1,935 research outputs found
Reducing Voltage Volatility with Step Voltage Regulators: A Life-Cycle Cost Analysis of Korean Solar Photovoltaic Distributed Generation
To meet the United Nation’s sustainable development energy goal, the Korean Ministry of Commerce announced they would increase renewable energy generation to 5.3% by 2029. These energy sources are often produced in small-scale power plants located close to the end users, known as distributed generation (DG). The use of DG is an excellent way to reduce greenhouse gases but has also been found to reduce power quality and safety reliability through an increase in voltage volatility. This paper performs a life-cycle cost analysis on the use of step voltage regulators (SVR) to reduce said volatility, simulating the impact they have on existing Korean solar photovoltaic (PV) DG. From the data collected on a Korean Electrical Power Corporation 30 km/8.2 megawatts (MW) feeder system, SVRs were found to increase earnings by one million USD. SVR volatile voltage mitigation increased expected earnings by increasing the estimated allowable PV power generation by 2.7 MW. While this study is based on Korean PV power generation, its findings are applicable to any DG sources worldwide.11Nsciescopu
Optimized Solar Photovoltaic Generation in a Real Local Distribution Network
Remarkable penetration of renewable energy in electric networks, despite its
valuable opportunities, such as power loss reduction and loadability
improvements, has raised concerns for system operators. Such huge penetration
can lead to a violation of the grid requirements, such as voltage and current
limits and reverse power flow. Optimal placement and sizing of Distributed
Generation (DG) are one of the best ways to strengthen the efficiency of the
power systems. This paper builds a simulation model for the local distribution
network based on obtained load profiles, GIS information, solar insolation,
feeder and voltage settings, and define the optimization problem of solar PVDG
installation to determine the optimal siting and sizing for different
penetration levels with different objective functions. The objective functions
include voltage profile improvement and energy loss minimization and the
considered constraints include the physical distribution network constraints
(AC power flow), the PV capacity constraint, and the voltage and reverse power
flow constraints.Comment: To be published (Accepted) in: Proceedings of the IEEE PES Innovative
Smart Grid Technologies Conference (ISGT), Washington D.C., USA, 201
Financial Analysis of a Grid-connected Photovoltaic System in South Florida
In this paper the performance and financial analysis of a grid-connected
photovoltaic system installed at Florida Atlantic University (FAU) is
evaluated. The power plant has the capacity of 14.8 kW and has been under
operation since August 2014. This solar PV system is composed of two 7.4 kW
sub-arrays, one fixed and one with single axis tracking. First, an overview of
the system followed by local weather characteristics in Boca Raton, Florida is
presented. In addition, monthly averaged daily solar radiation in Boca Raton as
well as system AC are calculated utilizing the PVwatts simulation calculator.
Inputs such as module and inverter specifications are applied to the System
Advisor Model (SAM) to design and optimize the system. Finally, the estimated
local load demand as well as simulation results are extracted and analyzed.Comment: 6 Pages, IEEE PVSC 2017 Conference, Washington D.
Estimating national and local low-voltage grid capacity for residential solar photovoltaic in Sweden, UK and Germany
The electric grid\u27s available capacity to accommodate solar photovoltaic on national scales is currently uncertain. This makes decisions about grid capacity expansion, which can be very costly for local grid operators, difficult to make. Yet, knowledge of national solar photovoltaic grid capacity is central in order to formulate realistic solar PV targets and strategies. We present a methodology based on publicly available data to estimate the grid\u27s hosting capacity of residential solar photovoltaic at both the national and local scale. The model is applied to Sweden, Germany and the UK and shows that low-voltage grid capacity for residential solar photovoltaic is very large, 33 (+5/-7) GW (Sweden), 248 (+5/-24) GW (Germany) and 63 (+1/-14) GW UK, and similar to current total generation capacity. Based on our estimations, we find that with the capacity of the present grid Sweden can supply 24%, Germany 60% and UK 21% of their current annual net electricity consumption from residential solar photovoltaic. In addition, we find that the grid-supported individual solar PV system sizes increase as population density decreases. Finally, our work highlights the importance of implementing sizing incentives for customers when installing their solar PV systems
An assessment of high distributed PV generation on eThekwini electricity distribution network.
