (HWPT) systems. Moreover, an overview of the major works is analyzed with a comparison of the symmetric and asymmetric design elements, operating frequency, distance, efficiency, and harvested power. In general, with respect to the operating frequency, it is concluded that the ultrasound-based and inductive-based WPTs have a low operating frequency of less than 50 MHz, whereas the microwave-based WPT works at a higher frequency. Moreover, it can be seen that most of the implanted receiver’s dimension is less than 30 mm for all the WPT-based methods. Furthermore, the HWPT system has a larger receiver size compared to the other methods used. In terms of efficiency, the maximum power transfer efficiency is conducted via inductive-based WPT at 95%, compared to the achievable frequencies of 78%, 50%, and 17% for microwave-based, ultrasound-based, and hybrid WPT, respectively. In general, the inductive coupling tactic is mostly employed for transmission of energy to neuro-stimulators, and the ultrasonic method is used for deep-seated implants.

Download Full-text

Optimization Design for Receiving Coil with Novel Structure Based on Mutual Coupling Model in Wireless Power Transmission for Capsule Endoscope

Energies ◽

10.3390/en13236460 ◽

2020 ◽

Vol 13 (23) ◽

pp. 6460

Author(s):

Shuai Kuang ◽

Guozheng Yan ◽

Zhiwu Wang

Keyword(s):

Optimization Design ◽

Power Transmission ◽

Biological Tissues ◽

Mutual Inductance ◽

Power Measurement ◽

Capsule Endoscope ◽

Wireless Power ◽

Wireless Power Transmission ◽

Sufficient Power ◽

Receiving Coil

Wireless capsule endoscope (WCE) is a promising technology for noninvasive and painless imaging detection on gastrointestinal (GI) diseases. On the other hand, conventional endoscopes with wires could discomfort patients and cause them to vomit and aerosolize coronavirus if the patients are infected with COVID-19. However, there stands a technical bottleneck on power supply for the WCE. With the help of wireless power transmission technology, a hollow receiving coil (RC) is proposed to supply sufficient power and also minimize the size of WCE. A model on mutual inductance between transmitting and receiving coils is proposed to evaluate receiving power when the RC is in a different position and direction of patient’s GI tract. Based on the model, an optimal RC is built to obtain sufficient and stable power. Measurement of mutual inductance with the optimal RC validates high accuracy of the proposed model. The standard deviation of receiving power is very low. WCE with optimum RC gets sufficient power and captures images stably in live pig’s intestine tract. Additionally, the model is little affected by biological tissues. It ensures reliable performance of WCE and makes popular clinical application of WCE possible, which is also a relief to reduce epidemics like COVID-19.

Download Full-text