3-D-Printed Air-Core Inductors for High-Frequency Power Converters

Liang, Wei; Raymond, Luke; Rivas, Juan

doi:10.1109/tpel.2015.2441005

Cited by 64 publications

(12 citation statements)

References 41 publications

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“…With miniaturization, AM allows for the manufacturing of small parts that would otherwise be difficult to obtain. AM has found application for thin films [60], inductors [61], solar cells [62], and others. The most common 3D printing techniques for electronics are inkjet and direct writing of conductive inks.…”

Section: D Printed Electronicsmentioning

confidence: 99%

Functional 3D Printed Polymeric Materials

Ortiz‐Acosta¹,

Moore²

2019

Functional Materials

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Additive manufacturing (AM) is an emerging 3D printing technology that enables the design and rapid manufacturing of materials with complex microstructures. Advances in 3D printing have allowed manufacturing companies to expand from design and 3D printing of prototypes to the rapid manufacturing of end products. Additive manufacturing enables the manufacturing of components in a layer-by-layer fashion, opposite to common manufacturing methods that rely on machining, molding and subtractive methods to obtain the final product. AM employs a computer-aided design software that allows for the design of virtual objects and the control of the nozzle and/or stage of the 3D printer. Due to their versatility and wide range of mechanical and chemical properties, polymers are the most utilized materials for AM. Polymers used for AM covers thermoplastics, thermosets, elastomers, polymers with incorporated fillers, biopolymers, and polymers blended with biological materials. The architectural design and choice of polymers can lead to materials with enhanced functionalities, mechanical properties, porosity, and stability. This chapter focuses on the development of polymerbased 3D printing materials with multifunctionalities used specifically for the production of biomedical devices, electronic devices, and aerospace-relevant products.

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Section: D Printed Electronicsmentioning

confidence: 99%

Functional 3D Printed Polymeric Materials

Ortiz‐Acosta¹,

Moore²

2019

Functional Materials

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“…Also, air core inductors are not limited by current saturation or by a Curie temperature limit, therefore offering much better linearity over wide operation range compared to their cored counterparts. Moreover, modern fabrication techniques [e.g., PCB [22][23][24][25][26][27][28][29], 3D printing [30], etc.] can be leveraged to reduce weight and cost without sacrificing performance.…”

Section: Switched Mode Dc-rf Power Inverter With Pcb Inductorsmentioning

confidence: 99%

An Integrated RF Power Delivery and Plasma Micro-Thruster System for Nano-Satellites

et al. 2018

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Progress in satellite technologies is ongoing and eventually finds applications back on Earth. Electric propulsion systems have been proven effective on large scale satellites (NASA DAWN) with better propellant efficiency than chemical or cold gas propulsion, and if miniaturized can be promising for long term operation of nano-satellites (e.g., CubeSats) in low Earth orbit or in deep space (NASA MarCO). However, the power supplies often used to power these electric thrusters, particularly those involving radiofrequency (RF) plasma, typically comprise power inefficient linear mode RF power amplifiers (e.g., class AB). These are simple systems designed to operate reliably under a wide range of loads for versatility, but they suffer low power efficiencies when operating at conditions significantly different from the nominal operating point. The required bulky and heavy thermal management components deem these electric propulsion systems impossible to fit on board nano-satellites. Here we present a compact and efficient switched mode dc-RF power inverter integrated with an electro-thermal plasma micro-thruster for nano-satellite (e.g., Cubesats) propulsion. The integrated system can serve as side panels and structural support of CubeSats, saving precious on-board volume for propellant and/or payloads. A complete assembly has been operationally tested in a space simulation system. This development opens a route for a new generation of power supplies applicable to the space sector, the microelectronics industry as well as the field of bioengineering.

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“…4 An air-core configuration is an alternative solution for megahertz-class power converters. [9][10][11][12] Air-core magnetic components are free from magnetic material iron losses. However, their magnetic flux density in the high-frequency region must be considered due to the following reasons.…”

Section: Introductionmentioning

confidence: 99%

Measurement of internal magnetic flux density distribution in air-core toroidal transformer under high-frequency excitation

Hashimoto

Okuda

Hikihara

2020

Review of Scientific Instruments

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An investigation of air-core toroidal transformers has been undertaken to enable power converters to achieve megahertz operation. The characteristics of the air-core toroidal transformer govern the behaviors of the internal magnetic flux of the transformer. Understanding the behaviors at an above-megahertz level is a key issue in the design of the air-core toroidal transformer. This paper discusses the internal magnetic flux density distribution in the air-core toroidal transformer under high-frequency excitation. We propose a measurement method for the distribution and show the obtained results under a sinusoidal excitation with an amplitude of 1.5 A and a frequency of 1 MHz. The results reveal a non-uniform distribution in the tangential and normal directions. The cause of this non-uniformity was found to be the structure of the air-core toroidal transformer. In addition, the validity of the proposed measurement method was confirmed by comparing the experimentally obtained results with a numerical estimation using the Biot-Savart law. These results suggest that the proposed measurement method is capable of investigating the distributed characteristics of air-core toroidal transformers under megahertz excitation.

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3-D-Printed Air-Core Inductors for High-Frequency Power Converters

Cited by 64 publications

References 41 publications

Functional 3D Printed Polymeric Materials

Functional 3D Printed Polymeric Materials

An Integrated RF Power Delivery and Plasma Micro-Thruster System for Nano-Satellites

Measurement of internal magnetic flux density distribution in air-core toroidal transformer under high-frequency excitation

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