Efficient simulation methods of large power systems with high penetration of renewable energy resources : theory and applications
Resumen
Electrical energy is one of the most common forms of energy these days. Consequently,
electric power system is an indispensable part of any society. However, due to
the deregulation of electricity markets and the growth in the share of power generation
by uncontrollable renewable energies such as wind and solar, power system simulations
are more challenging than earlier. Thus, new techniques for simplifying these
simulations are needed. One important example of such simplification techniques is
the power system reduction.
Power system reduction can be used at least for four different purposes: a) Simplifying
the power system simulations, b) Reducing the computational complexity, c)
Compensating the data unavailability, and d) Reducing the existing uncertainty. Due
to such reasons, power system reduction is an important and necessary subject, but a
challenging task to do. Power system reduction is even more essential when system
operators are facing very large-scale power systems and when the renewable energy
resources like hydro, wind, and solar have a high share in power generation.
This thesis focuses on the topic of large-scale power system reduction with high
penetration of renewable energy resources and tries to pursue the following goals:
• The thesis first reviews the different methods which can be used for simplifying
the power system studies, including the power system reduction. A comparison among
three important simplification techniques is also performed to reveal which simplification
results in less error and more simulation time decrement.
• Secondly, different steps and methods for power system reduction, including network
aggregation and generation aggregation, are introduced, described and discussed.
• Some improvements regarding the subject of power system reduction, i.e. on both
network aggregation and generation aggregation, are developed.
• Finally, power system reduction is applied to some power system problems and the
results of these applications are evaluated.
A general conclusion is that using power system simplification techniques and
specially the system reduction can provides many important advantages in studying
large-scale power systems with high share of renewable energy generations. In most of
applications, not only the power system reduction highly reduces the complexity of the
power system study under consideration, but it also results in small errors. Therefore,
it can be used as an efficient method for dealing with current bulk power systems with
huge amounts of renewable and distributed generations.