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1. Exploring the Leakage Inductance of Transformers Used in Dual Active Bridge

   https://doi.org/10.1109/NAPS46351.2019.9000267  

   Soria, Denisse A. ; Ranade, Satish ; Lavrova, Olga ( October 2019 , 2019 North American Power Symposium (NAPS))

   Battery Energy Storage Systems (BESS) are critical to achieving reliability and efficiency in the modern electric grid. Dual Active Bridges (DAB) are often proposed for such integration since they can allow multiple sources and electrical isolation via a high-frequency transformer. In defined applications, DABs rely on the magnetizing and leakage inductance of their high-frequency transformers to achieve their performance requirement. In this paper, the inductance parameters of two types of two-winding transformers are investigated using the Finite Element Analysis (FEA) software ANSYS Maxwell. The variation of the inductance values due to the windings' distribution and core geometry was studied by establishing a parametric analysis. Prototypes were built and tested to compare the inductances actual measurements versus the simulation results. Exploring the possibility of characterizing the inductances of a transformer from a simulation standpoint is of interest in order to construct customized transformers with the optimal characteristic required in a specific DAB design. 

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2. A High Power High Frequency Transformer Design for Solid State Transformer Applications

   https://doi.org/10.1109/ICRERA47325.2019.8996515  

   Shafei, Ahmad El ; Ozdemir, Saban ; Altin, Necmi ; Jean-Pierre, Garry ; Nasiri, Adel ( November 2019 , 2019 8th International Conference on Renewable Energy Research and Applications (ICRERA))

   null (Ed.)

   In this study, design of a 330kW single-phase transformer (corresponding to 1MW three-phase) operating at 50kHz is presented. Possible core materials and their performances are investigated under high switching frequency operation. Core volume, area, configuration, and market availability are studied to achieve the optimal compact and cost-effective transformer model. Next, transformer winding type, size, placement, and cost are analyzed. These steps will result in a complete transformer electromagnetic design and modelling. Afterwards, a 3D transformer model is created and simulated using a Finite Element Analysis (FEA) tool. ANSYS Maxwell-3D is used to simulate the magnetics, electrostatics, and transients of the designed transformer. This model is integrated with a power electronics circuit in ANSYS Simplorer to make a co-simulation for the entire system. Results obtained will include core maximum flux density, core/copper losses, leakage/magnetizing inductances, windings parasitic capacitances, and input/output voltage, current, and power values. Finally, the systems' overall efficiency is calculated and presented. 

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3. A Family of Novel Switch Capacitor Based Integrated Matrix Autotransformer LLC Converter for Data Center Application

   https://doi.org/10.1109/GreenTech56823.2023.10173801  

   Qiu, Maohang ; Wei, Mengxuan ; Liu, Xiaoyan ; Meng, Haoran ; Cao, Dong ( April 2023 , IEEE)

   Switched Tank Converter(STC) is one kind of Resonant Switch Capacitor(ReSC) that can be considered as a good candidate for data center application with high power efficiency and high power density. On the other hand, LLC converter can also realize very good performance for low voltage application. Although STC can realize relatively higher efficiency than LLC converter in the light load since the core loss is saved, LLC can keep relatively higher efficiency in the heavy load than STC does since the conduction loss of LLC is smaller. The main reason is because transformer’s winding resistance is smaller than semiconductor devices’ resistance, and this is very important for high current application.In order to utilize the benefits of the STC and the LLC converter together, this paper proposes a family of the novel Switch Capacitor based Integrated Matrix Autotransformer LLC Converters (SCIMAC). The proposed converters share the same high voltage side circuit of the STC with low voltage stress devices. Different from the traditional LLC converter with an isolated transformer, the proposed SCIMAC utilizes one autotransformer with only the secondary side windings similar to LLC's secondary side. There are several advantages that can be realized of the SCIMAC: 1). Low figure of merit (FOM) devices can be adopted to realize higher efficiency due to the low voltage stress of the SCIMAC. 2). Higher power efficiency can be realized when compared with STC converter in heavy load because the resistance of the autotransformer’s windings is lower than semiconductor devices’ resistance. 3). The primary side winding loss of the transformer is saved to further increase the efficiency. 4) ZVS turning on can be realized by the magnetizing current of the core. 

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4. A Decoupled Control Scheme of Four-Port Solid State Transformer

   https://doi.org/10.1109/ECCE.2019.8912595  

   Ozdemir, Saban ; Altin, Necmi ; Shafei, Ahmad El ; Rashidi, Mo ; Nasiri, Adel ( September 2019 , IEEE Energy Conversion Conference and Expo)

   In this study, a four-port solid-state transformer (SST) with decoupled control scheme to control the power flow and the output voltage is proposed. The proposed decoupled control scheme controls all of the four ports' powers independently. In addition, the design of the four-port transformer including core material selection and winding placement is investigated. The designed transformer is modeled in ANSYS-Maxwell and also co-simulated with ANSYS-Simplorer. The operating frequency of the system is designed for 100 kHz; therefore, a very compact size is obtained for the entire multi-port converter. The performance of the proposed system is validated throughout MATLAB/Simulink simulation and experimental studies carried out for a 10kW/port SST prototype. The obtained results show that the four-port SST provides an interface for four-different power supplies or loads. It is seen that the proposed decoupled control scheme can control the output voltage at the desired value and track the reference power signals for each port. It provides as well a good steady state and dynamic performance. 

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5. Design and Implementation of a Medium Voltage, High Power, High Frequency Four-Port Transformer

   https://doi.org/10.1109/APEC39645.2020.9124337  

   El Shafei, Ahmad ; Ozdemir, Saban ; Altin, Necmi ; Jean-Pierre, Garry ; Nasiri, Adel ( March 2020 , 2020 IEEE Applied Power Electronics Conference and Exposition (APEC))

   null (Ed.)

   With the growth in penetration number and power level of renewable energy resources, the need for a compact and high efficient solid state transformer becomes more important. The aim of this paper is to design a compact solid state transformer for microgrid application. The proposed transformer has four ports integrated on a single common core. Thus, it can integrate different renewable energy resources and energy storage systems. The transformer is operating at 50kHz switching frequency, and each port can handle 25kW rated power. In this paper, the ports are chosen to represent a realistic industrial microgrid model consisting of grid, energy storage system, photovoltaic system, and load. The grid port is designed to operate at 4160V AC, while the other three ports operate at 400V. Moreover, the grid, energy storage, and photovoltaic ports are active ports with dual active bridge topologies, while the load port is a passive port with full bridge rectifier one. In this paper, an extensive and complete design and modeling of the entire solid state transformer is presented. The proposed design is first validated with simulation results, and then the proposed transformer is implemented. Some preliminary experimental tests are also performed and the obtained results are reported. 

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