Resonant Configuration Topology Exploration for Inductive Link Power Transfer

Hafiz, S.; Zaharudin, Zarimin; Khan, Sheroz; Midi, Nur Shahida; Hwang, John T.; Kadir, Kushsairy; Shah, Jawad Ali

doi:10.11591/ijeecs.v11.i2.pp522-530

Cited by 2 publications

(2 citation statements)

References 18 publications

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“…In general, the structure of the inductive coupling link for bio-implanted devices consist of two coils: an external coil (primary coil), which is placed outside the human body and the internal coil (secondary coil), which is inside the human body at a short distance from the external coil [5] as shown in Figure 1.…”

Section: Introductionmentioning

confidence: 99%

Design and Optimization of Inductively Coupled Spiral Square Coils for Bio-Implantable Micro-System Device

Lakhdari¹,

Mekkakia-Maaza²,

Dekmous³

2019

IJECE

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Due to the development of biomedical microsystems technologies, the use of wireless power transfer systems in biomedical application has become very largely used for powering the implanted devices. The wireless power transfer by inductive resonance coupling link, is a technic for powering implantable medical devices<strong> </strong>(IMDs) between the external and implanted circuits. In this paper we describe the design of an inductive resonance coupling link using for powering small bio-implanted devices such as implantable bio-microsystem, peacemaker and cochlear implants. We present the reduced design and an optimization of small size obtained spiral coils of a 9.5 mm<sup>2</sup> implantable device with an operating frequency of 13.56 MHz according to the industrial scientific-medical (ISM). The model of the inductive coupling link based on spiral square coils design is developed using the theoretical analysis and optimization geometry of an inductive link. For a mutual distance between the two coils at 10mm, the power transfer efficiency is about 79% with , coupling coefficient of 0.075 and a mutual inductance value of 2µH. In comparison with previous works, the results obtained in this work showed better performance such as the weak inter coils distance, the hight efficiency power transfer and geometry.

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Section: Introductionmentioning

confidence: 99%

Design and Optimization of Inductively Coupled Spiral Square Coils for Bio-Implantable Micro-System Device

Lakhdari¹,

Mekkakia-Maaza²,

Dekmous³

2019

IJECE

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“…However, when a portable accelerator is required with the waveguide length of 0.3-0.5 , electron energy of 4-8 and low beam current, then standing wave accelerators have certain advantage [1]. Operation modes of electron linear accelerator (linac) are compared in [2] and reasonability of development of standing wave accelerators for small and moderate energies is described.…”

Section: Introductionmentioning

confidence: 99%

Radial dynamics of electrons in two-section linear accelerator

Filatov

Shilov

2019

IJECE

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This article discusses possibility of harness wiring with the use of focusing system of high frequency eigenfields of accelerating resonators in standing wave linear accelerators on the basis of biperiodic slowing systems. The scopes of business activities and specificity of existing engineering processes applied in industry, especially in chemistry and metallurgy, require for special measures on environmental protection. At present electron linear accelerators operating in pulse mode are used for application purposes. Such accelerators can be characterized by sufficient beam power for efficient industrial use and for environmental protection. The results of numerical analysis of electron dynamics in two-section accelerator upon various initial conditions are presented. The obtained results are applied for development of actual accelerator, calculated and experimental data are given. The performed experimental study confirmed possibility of development of standing wave linear accelerator without external magnetic focusing system with output beam diameter of not higher than . The results of calculations of beam dynamics are experimentally verified.

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Resonant Configuration Topology Exploration for Inductive Link Power Transfer

Cited by 2 publications

References 18 publications

Design and Optimization of Inductively Coupled Spiral Square Coils for Bio-Implantable Micro-System Device

Design and Optimization of Inductively Coupled Spiral Square Coils for Bio-Implantable Micro-System Device

Radial dynamics of electrons in two-section linear accelerator

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