Masters Degree. University of KwaZulu-Natal, Durban.Small-scale Distributed Photovoltaic Generation (DPVG) continues to grow with increasing operational
challenges for electricity utilities and Distribution Network (DN) operators. In Low Voltage (LV) DNs,
there are well researched potential issues that arise with high Photovoltaic (PV) penetration. These include:
feeder voltage rise, voltage fluctuations and reverse power flow. Among these, the most important issue is
voltage rise at the LV distribution feeder. In a broader perspective, to this point in time, there has not been
more detailed research on small-scale DPVG interconnections in the LV networks in South Africa (SA) and
in the KwaZulu-Natal (KZN) region. There is a great need for research in this field for ensuring network
efficiency, reliability and future regulatory standards. Other network systems have been studied around the
world were conditions, environment, network characteristics and electricity customer loads will be different;
e.g in the North-West of England, Germany, and Queensland, Australia. Hence, the main objective of this
research study is to analyze the mentioned problems, identify and test the appropriate mitigation solutions,
in the event of high DPVG. This study was carried out on a typical SAn LV DN model, which represents
an existing housing development estate at eThekwini Municipality. Consequently the aim is to identify
solutions suitable for networks in SAn or of similar architect and characteristics. As a result, a specific
application is undertaken at the KZN region, which is also representative of network characteristics of SAn
networks. A voltage rise, voltage fluctuation and network power loss issues were analyzed at different PV
penetration levels and varying customer loads. An innovative approach of utilization of a standard central
On-Load-Tap-Change (Off-LTC) transformer for voltage regulation with high DPVG was tested. Usage
of this technique has not been reported in the literature to date. National standards in SA were used as
a basic guide in this study and stated the possibility of grid voltage control of distributed PV inverters.
Assessment of the typical LV network showed that there is indeed voltage rise and hence possible voltage
fluctuation, when PV system output power varies. The Off-LTC transformer was able to maintain network
voltages within the allowed operational range and reduced the magnitude of voltage rise. This implies that
there is a possibility of avoiding expensive upgrades of the existing and widespread Off-LTC transformers
technology
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A review of microgrid development in the United States – A decade of progress on policies, demonstrations, controls, and software tools
Microgrids have become increasingly popular in the United States. Supported by favorable federal and local policies, microgrid projects can provide greater energy stability and resilience within a project site or community. This paper reviews major federal, state, and utility-level policies driving microgrid development in the United States. Representative U.S. demonstration projects are selected and their technical characteristics and non-technical features are introduced. The paper discusses trends in the technology development of microgrid systems as well as microgrid control methods and interactions within the electricity market. Software tools for microgrid design, planning, and performance analysis are illustrated with each tool's core capability. Finally, the paper summarizes the successes and lessons learned during the recent expansion of the U.S. microgrid industry that may serve as a reference for other countries developing their own microgrid industries
Application of stochastic and evolutionary methods to plan for the installation of energy storage in voltage constrained LV networks
Energy storage is widely considered to be an important component of a decarbonised power system if large amounts of renewable generation are to provide reliable electricity. However, storage is a highly capital intensive asset and clear business cases are needed before storage can be widely deployed. A proposed business case is using storage to prevent overvoltage in low voltage (LV) distribution networks to enable residential photovoltaic systems.
Despite storage being widely considered for use in LV networks, there is little work comparing where storage might be installed in LV networks from the perspective of the owners of distribution networks (DNOs). This work addresses this in two ways. Firstly, a tool is developed to examine whether DNOs should support a free market for energy storage in which customers with PV purchase storage (e.g. battery systems) to improve their self-consumption. This reflects a recent policy in Germany. Secondly, a new (published) method is developed which considers how DNOs should purchase and locate storage to prevent overvoltage. Both tools use a snapshot approach by modelling the highest and lowest LV voltages.
On their own, these tools enable a DNO to determine the cost of energy storage for a particular LV network with a particular set of loads and with PV installed by a given set of customers. However, in order to predict and understand the future viability of energy storage it is valuable to apply the tools to a large number of LV networks under realistic future scenarios for growth of photovoltaics in the UK power system. Therefore, the work extracts over 9,000 LV network models containing over 40,000 LV feeders from a GIS map of cables provided by one of the UK’s electricity distribution networks- Electricity North West.
Applying the proposed tools to these 9,000 network models, the work is able to provide projections for how much LV energy storage would be installed under different scenarios. The cost of doing so is compared to the existing method of preventing reinforcement- LV network reconductoring. This is a novel way of assessing the viability of LV energy storage against traditional approaches and allows the work to draw the following conclusions about the market for energy storage in LV distribution networks in the UK:
- Overvoltage as a result of PV could begin to occur in the next few years unless UK regulations for voltage levels are relaxed. There could be a large cost (hundreds of millions of pounds) to prevent this if the traditional approach of reconductoring is used.
- If overvoltage begins to occur, a free market for energy storage (randomly purchased by electricity consumers) cannot offer large benefits to DNOs in reducing the reinforcement cost unless this is properly controlled, located and/or widely installed by customers.
- Optimally located storage by the DNO can reduce overall reinforcement costs to mitigate overvoltage. This would enable more energy storage to balance renewable generation and present large savings to the power system. The exact topology of storage and the storage rating in each LV network could be determined using the tool proposed in this work
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