A Simulation Model With Multi-Attribute Utility Functions For Energy Consumption Scheduling In A Smart Grid

Keywords

Demand response; Smart grid; Utility theory

Abstract

When consumers’ use of electricity is mainly driven by convenience, coincident demand occurs, resulting in electric load peaks. Consequently, the undesirable large gaps between peak and off-peak loads will adversely affect the system’s efficiency due to unused capacity during off-peak hours and extra ancillary generators required during peak hours. Demand response (DR) has long been proposed to reduce peak load by providing incentives to encourage consumers to shift their peak loads to off-peak periods. In most DR literature, incentive schemes are purely financial in assuming that cost is the only parameter to influence consumers’ load-shifting behavior. In this paper, we assume that in addition to cost, convenience of energy usage is also an important factor when consumers respond to DR programs. Hence, we use multi-attribute utility functions consisting of both cost and convenience factors to model consumer behavior on energy consumption for home appliances. The “convenience” herein is defined as being able to use an appliance during one’s preferred time window. A simulation model is developed to study a residential population consisting of heterogeneous households with varying preference of convenience over cost. We study the effects of time-of-use pricing structure on users’ utility-based load shifting behaviors and subsequently on system-wide performances such as peak to average ratio (PAR) and load variance (LV). We also describe a method of design of experiment (DOE) for determining an optimal time-of-use rate structure that minimizes both PAR and LV for the system.

Publication Date

11-1-2015

Publication Title

Energy Systems

Volume

6

Issue

4

Number of Pages

533-550

Document Type

Article

Personal Identifier

scopus

DOI Link

https://doi.org/10.1007/s12667-015-0153-9

Socpus ID

84944454338 (Scopus)

Source API URL

https://api.elsevier.com/content/abstract/scopus_id/84944454338

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