4.8 Article

An internal trading strategy for optimal energy management of combined cooling, heat and power in building microgrids

Journal

APPLIED ENERGY
Volume 239, Issue -, Pages 536-548

Publisher

ELSEVIER SCI LTD
DOI: 10.1016/j.apenergy.2019.01.160

Keywords

Building energy management system; Building microgrid operation; Community energy management system; Combined cooling, heat, and power; Internal trading strategy

Funding

  1. National Research Council of Science & Technology (NST) - Korea government (MSIP) [CRC-15-01-KIST]
  2. National Research Council of Science & Technology (NST), Republic of Korea [CRC-15-01-KIST] Funding Source: Korea Institute of Science & Technology Information (KISTI), National Science & Technology Information Service (NTIS)

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This paper proposes a three-step internal trading strategy for optimal energy sharing among building microgrids (MGs) to minimize the operation cost of the entire system. In the first step, barter trading is performed to exchange energies among building MGs of the network. Building MGs having shortage of electricity and surplus of heat can pair with buildings having surplus of electricity and shortage of heat to exchange their energies. Then, the surplus/shortage energy is updated after carrying out the barter trading. In the second step, building MGs sell their remaining surplus energy to other building MGs that have shortage energy. In the third step, building MGs, which have lower generation cost than the external system and ability to increase their power generation, increase their power generation and trade with other building MGs. These three steps can increase the power sharing among building MGs and reduce the trading with the external systems, which results in reduced operation cost of the network. An additional internal market along with price signals is also presented to carry out the proposed internal trading strategy. The internal market provides a mechanism for trading energies among the building MGs of a combined cooling, heat and power (CCHP) system. A hierarchical energy management system (EMS), including building EMSs (BEMSs) and a community EMS (C-EMS) is developed to minimize the operation cost of the CCHP system. Moreover, a heat pipeline (HPL) system is applied for storing the surplus heat energy for fulfilling the shortage heat energy in the building MGs. By using the proposed strategy, total trading cost of CCHP system is reduced by 7.43% compared with the conventional operation strategy.

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