论文信息 - An analysis of peak demand reductions due to elasticity of domestic appliances

An analysis of peak demand reductions due to elasticity of domestic appliances

Unlike prior work on demand management, which typically requires industrial loads to be turned off during peak times, this paper studies the potential to carry out demand response by modifying the elastic load components of common household appliances. Such a component can decrease its instantaneous power draw at the expense of increasing its duration of operation with no impact on the appliance's lifetime. We identify the elastic components of ten common household appliances. Assuming separate control of an appliance's elastic component, we quantify the relationship between the potential reduction in aggregate peak and the duration required to complete the operation of appliances in four geographic regions: Ontario, Quebec, France and India. We find that even with a small extension to the operation duration of appliances, peak demand can be significantly reduced in all four regions both during winter and summer. For example, during winter in Quebec, a nearly 125 MW reduction in peak demand can be obtained with just a 10% increase in appliance operation duration. We conclude that exploiting appliance elasticity to reduce peak power demand should be an important consideration for appliance manufacturers. From a policy perspective, our study gives regulators the ability to quantitatively assess the impact of requiring manufacturers to conform to “smart appliance” standards.

[1] Iain MacGill,et al. Coordinated Scheduling of Residential Distributed Energy Resources to Optimize Smart Home Energy Services , 2010, IEEE Transactions on Smart Grid.

[2] Nanming Chen,et al. Air conditioner direct load control by multi-pass dynamic programming , 1995 .

[3] Na Li,et al. Optimal demand response based on utility maximization in power networks , 2011, 2011 IEEE Power and Energy Society General Meeting.

[4] E Bonneville,et al. DEMAND SIDE MANAGEMENT FOR RESIDENTIAL AND COMMERCIAL END-USERS , 2006 .

[5] Farrokh Albuyeh,et al. Grid of the future , 2009, IEEE Power and Energy Magazine.

[6] Georgios B. Giannakis,et al. Cooperative multi-residence demand response scheduling , 2011, 2011 45th Annual Conference on Information Sciences and Systems.

[7] A. V. Meier. Electric power systems : a conceptual introduction , 2006 .

[8] G. Pistoia,et al. Electric and hybrid vehicles : power sources, models, sustainability, infrastructure and the market , 2010 .

[9] Tooraj Jamasb,et al. The Future of Electricity Demand : customers, citizens and loads , 2011 .

[10] David Angeli,et al. Decentralized random control of refrigerator appliances , 2011 .

[11] Sakis Meliopoulos,et al. Simulated demand response of a residential energy management system , 2011, IEEE 2011 EnergyTech.

[12] M. Ivimey. Annual report , 1958, IRE Transactions on Engineering Writing and Speech.