How combination of control methods and renewable energies leads a large commercial building to a zero-emission zone-A case study in US

This paper aims to develop a decision-making tool to minimize large commercial buildings' Heating, Ventilation, Air-conditioning, and Cooling (HVAC) system environmental footprints. We modeled a terminal of an airport as a case study constituting hot water boilers, chillers, and air handling units, which forms the initial HVAC system, in EnergyPlus. The case study model is validated with monthly energy consumption data. Then, the decision-making system is applied on the retrofitted hybrid HVAC system resulted by combining Building Integrated Photovoltaic (BIPV) system, Combined Cooling, Heating and Power (CCHP) unit, and existing HVAC system. The decision-making system is developed based on three kinds of optimized controllers including Model Predictive Controller (MPC), Fuzzy Sliding Mode Control (FSMC), and relay controller (Initial controller of HVAC system). The optimization is designed based on reducing CO2 emission as well as providing comfort temperature. We found that retrofitting by hybrid system reduces emission by 90% compared with the initial system and applying intelligent controllers including MPC and FSMC, improve it to 95% CO2 emission reduction. While initial system provides comfort temperature 85% of the simulation period, retrofitted HVAC system controlled by MPC or FSMC sets indoor temperature 96% of 1-year simulation.

Automated summary

This paper aims to develop a decision-making tool to minimize the environmental footprints of HVAC systems in large commercial buildings. A case study is conducted on an airport terminal, where the initial HVAC system is modeled using hot water boilers, chillers, and air handling units. The decision-making system is then applied to a retrofitted hybrid HVAC system, which combines Building Integrated Photovoltaic (BIPV) system, Combined Cooling, Heating and Power (CCHP) unit, and the existing HVAC system.