2019
DOI: 10.1016/j.segan.2019.100224
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Evaluating the technical benefits of AC–DC hybrid distribution systems consisting of solid-state transformers using a multiobjective index

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Cited by 10 publications
(16 citation statements)
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“…In this context, special attention is paid to the Dual Active Bridge (DAB) (i.e., a bidirectional DC/DC converter with identical full bridges on its primary and secondary side and a high frequency transformer being the set of power electronics responsible for converting MVDC to LVDC in a three-stage SST), the minimization of the core's volume, losses and cost, and the optimal incorporation of the three-stage SST in modern applications [30,31]. Such applications include a wide range of scales, from smart buildings up to entire distribution systems [32][33][34].…”
Section: Interface With the Ac Gridmentioning
confidence: 99%
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“…In this context, special attention is paid to the Dual Active Bridge (DAB) (i.e., a bidirectional DC/DC converter with identical full bridges on its primary and secondary side and a high frequency transformer being the set of power electronics responsible for converting MVDC to LVDC in a three-stage SST), the minimization of the core's volume, losses and cost, and the optimal incorporation of the three-stage SST in modern applications [30,31]. Such applications include a wide range of scales, from smart buildings up to entire distribution systems [32][33][34].…”
Section: Interface With the Ac Gridmentioning
confidence: 99%
“…Although its deployment is quite rare, several researchers have studied the capabilities that it provides. For instance, in [33,44,45], DC MGs with mesh configurations are presented. More specifically, in [45] an interesting aspect regarding the architecture of MGs is developed.…”
Section: Meshmentioning
confidence: 99%
“…Figure 9 shows an example of a wind energy system. [87][88][89][90] In these systems, a reactive power compensator may be needed to stabilize the voltage. However, by using and combining functions of SST such as active power transmission, reactive power compensation, and voltage regulation, a F I G U R E 5 SST applied to the distribution network 81 modern wind energy system similar to that shown in Figure 9 can be created, where SST has effectively replaced the two conventional transformers and STATCOM and internal capacitors.…”
Section: Voltage Stabilization and Regulationmentioning
confidence: 99%
“…SSTs are essentially replacing power electronic converters and low‐frequency transformers to achieve a more compact system. Figure 9 shows an example of a wind energy system 87‐90 …”
Section: Solid‐state Transformer Applicationsmentioning
confidence: 99%
“…Lately, a SST customized to provide ancillary services to the distribution grid has been attracting much of interest. 7,8 The SST was envisaged as a substitution for the conventional fundamental frequency power transformer, with subordinated volume and weight but is capable of wider applications like energy routing capabilities, RPS, and fault tolerance. 9,10 On account of this, the SST paves a contemporary path into DN integration, further sketching out the unexplored preferences that they offer.…”
Section: Introductionmentioning
confidence: 99%