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DTSTART;TZID=Europe/London:20230718T140000
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DESCRIPTION:The electric power system is going through an unprecedented tra
 nsformation and related challenges in the implementation of smart grids. T
 he smart grid is based on the flexible electrical power system that coordi
 nates different energy resources and loads with the aim of delivering sust
 ainable\, economical and reliable electrical supply to the loads in an eff
 icient manner. In this presentation\, a plug and play type autonomous-micr
 ogrid system formation is proposed. Multiple distributed generating source
 s and loads interaction is considered pertaining to the stability of the m
 icro-grid. The proposed method enables communication-less operation of eac
 h of the elements of the micro-grid system. It is also considered that the
  sources are of different power capacity as can be seen in a typical auton
 omous micro-grid system. Spatial Repetitive Controller (SRC) is proposed t
 o control each of the distributed generating sources in a decentralized ma
 nner to stabilize the overall micro-grid system. The proposed system consi
 ders sudden change in load as well as other distributed generators conditi
 ons like a true plug and play operation. A novel signature frequency volta
 ge injection method is proposed to identify the presence of special distri
 buted generator and operation of backup distributed generators. The implem
 ented control architecture also ensures stability of the micro-grid fundam
 ental frequency even in the case of dynamic conditions unlike the traditio
 nal droop-control method. A detailed experimental study is carried out and
  the experimental results presented show the efficacy of the proposed syst
 em.\n\nCo-sponsored by: University of Cambridge\n\nRoom: CGC Seminar Room\
 , 9 JJ Thomson Avenue\, Department of Engineering\, University of Cambridg
 e\, Cambridge\, England\, United Kingdom\, CB3 0FA
LOCATION:Room: CGC Seminar Room\, 9 JJ Thomson Avenue\, Department of Engin
 eering\, University of Cambridge\, Cambridge\, England\, United Kingdom\, 
 CB3 0FA
ORGANIZER:bing.ji@leicester.ac.uk
SEQUENCE:10
SUMMARY:PELS Distinguished Lecturer event on Plug and Play Microgrid System
URL;VALUE=URI:https://events.vtools.ieee.org/m/366764
X-ALT-DESC:Description: <br /><p>The electric power system is going through
  an unprecedented transformation and related challenges in the implementat
 ion of smart grids. The smart grid is based on the flexible electrical pow
 er system that coordinates different energy resources and loads with the a
 im of delivering sustainable\, economical and reliable electrical supply t
 o the loads in an efficient manner. In this presentation\, a plug and play
  type autonomous-microgrid system formation is proposed. Multiple distribu
 ted generating sources and loads interaction is considered pertaining to t
 he stability of the micro-grid. The proposed method enables communication-
 less operation of each of the elements of the micro-grid system. It is als
 o considered that the sources are of different power capacity as can be se
 en in a typical autonomous micro-grid system. Spatial Repetitive Controlle
 r (SRC) is proposed to control each of the distributed generating sources 
 in a decentralized manner to stabilize the overall micro-grid system. The 
 proposed system considers sudden change in load as well as other distribut
 ed generators conditions like a true plug and play operation. A novel sign
 ature frequency voltage injection method is proposed to identify the prese
 nce of special distributed generator and operation of backup distributed g
 enerators. The implemented control architecture also ensures stability of 
 the micro-grid fundamental frequency even in the case of dynamic condition
 s unlike the traditional droop-control method. A detailed experimental stu
 dy is carried out and the experimental results presented show the efficacy
  of the proposed system.&nbsp\;</p>\n<div id="simple-translate" class="sim
 ple-translate-system-theme">\n<div>\n<div class="simple-translate-button i
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