Abstract:
In current scenario, the integration of renewable energy resources (RESs) especially,
wind and PV generation, has been tremendously increasing due to the three key factors,
namely environmental concerns, technological innovation and government new policies.
However, the planning, operation and control of distribution systems are significantly be coming a challenge to accommodate the large number of installation and penetration of
intermittent RESs. Typically, the intermittent RESs have impact on voltage constraints,
network efficiency, voltage stability, and congestion. However, flexible sources (e.g. bat tery energy storage, dispatchable generation and flexible demands) alleviate the impacts
of the intermittent and variable production of RESs. Recently, the updated IEEE 1547
− 2018 standard stated that all inverter-interfaced distributed energy resources (DER) to
be equipped with smart inverter functions (e.g. volt−var mode, volt−watt mode, voltage
ride through, etc.). Thereby, smart inverter can provide effective solutions to alleviate the
operational challenges of connecting the large number of intermittent RESs. However, the
abnormal proliferation of RESs in terms of installations number, types, locations, capacity
and connection time can impose the planning challenges to the utilities. Typically, utilities
have maintained the network performance (e.g., voltage profile, network losses, maximum
voltage rise and voltage drop limits, system reliability) over the use of utility-owned volt age control devices, such as on-load tap changing transformers (OLTC), voltage regulators
(VRs), reactive power compensators (RPCs), remoted controlled switches (RCSs) and ca pacitor banks (CBs). However, abnormal and high proliferation of RESs in the network
can impact the effectiveness of the existing devices. Thus, the conventional planning and
operation decisions are needed to updated with advanced devices such that they are flexi bly adaptable to any diverse proliferation of RESs in the distribution networks. Although,
active network management schemes such as distribution network reconfiguration (DNR)
and volt-VAR control (VVC) techniques have been employed for improving network per vformance and enhance the system reliability. Nevertheless, these techniques have been
implemented separately. Moreover, conventional VVC operation has been performed by
traditional voltage control devices, which could not handle the sharp voltage violations
caused by the intermittent nature of RESs. Further, frequent operation of these devices
deteriorates their lifetime. Hence, there is a need of fast acting voltage regulation devices
(e.g. smart inverter) along with traditional VVC devices to encounter these issues. How ever, without proper coordination of these devices may cause a detrimental impact on
distribution operations and network assets. Therefore, the proper planning and operation
of DERs in conjunction with advanced distribution management schemes are required
for improving the distribution network performance and accommodation of high RESs
penetration.
In this thesis, an integrated approach has been proposed for performance enhance ment of distribution network and accommodation of high RESs penetration. Under this
approach the following five aspects have been accomplished: 1) developed a new method ology for combined operation of distribution network reconfiguration (DNR) and volt-var
control (VVC) devices in the presence of DERs. 2) developed a time series model of
coordinated VVC scheme considering DNR and soft open point operations. 3) devel oped a hierarchical coordinated volt-VAR optimization (VVO) methodology for conflict
objectives. 4) developed the real time hierarchical coordinated voltage control of smart
inverters for active distribution network with high PV penetration. 5) developed two-layer
coordinated optimization framework for planning and operation of DERs.
The first part presents an efficient and optimal approach for combined operation
of DNR and VVC techniques. To achieve the optimal solution, modified binary grey
wolf optimization (MBGWO) algorithm has been proposed. In the proposed approach,
a centralised as well as local control schemes have been employed for optimal operation
of distribution network such that no system constraints are violated. Centralized control
scheme provides the optimal set points for field devices in regular intervals based on mea surements fed back through advanced metering infrastructure (AMI) and control sensors
through communication infrastructures. However, local control scheme action executed
based on local measurements or the criterion adopted by the local operator. Besides, pro posed method has been employed for service restoration considering voltage regulation
and peak demand reduction under faulty condition. For validation, the performance of
vithe proposed algorithm has been tested on balanced as well as unbalanced distribution
systems.
The second part presents a time series model of coordinated VVC scheme to minimize
the energy demand including operating cost in distribution system considering DNR.
Besides, soft open point (SOP) a flexible power electronic device has been introduced in
the VVC scheme. Instead of simply opening/closing normally-open points, SOP devices
are capable to control load transfer and optimize network voltage profile by providing fast,
dynamic and continuous real/ reactive power flow control between feeders. Furthermore,
technical-economical-environmental benefits of proposed coordinated scheme has been
presented. Validation of proposed coordinated scheme has been carried out on well-known
69 bus distribution system.
The third part introduces a hierarchical coordinated multi objective optimization
model for the effective operation of ADN in presence of high penetrated photovoltaic based
DER. The proposed model determines the optimal network configuration that achieves
two objectives: 1) Minimizing the total operating cost and 2) Minimizing the total voltage
deviation. In this methodology, the ε−constraint method has been employed to obtain
set of non-inferior solutions and fuzzy decision-making method to determine the best
compromise solution among the set of non-inferior solutions. Besides, the significance of
battery energy storage (BES) on total operating cost and voltage deviation has also been
presented.
The fourth part introduces real-time validation of hierarchical coordinated voltage
control for active distribution network with high PV penetration. Besides, the impact of
advanced flexible power electronic devices such as PV smart inverter and soft open point
(SOP) on energy consumption and losses have been presented. The proposed methodology
has been implemented on modied 33 bus distribution system. The test results demon strate the signicant impact of the proposed integrated operation on voltage violation,
energy losses and energy consumption. Furthermore, real-time co-simulation platform for
operation and control of DER in the distribution system using MATLAB and Real Time
Digital Simulator (RTDS) have been developed and tested.
The fifth part presents a new two-layer coordinated optimization framework for plan ning and operation of DERs and soft open point (SOP) in active distribution network
(ADN). It consists of outer and inner layer optimization model, where the outer and
viiinner layer corresponding to the decision-making in the planning and operation levels
respectively. The outer-layer performs the planning of DER and SOP devices. In outer
layer, decision variables are the locations and capacities of DER and SOP to be installed.
For coordination purpose, all the candidate planning proposals will then be transferred
to the inner layer, where optimal scheduling of DER, SOP and VVC devices over a day
have been performed considering uncertainties of solar irradiance, wind speed and loads.
Meanwhile, the feasibility of outer layer decisions has also been checked in these sim ulations, where the technically infeasible solutions are recognized and discarded. After
this step, the posted scheduling of DERs, SOPs and VVC devices have been fed back
to revise previous planning scheme in the upper layer. With on-going simulations, these
procedures would finally arrive at the optimal solution. In order to solve the planning
and operation of DERs in distribution system, a co-simulation platform has been devel oped using MATLAB and General Algebraic Modeling System (GAMS) tools. Besides,
an integrated long-term planning model for DER has been presented that addresses the
economic, operational, and environmental issues of DER. Furthermore, combined impact
of DNR and VVC techniques in conjunction with smart inverter and SOPs on DERs
planning has been presented.