Voltage and Power Balance Strategy without Communication for a Modular Solid State Transformer Based on Adaptive Droop Control

Rodrigues, Welbert Alves; Oliveira, Thiago Ribeiro de; Morais, Lenin Martins Ferreira; Rosa, Arthur H. R.

doi:10.3390/en11071802

Cited by 9 publications

(8 citation statements)

References 32 publications

(49 reference statements)

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“…Droop control is also a well-known practice used in power systems to share power among different generators. This concept has been recently proposed for other kinds of applications, such as speed control for integrated modular motor drives or modular DC/DC converter for smart transformers [10,11]. In this case, the droop control, illustrated in Figure 15, could be a suitable solution to enable parallel connection and to allow power sharing among the DABs; moreover, it does not require any communications between the BDC modules.…”

Section: Converter Paralleling For Power Scalabilitymentioning

confidence: 99%

Power Scalable Bi-Directional DC-DC Conversion Solutions for Future Aircraft Applications

Lamantia¹,

Giuliani²,

Castellazzi

2020

Energies

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With the introduction of the more electric aircraft, there is growing emphasis on improving overall efficiency and thus gravimetric and volumetric power density, as well as smart functionalities and safety of an aircraft. In future on-board power distribution networks, so-called high voltage DC (HVDC, typically +/−270VDC) supplies will be introduced to facilitate distribution and reduce the associated mass and volume, including harness. Future aircraft power distribution systems will also very likely include energy storage devices (probably, batteries) for emergency back up and engine starting. Correspondingly, novel DC-DC conversion solutions are required, which can interface the traditional low voltage (28 V) DC bus with the new 270 V one. Such solutions presently need to cater for a significant degree of flexibility in their power ratings, power transfer capability and number of inputs/outputs. Specifically, multi-port power-scalable bi-directional converters are required. This paper presents the design and testing of such a solution, addressing the use of leading edge wide-band-gap (WBG) solid state technology, especially silicon carbide (SiC), for use as high-frequency switches within the bi-directional converter on the high-voltage side.

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Section: Converter Paralleling For Power Scalabilitymentioning

confidence: 99%

Power Scalable Bi-Directional DC-DC Conversion Solutions for Future Aircraft Applications

Lamantia¹,

Giuliani²,

Castellazzi

2020

Energies

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“…Equation (A32) can be used for all converters and SFL, PBC and IDA-PBC control laws. For SFL control and boost converter: The proposed methodology is used to evaluate another study cases: a PFC (Power Factor Correction) Boost converter [45] and the SST (Solid-State Transformer) [46]. In the last case, 32 control loops are embedded in the same DSP, which also justifies the use of the approach in more complex applications.…”

Section: Appendix a Nonlinear Controllersmentioning

confidence: 99%

SHIL and DHIL Simulations of Nonlinear Control Methods Applied for Power Converters Using Embedded Systems

et al. 2018

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In this work, a new real-time Simulation method is designed for nonlinear control techniques applied to power converters. We propose two different implementations: in the first one (Single Hardware in The Loop: SHIL), both model and control laws are inserted in the same Digital Signal Processor (DSP), and in the second approach (Double Hardware in The Loop: DHIL), the equations are loaded in different embedded systems. With this methodology, linear and nonlinear control techniques can be designed and compared in a quick and cheap real-time realization of the proposed systems, ideal for both students and engineers who are interested in learning and validating converters performance. The methodology can be applied to buck, boost, buck-boost, flyback, SEPIC and 3-phase AC-DC boost converters showing that the new and high performance embedded systems can evaluate distinct nonlinear controllers. The approach is done using matlab-simulink over commodity Texas Instruments Digital Signal Processors (TI-DSPs). The main purpose is to demonstrate the feasibility of proposed real-time implementations without using expensive HIL systems such as Opal-RT and Typhoon-HL.

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“…A traditional DC microgrid uses economical and reliable line frequency transformer to achieve electrical isolation and voltage matching [9]. However, its large size and weight, low power density, and the lack of continuous regulation and integrated control of the voltage and current lead to the bottlenecks of large-scale grid connection of the DC microgrid.…”

Section: Introductionmentioning

confidence: 99%

A Virtual Inertia-Based Power Feedforward Control Strategy for an Energy Router in a Direct Current Microgrid Application

Sun

Wang

et al. 2019

Energies

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Due to the uncertainty of the power load and the randomness of distributed generations, low-voltage direct current (LVDC) bus voltage fluctuation will greatly affect the safety of an energy router-enabled direct current (DC) microgrid. In this paper, a power feedforward control strategy based on a dual active bridge (DAB) DC/DC converter in an energy router-based DC Microgrid is proposed. Based on this strategy, the LVDC bus voltage is controlled by virtual inertia control of the DC microgrid, instead of by the DAB converter. Thus, two benefits of the proposed strategy can be achieved: the power feedforward control can be realized, to mitigate the voltage fluctuation range of the LVDC bus; and the modulation algorithm in the DAB converter can be simplified. Experimental results verify the correctness and effectiveness of the proposed control method.

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Voltage and Power Balance Strategy without Communication for a Modular Solid State Transformer Based on Adaptive Droop Control

Cited by 9 publications

References 32 publications

Power Scalable Bi-Directional DC-DC Conversion Solutions for Future Aircraft Applications

Power Scalable Bi-Directional DC-DC Conversion Solutions for Future Aircraft Applications

SHIL and DHIL Simulations of Nonlinear Control Methods Applied for Power Converters Using Embedded Systems

A Virtual Inertia-Based Power Feedforward Control Strategy for an Energy Router in a Direct Current Microgrid Application

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