REAL TIME SIMULATION OF NEW DEFENSE SCHEME BASED ON CENTRALIZED REMEDIAL ACTION FOR BATAMBINTAN ELECTRICAL SYSTEM IMPLEMENTATION
System reliability is the main factor that is maintained in the continuity of the electricity system operation. In the event of a major disruption to the power system, a defense scheme can work quickly and safely to restore the system. Existing defense systems and disruptions that can lead to ins...
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id-itb.:554912021-06-17T21:34:26ZREAL TIME SIMULATION OF NEW DEFENSE SCHEME BASED ON CENTRALIZED REMEDIAL ACTION FOR BATAMBINTAN ELECTRICAL SYSTEM IMPLEMENTATION Yosia, Nuel Indonesia Theses stability, Centralized Remedial Action Scheme, Hardware-in-TheLoop real-time simulation, IEC 61850, load and generation shedding, INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/55491 System reliability is the main factor that is maintained in the continuity of the electricity system operation. In the event of a major disruption to the power system, a defense scheme can work quickly and safely to restore the system. Existing defense systems and disruptions that can lead to instability consist of UFLS, OGS, and other schemes. This scheme describes the design of the Centralized Remedial Action Scheme for the existing scheme implemented in the defense scheme in the BatamBintan system. The CRAS scheme will use the HYPERSIM simulator with OPALRT as Hardware In The Loop to perform real-time simulations, the SEL-3530 RTAC as the main processor for the RAS algorithm, and SEL 751 as the mitigation relay IED to send digital output CB commands back to HYPERSIM, where all This security equipment will be connected using an ethernet cable and communicated using the IEC 61850 GOOSE Protocol. The 8 types of vulnerability in the system are implemented as an event-based algorithm that immediately executes through critical component CB status information, which is then effectively mitigated by using load shedding and generation steps. The results obtained are 8 types of vulnerability that can be overcome by minimizing load discharges or generations curtailment by equalizing the power deficit. The system frequency value can stabilize again within 5-8 seconds of the disturbance, and the transient response can return to a stable state value of 50 Hz. CRAS schemes can also be run by equipment with a duration of 30-40 ms from the start of the fault event to the CB opening command. text |
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Indonesia |
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System reliability is the main factor that is maintained in the continuity of the
electricity system operation. In the event of a major disruption to the power system,
a defense scheme can work quickly and safely to restore the system. Existing defense
systems and disruptions that can lead to instability consist of UFLS, OGS, and other
schemes. This scheme describes the design of the Centralized Remedial Action
Scheme for the existing scheme implemented in the defense scheme in the BatamBintan system. The CRAS scheme will use the HYPERSIM simulator with OPALRT as Hardware In The Loop to perform real-time simulations, the SEL-3530 RTAC
as the main processor for the RAS algorithm, and SEL 751 as the mitigation relay
IED to send digital output CB commands back to HYPERSIM, where all This
security equipment will be connected using an ethernet cable and communicated
using the IEC 61850 GOOSE Protocol. The 8 types of vulnerability in the system
are implemented as an event-based algorithm that immediately executes through
critical component CB status information, which is then effectively mitigated by
using load shedding and generation steps. The results obtained are 8 types of
vulnerability that can be overcome by minimizing load discharges or generations
curtailment by equalizing the power deficit. The system frequency value can
stabilize again within 5-8 seconds of the disturbance, and the transient response
can return to a stable state value of 50 Hz. CRAS schemes can also be run by
equipment with a duration of 30-40 ms from the start of the fault event to the CB
opening command.
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| format |
Theses |
| author |
Yosia, Nuel |
| spellingShingle |
Yosia, Nuel REAL TIME SIMULATION OF NEW DEFENSE SCHEME BASED ON CENTRALIZED REMEDIAL ACTION FOR BATAMBINTAN ELECTRICAL SYSTEM IMPLEMENTATION |
| author_facet |
Yosia, Nuel |
| author_sort |
Yosia, Nuel |
| title |
REAL TIME SIMULATION OF NEW DEFENSE SCHEME BASED ON CENTRALIZED REMEDIAL ACTION FOR BATAMBINTAN ELECTRICAL SYSTEM IMPLEMENTATION |
| title_short |
REAL TIME SIMULATION OF NEW DEFENSE SCHEME BASED ON CENTRALIZED REMEDIAL ACTION FOR BATAMBINTAN ELECTRICAL SYSTEM IMPLEMENTATION |
| title_full |
REAL TIME SIMULATION OF NEW DEFENSE SCHEME BASED ON CENTRALIZED REMEDIAL ACTION FOR BATAMBINTAN ELECTRICAL SYSTEM IMPLEMENTATION |
| title_fullStr |
REAL TIME SIMULATION OF NEW DEFENSE SCHEME BASED ON CENTRALIZED REMEDIAL ACTION FOR BATAMBINTAN ELECTRICAL SYSTEM IMPLEMENTATION |
| title_full_unstemmed |
REAL TIME SIMULATION OF NEW DEFENSE SCHEME BASED ON CENTRALIZED REMEDIAL ACTION FOR BATAMBINTAN ELECTRICAL SYSTEM IMPLEMENTATION |
| title_sort |
real time simulation of new defense scheme based on centralized remedial action for batambintan electrical system implementation |
| url |
https://digilib.itb.ac.id/gdl/view/55491 |
| _version_ |
1822274279875543040 |