Transactive Control of Commercial Buildings for Demand Response

Transactive control is a type of distributed control strategy that uses market mechanisms to engage self-interested responsive loads to achieve power balance in the electrical power grid. In this paper, we propose a transactive control approach of commercial building heating, ventilation, and air-co...

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Published in	IEEE transactions on power systems Vol. 32; no. 1; pp. 774 - 783
Main Authors	He Hao, Corbin, Charles D., Kalsi, Karanjit, Pratt, Robert G.
Format	Journal Article
Language	English
Published	New York IEEE 01.01.2017 The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects	Air conditioners Air conditioning Atmospheric modeling Buildings Clearing Commercial buildings Computer simulation Control systems Cooling Data models demand response ENERGY CONSERVATION, CONSUMPTION, AND UTILIZATION HVAC HVAC equipment HVAC systems Load management Load modeling market mechanism Markets Parameter identification Systems engineering Temperature measurement transactive control Ventilation Virtual environments
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Abstract	Transactive control is a type of distributed control strategy that uses market mechanisms to engage self-interested responsive loads to achieve power balance in the electrical power grid. In this paper, we propose a transactive control approach of commercial building heating, ventilation, and air-conditioning (HVAC) systems for demand response. We first describe the system models, and identify their model parameters using data collected from systems engineering building (SEB) located on our Pacific Northwest National Laboratory campus. We next present a transactive control market structure for commercial building HVAC systems, and describe its agent bidding and market clearing strategies. Several case studies are performed in a simulation environment using building controls virtual test bed (BCVTB) and calibrated SEB EnergyPlus model. We show that the proposed transactive control approach is very effective at peak shaving, load shifting, and strategic conservation for commercial building HVAC systems.
AbstractList	Transactive control is a type of distributed control strategy that uses market mechanism to engage self-interested responsive loads to achieve power balance in the electrical power grid. In this paper, we propose a transactive control approach of commercial building Heating, Ventilation, and Air- Conditioning (HVAC) systems for demand response. We first describe the system models, and identify their model parameters using data collected from Systems Engineering Building (SEB) located on our Pacific Northwest National Laboratory (PNNL) campus. We next present a transactive control market structure for commercial building HVAC system, and describe its agent bidding and market clearing strategies. Several case studies are performed in a simulation environment using Building Control Virtual Test Bed (BCVTB) and calibrated SEB EnergyPlus model. We show that the proposed transactive control approach is very effective at peak clipping, load shifting, and strategic conservation for commercial building HVAC systems. Transactive control is a type of distributed control strategy that uses market mechanisms to engage self-interested responsive loads to achieve power balance in the electrical power grid. In this paper, we propose a transactive control approach of commercial building heating, ventilation, and air-conditioning (HVAC) systems for demand response. We first describe the system models, and identify their model parameters using data collected from systems engineering building (SEB) located on our Pacific Northwest National Laboratory campus. We next present a transactive control market structure for commercial building HVAC systems, and describe its agent bidding and market clearing strategies. Several case studies are performed in a simulation environment using building controls virtual test bed (BCVTB) and calibrated SEB EnergyPlus model. We show that the proposed transactive control approach is very effective at peak shaving, load shifting, and strategic conservation for commercial building HVAC systems.
Author	He Hao Corbin, Charles D. Kalsi, Karanjit Pratt, Robert G.
Author_xml	– sequence: 1 surname: He Hao fullname: He Hao email: He.Hao@pnnl.gov organization: Electr. Infrastruct. & Buildings Div., Pacific Northwest Nat. Lab., Richland, WA, USA – sequence: 2 givenname: Charles D. surname: Corbin fullname: Corbin, Charles D. email: Charles.Corbin@pnnl.gov organization: Electr. Infrastruct. & Buildings Div., Pacific Northwest Nat. Lab., Richland, WA, USA – sequence: 3 givenname: Karanjit surname: Kalsi fullname: Kalsi, Karanjit email: Karanjit.Kalsi@pnnl.gov organization: Electr. Infrastruct. & Buildings Div., Pacific Northwest Nat. Lab., Richland, WA, USA – sequence: 4 givenname: Robert G. surname: Pratt fullname: Pratt, Robert G. email: Robert.Pratt@pnnl.gov organization: Electr. Infrastruct. & Buildings Div., Pacific Northwest Nat. Lab., Richland, WA, USA
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Snippet	Transactive control is a type of distributed control strategy that uses market mechanisms to engage self-interested responsive loads to achieve power balance... Transactive control is a type of distributed control strategy that uses market mechanism to engage self-interested responsive loads to achieve power balance in...
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SubjectTerms	Air conditioners Air conditioning Atmospheric modeling Buildings Clearing Commercial buildings Computer simulation Control systems Cooling Data models demand response ENERGY CONSERVATION, CONSUMPTION, AND UTILIZATION HVAC HVAC equipment HVAC systems Load management Load modeling market mechanism Markets Parameter identification Systems engineering Temperature measurement transactive control Ventilation Virtual environments
Title	Transactive Control of Commercial Buildings for Demand Response
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