2006 IEEE Power Engineering Society General Meeting 2006
DOI: 10.1109/pes.2006.1709502
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Benefits of power electronic interfaces for distributed energy systems

Abstract: Abstract-With the increasing use of distributed energy (DE) systems in industry and its technological advancement, it is becoming more important to understand the integration of these systems with the electric power systems. New markets and benefits for DE applications include the ability to provide ancillary services, improve energy efficiency, enhance power system reliability, and allow customer choice. Advanced power electronic (PE) interfaces will allow DE systems to provide increased functionality through… Show more

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Cited by 89 publications
(49 citation statements)
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“…A useful feature of a power electronic interface is the ability to reduce or eliminate fault current contributions from distributed energy system, thereby allowing negligible impacts on protection coordination. Finally, power electronic interfaces provide flexibility in operations with various other DERs, and can potentially reduce overall interconnection costs through standardization and modularity [91]. This issue is discussed in [92] in which a power-electronic interface, including an ESS module and an inverter for coupling DERs within a microgrid is introduced.…”
Section: Application Of Power Electronics In Microgridsmentioning
confidence: 99%
“…A useful feature of a power electronic interface is the ability to reduce or eliminate fault current contributions from distributed energy system, thereby allowing negligible impacts on protection coordination. Finally, power electronic interfaces provide flexibility in operations with various other DERs, and can potentially reduce overall interconnection costs through standardization and modularity [91]. This issue is discussed in [92] in which a power-electronic interface, including an ESS module and an inverter for coupling DERs within a microgrid is introduced.…”
Section: Application Of Power Electronics In Microgridsmentioning
confidence: 99%
“…After the fault occurs, the arm inductors suffer a high fault short-circuit voltage, as depicted by (6), which causes a rapid increase of fault currents. Thus, the active dc component control of fault current is required to have a fast response and the ability to predict the future error of the system response.…”
Section: Active Fault Current Control Strategymentioning
confidence: 99%
“…The dc circuit breakers (DCCBs), including mechanical DCCBs, solid-state DCCBs, and hybrid DCCBs, have the potential to isolate a dc fault and protect stations from damage. However, the response of conventional mechanical DCCBs is slow and converter semiconductors endure high current stress during the response time [5][6][7]. The solid-state DCCBs can rapidly isolate a fault but at high capital cost and significant on-state losses.…”
Section: Introductionmentioning
confidence: 99%
“…As a result of the growing concerns about distributed generation, the paradigms of microgrids and smart grids have emerged and gained attention over the last years [10] [11] [12], in which power electronics undergoes an essential involvement [13]. Concerning microgrids, these can operate either in islanded mode or in grid-connected mode.…”
Section: Introductionmentioning
confidence: 99%