Hierarchical market integration of responsive loads as spinning reserve

Applied Energy

Volumn 104, Issue , 2013, Pages 229-238

  Wang, D ^a   Parkinson, S ^a   Miao, W ^b   Jia, H ^b   Crawford, C ^a   Djilali, N ^a  

^a UNIVERSITY OF VICTORIA   (Canada)

^b TIANJIN UNIVERSITY   (China)

Author keywords

Demand response; Economic dispatch; Electric vehicles; Heat pumps; Hydrogen production; Virtual power plant

Indexed keywords

ELECTRIC VEHICLES; ELECTROLYTIC CELLS; HEAT PUMP SYSTEMS; HYDROGEN PRODUCTION; INTEGRATION; POWER PLANTS; SCHEDULING;

ACTIVE POWER; BOTTOM-UP MODELING; DEMAND RESPONSE; DEMAND-SIDE; ECONOMIC DISPATCH; ECONOMIC EFFICIENCY; ELECTROLYZERS; HEAT PUMPS; MANAGEMENT POLICY; MARKET INTEGRATION; NEW SOURCES; OPERATING CHARACTERISTICS; POTENTIAL IMPACTS; RESERVE CAPACITY; RESPONSIVE LOAD; SECURITY-CONSTRAINED ECONOMIC DISPATCH; SPINNING RESERVES; VIRTUAL POWER PLANTS;

COMMERCE;

BOTTOM-UP APPROACH; COST-BENEFIT ANALYSIS; DEMAND ANALYSIS; ELECTRIC VEHICLE; EMISSION; HIERARCHICAL SYSTEM; HYDROGEN; INTEGRATED APPROACH; MANAGEMENT PRACTICE; MARKET SYSTEM; POWER GENERATION; POWER PLANT; PUMP; VIRTUAL REALITY;

EID: 84870916140     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2012.10.054     Document Type: Article

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