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2022 | OriginalPaper | Buchkapitel

3. Virtual Power Plant System

verfasst von : Chuzo Ninagawa

Erschienen in: Virtual Power Plant System Integration Technology

Verlag: Springer Singapore

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Abstract

As described in the proceeding chapters, in present power system, the demand and supply are controlled only by generation side, according to the fluctuation of the power consumption on the demand side. However, if the number of renewable power generation facilities such as solar power generation and wind power generation increases, the proportion of the amount of supply that can be controlled by governor control or LFC control described in the Chap. 2 decreases relatively and control according to the demand side becomes difficult.

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Vorheriges Kapitel Power Supply and Demand Balance

Nächstes Kapitel Components of Virtual Power Plant

Technical report of the Inst. of Electrical Engineers of Japan, Standard Analysis Model for Power Supply and Demand/Frequency Simulation, No. 1386 (2016)

C. Ninagawa, H. Asaka, M. Takahama, Asymmetric constant-rate transfer function model for FastADR feedback control of a cluster of building multi-type air-conditoners. IEEJ Trans. Power Energy 137(8), 566–572 (2017) (in Japanese)

K. Suzuki, C. Ninagawa, J. Morikawa, Estimation on averaging effect of large-scale aggregation of DR transient responses of building multi-type air-conditioning facilities. IEEJ Trans. Power Energy 138(7), 582–590 (2018) (in Japanese)

OpenADR Alliance. https://www.openadr.org/

M. Piette et al., Open Automated Demand Response Communications Specification (Version 1.0), LBNL Report 1779E (2009)

OASIS Standard, Energy Interoperation Version 1.0, OASIS Committee Specification Draft 01, 2010. http://docs.oasis-open.org/energyinterop/ei/v1.0/os/energy-interop-v1.0-os.html

IEC standard, Reference Architecture for Electric Power Systems, IEC 61850 (2011)

IEEE standard for Ubiquitous Green Community Control Network Protocol, IEEE1888-2011 (2011)

Open System for Energy Services (OS4ES). http://www.os4es.eu/

10.

IEC Standard, Specific Communication Service Mapping (SCSM)—Mappings to MMS (ISO 9506-1 and ISO 9506-2) and to ISO/IEC 8802-3, IEC 61805-8-1 (2004)

11.

ISO Standard, Industrial Automation Systems—Manufacturing Message Specification, ISO9506:2003 (2003)

12.

IEC standard, Communication Networks and Systems for Power Utility Automation-Part 6: Configuration Description Language for Communication in Electrical Substations Related to IEDs, IEC 61850-6 (2009)

13.

IEEE standard, Ubiquitous Green Community Control Network Protocol, IEEE1888-2011 (2011)

14.

Green University of Tokyo Project. http://www.gutp.jp/

15.

C. Ninagawa, H. Yoshida, S. Kondo, H. Otake, Data transmission of IEEE1888 communication for wide-area real-time smart grid applications, in International Renewal and Sustainable Energy Conference IRSEC’13, pp.1–6 (2013)

16.

C. Ninagawa, T. Iwahara, K. Suzuki, Enhancement of OpenADR Communication for Flexible FastADR Aggregation Using TRAP Mechanism of IEEE1888 Protocol, in IEEE International Conference on Industrial Technologies, ICIT 2015, Seville, Spain (2015)

17.

T. Iwahara, T. Yamada, C. Ninagawa, Smart grid OpenADR communication Realized by Using IEEE188TRAP Mechanism’s Flexible Server-Push Capability, in IEEJ Technical Meeting on Smart Facilities, SMF-15-014 (2015) (in Japanese)

Titel: Virtual Power Plant System
verfasst von: Chuzo Ninagawa
Verlag: Springer Singapore
Buch: Virtual Power Plant System Integration Technology
Print ISBN: 978-981-16-6147-1

Electronic ISBN: 978-981-16-6148-8

Copyright-Jahr: 2022
DOI: https://doi.org/10.1007/978-981-16-6148-8_3