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1. Low-Power Solid-State Transformers to Replace Line-Frequency Class 2 Transformers

   https://doi.org/10.1109/APEC48139.2024.10509077  

   Nguyen, Allen T; Sullivan, Charles R (February 2024, IEEE)

   Class 2 transformers are small line-frequency transformers widely used for control systems requiring 24 VAC signaling, including residential and commercial HVAC systems, industrial controls, and much more. These transformers have large standby losses, low efficiencies, large weights, and high costs. In this work, we propose a power electronic alternative in the form of a low-power solid-state transformer. We design and test two 40 VA 120 VAC to 24 VAC solid state transformers, including a two-stage and a single-stage topology. Both converters provide higher efficiencies across all load ranges compared to the Class 2 line-frequency transformers, especially at light load (5 VA) with improvements of 19.6% and 29.9%, respectively. Standby losses for the two are 417 mW and 196 mW, compared to an average of 2.8 W standby loss for 40 VA Class 2 line-frequency transformers. 

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2. Position-Insensitive Wireless Power Transfer Based on Nonlinear Resonant Circuits

   O. B. Abdelatty, X. Wang (March 2019, IEEE transactions on microwave theory and techniques)

   Near-field resonant-based wireless power transfer (WPT) technology has a significant impact in many applications ranging from charging of biomedical implants to electric vehicles (EVs). The design of robust WPT systems is challenging due to its position-dependent power transfer efficiency (PTE). In this paper, a new approach is presented to address WPT's strong sensitivity to the coupling factor variation between the transmit and receive coils. The introduced technique relies on harnessing the unique properties of a specific class of nonlinear resonant circuits to design position-insensitive WPT systems that maintain a high PTE over large transmission distances and misalignments without tuning the source's operating frequency or employing tunable matching networks, as well as any active feedback/control circuitry. A nonlinear-resonant-based WPT circuit capable of transmitting 60 W at 2.25 MHz is designed and fabricated. The circuit maintains a high PTE of 86% over a transmission distance variation of 20 cm. Furthermore, transmit power and PTE are maintained over a large lateral misalignment up to ±50% of the coil diameter and angular misalignment up to ±75°. The new design approach enhances the performance of WPT systems by significantly extending the range of coupling factors over which both load power and high PTE are maintained. 

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3. An 80-W 94.6%-Efficient Multi-Phase Multi-Inductor Hybrid Converter

   Das, Ratul; Seo, Gab-Su; Maksimovic, Dragan; and Le, Hanh-Phuc (March 2019, 2019 IEEE Applied Power Electronics Conference and Exposition (APEC))

   This paper presents a new Multi-Phase Multi-Inductor Hybrid (MP-MIH) converter that features high efficiency at large conversion ratios, while operating the switches with duty cycles larger than state-of-the-art hybrid topologies. In this converter, the capacitors are soft-charged and soft- discharged through three inductors operated in three interleaving phases. An experimental six-level three-phase converter prototype achieves 94.6% peak efficiency and 425 W/in3 power density for conversions from 48V to 1V-2V at loads of up to 40A. This multi-phase multi-inductor hybrid converter architecture can be extended to any number of switched-capacitor network levels to support wide range of input and output voltages and load currents in data centers, telecommunication and other high- performance digital systems. 

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4. Development of a Power and Voltage Control Scheme for Multi-Port Solid State Transformers

   https://doi.org/10.1109/ICRERA.2018.8567001  

   Khayamy, Mehdy; Nasiri, Adel; Altin, Necmi (October 2018, 2018 7th International Conference on Renewable Energy Research and Applications (ICRERA))

   Solid State Transformers (SSTs) are being considered as a replacement to the classic transformers especially for renewable energy and energy storage systems mainly due to their much smaller size and controllability and regulation over the transferred power. Multi-Port SSTs share one high frequency core for the isolation between several devices and hence are even more compact and efficient but the system is complex and the control of such a system is a challenge. This paper considers a four-port, MPSST connected to a renewable source, battery, load, and the grid and discusses various scenarios and operating points. It is shown that several factors including the ratio of the renewable power to the load, battery SOC status and role of the battery in the system change the desired power flow in the system and there are several control structure needed for each mode of operation. These modes of operation and the boundary between them are recognized and eventually a MIMO control scheme is suggested that includes several switches to changes the structure of the controller to adjust the controller structure to the operating condition. Eventually, input-output linearization technique has been adopted to the system to linearize the model and achieve a better control performance. 

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5. Optimization of an Unregulated Low-Q Resonant Isolated DC-DC Stage for Low-Power AC-AC Converters

   https://doi.org/10.1109/COMPEL57542.2024.10614056  

   Nguyen, Allen T; Sullivan, Charles R (June 2024, IEEE)

   Low-power line-frequency transformers are common across several applications, but these transformers are found to have large standby losses, low efficiencies, large weights, and high costs. In this paper we optimize a power conversion stage for this and other applications where an unregulated, isolated converter is needed. The selected topology uses low-impedance passives to reduce their size; to address this case we analyze operation of a lower-Q resonant tank. Lastly, because of the application of low-power line-frequency transformers, we optimize around a typical usage cycle to minimize the yearly average power loss. For the application of a Class 2 line-frequency transformer, model results are accurate to simulation by within 12.1%, and optimization produced a design that was experimentally validated to achieve a yearly average power loss of 285.1 mW, a peak efficiency of 99.26% and a standby loss of 155 mW. 

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