Abstract:
Simulation Study for Optimized Demand Side Management in Smart
Grid
Smart grid is envisioned to meet the 21st century energy requirements in a sophisticated manner
with real time approach by integrating the latest digital communications and advanced control
technologies to the existing power grid. It will dynamically connect all the stake holders of
smart grid through enhanced energy efficiency awareness corridor.
Smart Homes (SHs), Home Energy Management Systems (HEMS) and effect of home appliances
scheduling in smart grid are now familiar research topics in electrical engineering. Peak
load management and reduction of Peak to Average Ratio (PAR) and associated methods are
under focus of researchers since decades. These topics have got new dimensions in smart grid
environment. This dissertation aims at simulation study for effective Demand SideManagement
(DSM) in smart grid environment. This work is mainly focused on optimal load scheduling for
energy cost minimization and peak load reduction.
This work comprehensively reviews the smart grid applications, communication technologies,
load management techniques, pricing schemes and related topics in order to provide an insight
to the environment required for dynamic DSM. Various network attributes such as Internet Protocol
(IP) support, power usage, data rate etc. are considered to compare the communications
technologies in smart grid context. Techniques suitable for Home Area Networks (HANs) such
as ZigBee, Bluetooth, Wi-Fi, 6LoWPAN and Z-wave are discussed and compared in context of
consumer concerns and network attributes. A similar approach in context of utilities’ concerns
is adopted for wireless communications techniques for Neighborhood Area Networks (NANs),
which include WiMAX and GSM based cellular standards. Issues and challenges regarding
dynamic DSM in smart grid have been discussed briefly.
DSM is supposed to have a vital role in future energy management systems and is one of the
hot research areas. This study presents detailed review and analytical comparison of DSM techniques
along with related technologies and implementation challenges in smart grid. It also
covers consumers and utilities concerns in context of DSM to enhance the readers’ intuition
about the topic. Two major types of DSM schemes, incentive based and dynamic pricing based,
have been discussed and compared analytically. Dynamic pricing based HEMS are emphasized
as important tools for peak load reduction and consumers’ energy cost minimization. Dynamic
pricing based HEMS and their associated optimization techniques along with analytical comparison
of the latest schemes have been described. Comparison of DSM techniques and study
of latest HEMS scheme provided the base for new ideas of partial baseline load and reserved
interrupting load to formulate two unique energy cost minimization problems. These models
resulted the following two solutions in which scheduling has been carried out through many
different algorithms to reduce peak load and consequently the PAR.
This work includes novel appliance scheduling solution named; Comprehensive Home Energy
Management Architecture (CHEMA), with multiple integrated scheduling options in smart grid
environment. Multiple layers of enhanced architecture are modeled in Simulink with embedded
MATLAB code. Single Knapsack is used for scheduling and four different cases for cost
reduction are modeled. Fault identification and electricity theft control have also been added
along with the carbon foot prints reduction for environmental concerns. Simulation results have
shown the peak load reduction of 22.9% for unscheduled load with Persons Presence Controller
(PPC), 23.15% for scheduled load with PPC and 25.56% for flexible load scheduling. Similarly
total cost reduction of 23.11%, 24% and 25.7% has been observed, respectively. Smart
grid interface layer and load forecasting layers are not implemented in current work and will be
focused in future work.
Another novel comparative approach has also been proposed in this research, which investigates
the effect of multiple pricing schemes and optimization techniques for cost minimization
and peak load reduction. The proposed model uses multiple pricing schemes including Time
of Use (ToU), Real Time Pricing (RTP) day ahead case and Critical Peak Pricing (CPP). Proposed
optimization problem has been solved with multiple optimization techniques including
Knapsack, Particle Swarm Optimization (PSO) and Genetic Algorithm (GA). Knapsack is used
with two options of limited slots scheduling and whole day scheduling. Comparative results
of the multiple pricing and optimization schemes have been discussed. Results show that the
best combination achieved with GA and CPP with 39.9223% cost reduction. PSO showed the
43.73% cost reduction with all the pricing schemes.
The proposed schemes have many applications for peak load reduction and energy cost minimization
to benefit consumers and utilities. A user can schedule his load using one of the options
provided in CHEMA according to his preferences. Similarly, maintenance activities can
be accommodated without disturbing the pre-defined schedule by using reserved interrupting
slots. In large buildings, reserved slots can be used to schedule heavy loads without generating
a peak.