Simulation of a controlled water heating system with demand response remunerated on imbalance market pricing

Abstract: Buildings are responsible for 40% of our worldwide energy consumption and 50% of this energy is converted for HVAC systems in buildings (e.g. for hot water). Through demand response it becomes possible to activate these systems and aiding in balancing the net. We simulated a domestic water heater participating in the balancing of the electricity net and calculated the revenue from this action. The transmission system operator rewards active participation in delivering balancing energy. We simulate a water heat… Show more

“…Alternatively, energy companies can pay a flexibility bonus per kWh of shifted demand. It has been shown that such incentives can greatly improve the return on investment [37,69]. However, too many incentives without regulation can lead to the use of less efficient technologies which offer greater flexibility.…”

Analysing the Economic Viability of Implicit Demand Response Control of Thermal Energy Storage in Hot Water Tanks

“…Alternatively, energy companies can pay a flexibility bonus per kWh of shifted demand. It has been shown that such incentives can greatly improve the return on investment [37,69]. However, too many incentives without regulation can lead to the use of less efficient technologies which offer greater flexibility.…”

Analysing the Economic Viability of Implicit Demand Response Control of Thermal Energy Storage in Hot Water Tanks

“…Most of the previous studies about demand response J o u r n a l P r e -p r o o f 3 focused on energy management [10,11] to match energy generation and consumption with the behavior and comfort of occupants [12,13]. Demand response in building energy systems usually aimed to use low-cost [14] or low CO 2 emissions energy by shifting consumption times [15]. To meet the requirements of diversified energy systems in the future, the measurements to increase the energy flexibility of buildings regarding both electricity and thermal systems were also studied [16,17].…”

Demand response of district heating using model predictive control to prevent the draught risk of cold window in an office building

Coordinated optimization of robustness and flexibility of building heating systems for demand response control considering prediction uncertainty