Abstract
This paper presents real time information based energy management algorithms to reduce electricity cost and peak to average ratio (PAR) while preserving user comfort in a smart home. We categorize household appliances into thermostatically controlled (tc), user aware (ua), elastic (el), inelastic (iel) and regular (r) appliances/loads. An optimization problem is formulated to reduce electricity cost by determining the optimal use of household appliances. The operational schedules of these appliances are optimized in response to the electricity price signals and customer preferences to maximize electricity cost saving and user comfort while minimizing curtailed energy. Mathematical optimization models of tc appliances, i.e., air-conditioner and refrigerator, are proposed which are solved by using intelligent programmable communication thermostat ( iPCT). We add extra intelligence to conventional programmable communication thermostat (CPCT) by using genetic algorithm (GA) to control tc appliances under comfort constraints. The optimization models for ua, el, and iel appliances are solved subject to electricity cost minimization and PAR reduction. Considering user comfort, el appliances are considered where users can adjust appliance waiting time to increase or decrease their comfort level. Furthermore, energy demand of r appliances is fulfilled via local supply where the major objective is to reduce the fuel cost of various generators by proper scheduling. Simulation results show that the proposed algorithms efficiently schedule the energy demand of all types of appliances by considering identified constraints (i.e., PAR, variable prices, temperature, capacity limit and waiting time).
Highlights
With the rapid increase in the world’s population, electricity demand increases
We propose an algorithm to control energy consumption and electricity cost of heating ventilation and air conditioning (HVAC) system while considering dynamic pricing and user comfort constraints
The energy management system works efficiently there might be some complexities when using the small time window: (i) processing time can be increased; (ii) system complexities may increase because it is comparatively more complex to handle short time windows; (iii) it is very difficult for utilities to design real time demand response (DR) programs based on small time slots
Summary
With the rapid increase in the world’s population, electricity demand increases. It is estimated that total energy demand at the end of 2020 will increase by 75% as compared to 2000 [1]. This increase may force utilities to rethink electricity generation and distribution in order to avoid unprecedented energy challenges. The utilities struggle to fulfill and manage the energy demand with smart generation with reduced carbon emissions. For this purpose, the traditional electric grid is evolving to a new smart grid (SG) [2]. In SG, advanced information and communication technologies provide flexibility to interact customers with utility [3,4].
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