Dynamic Simulation of a Hybrid Wind/Diesel Isolated Power System Using Artificial Neural Network

Jarjue, Edrissa

04 July 2011

An isolated hybrid system comprised of a dispatchable and a non-dispatchable power generation sources, is proposed to supply the load of a remote village in the west coast region of The Gambia. The thesis presents an artificial neural network (ANN) based approach to tune the parameters of the frequency regulator in hybrid wind/diesel power system for isolated area power supply. The multi-layer feed-forward ANN with the error back-propagation training is employed to tune the frequency regulator in the simulation of hybrid system under different load and wind conditions. Using MATLAB/Simulink, dynamic simulations are performed to investigate the interaction between these two power sources for the load management, and the voltage and frequency behaviors during wind speed and load variations. Simulation results show that the wind turbine and the diesel generator can be operated suitably in parallel. During simulation, the frequency and voltage regulators used in the proposed hybrid system performed fairly well under wind speed variations and load changing conditions. A good frequency regulator interface, which is around 50Hz is observed for nearly the entire period of operation.

Isolated Hybrid System

Non-Dispatchable

Artificial Neural Network

Frequency and Voltage Regulators

Dynamic Simulation and Economic Analysis of an Isolated Hybrid Wind Diesel System

Selony, Wilson

24 June 2008

An isolated hybrid system comprised of a dispatchable and a non-dispatchable power generation sources, is proposed to supply the load of a remote village in the west region of Haiti. The wind speed data and load data of this remote village are used to study the system. The non-dispatchable generation comes from a nature-dependent wind turbine, and the dispatchable one is a diesel generator. Using MATLAB/Simulink, dynamic simulations are performed to investigate the interaction between these two power sources for the load management, and the voltage and frequency behaviors during wind speed and load variations. Economic analyses of the system are also conducted. The cost of energy (COE), energy payback time (PBT), internal rate of return (IRR) and avoided cost (AC) of CO2¬, NOx and PM (Particles Materials) of the hybrid system are computed, and results are compared with those of the baseline diesel only case. Simulation results show that the wind turbine and the diesel generator can be operated suitably in parallel, and the economic analyses show the positive benefits of wind generation in reducing COE and increasing the avoided cost (AC) of emitted pollutions.

hybrid system

non-dispatchable

nature-dependent

economic analysis

MATLAB/Simulink

Pricing Schemes in Electric Energy Markets

January 2016

abstract: Two thirds of the U.S. power systems are operated under market structures. A good market design should maximize social welfare and give market participants proper incentives to follow market solutions. Pricing schemes play very important roles in market design. Locational marginal pricing scheme is the core pricing scheme in energy markets. Locational marginal prices are good pricing signals for dispatch marginal costs. However, the locational marginal prices alone are not incentive compatible since energy markets are non-convex markets. Locational marginal prices capture dispatch costs but fail to capture commitment costs such as startup cost, no-load cost, and shutdown cost. As a result, uplift payments are paid to generators in markets in order to provide incentives for generators to follow market solutions. The uplift payments distort pricing signals. In this thesis, pricing schemes in electric energy markets are studied. In the first part, convex hull pricing scheme is studied and the pricing model is extended with network constraints. The subgradient algorithm is applied to solve the pricing model. In the second part, a stochastic dispatchable pricing model is proposed to better address the non-convexity and uncertainty issues in day-ahead energy markets. In the third part, an energy storage arbitrage model with the current locational marginal price scheme is studied. Numerical test cases are studied to show the arguments in this thesis. The overall market and pricing scheme design is a very complex problem. This thesis gives a thorough overview of pricing schemes in day-ahead energy markets and addressed several key issues in the markets. New pricing schemes are proposed to improve market efficiency. / Dissertation/Thesis / Masters Thesis Electrical Engineering 2016

Engineering

Operations research

Economics

Convex Hull Pricing

Dispatchable Pricing

Energy Market

Pricing Scheme

Stochastic Pricing

Integrating non-dispatchable renewable energy into the South African grid : an energy balancing view / L.K. du Plessis.

Du Plessis, Louis Kemp

January 2013

The integration of dispatchable renewable energies like biomass, geothermal and reservoir hydro technologies into an electrical network present no greater challenge than the integration of conventional power technologies for which are well understood by Eskom engineers. However, renewable energies that are based on resources that fluctuate throughout the day and from season to season, like wind and solar, introduce a number of challenges that Eskom engineers have not dealt with before. It is current practice for Eskom‟s generation to follow the load in order to balance the demand and supply. Through Eskom‟s load dispatching desk at National Control, generator outputs are adjusted on an hourly basis with balancing reserves making up only a small fraction of the total generation. Through the Integrated Resource Plan for Electricity of 2010, the Department of Energy has set some targets towards integrating renewable energy, including wind and solar generation, into the South African electricity market consequently introducing variability on the supply side. With demand that varies continually, maintaining a steady balance between supply and demand is already a challenging task. When the supply also becomes variable and less certain with the introduction of non-dispatchable renewable energy, the task becomes even more challenging. The aim of this research study is to determine whether the resources that previously helped to balance the variability in demand will still be adequate to balance variability in both demand and supply. The study will only concentrate on variable or non-dispatchable renewable energies as will be added to the South African electrical network according to the first two rounds of the Department of Energy‟s Renewable Energy Independent Power Producer Procurement Programme. This research study only looks into the balancing challenge and does not go into an analysis of voltage stability or network adequacy, both of which warrant in depth analysis. / Thesis (MIng (Development and Management Engineering))--North-West University, Potchefstroom Campus, 2013.

Dispatchable

non-dispatchable

renewable energy

demand and supply

balancing reserves

operating reserves

generator ramp rates

wind turbine generators

electricity market

REBID programme

grid code

embedded generators

Integrating non-dispatchable renewable energy into the South African grid : an energy balancing view / L.K. du Plessis.

Du Plessis, Louis Kemp

January 2013

The integration of dispatchable renewable energies like biomass, geothermal and reservoir hydro technologies into an electrical network present no greater challenge than the integration of conventional power technologies for which are well understood by Eskom engineers. However, renewable energies that are based on resources that fluctuate throughout the day and from season to season, like wind and solar, introduce a number of challenges that Eskom engineers have not dealt with before. It is current practice for Eskom‟s generation to follow the load in order to balance the demand and supply. Through Eskom‟s load dispatching desk at National Control, generator outputs are adjusted on an hourly basis with balancing reserves making up only a small fraction of the total generation. Through the Integrated Resource Plan for Electricity of 2010, the Department of Energy has set some targets towards integrating renewable energy, including wind and solar generation, into the South African electricity market consequently introducing variability on the supply side. With demand that varies continually, maintaining a steady balance between supply and demand is already a challenging task. When the supply also becomes variable and less certain with the introduction of non-dispatchable renewable energy, the task becomes even more challenging. The aim of this research study is to determine whether the resources that previously helped to balance the variability in demand will still be adequate to balance variability in both demand and supply. The study will only concentrate on variable or non-dispatchable renewable energies as will be added to the South African electrical network according to the first two rounds of the Department of Energy‟s Renewable Energy Independent Power Producer Procurement Programme. This research study only looks into the balancing challenge and does not go into an analysis of voltage stability or network adequacy, both of which warrant in depth analysis. / Thesis (MIng (Development and Management Engineering))--North-West University, Potchefstroom Campus, 2013.

Dispatchable

non-dispatchable

renewable energy

demand and supply

balancing reserves

operating reserves

generator ramp rates

wind turbine generators

electricity market

REBID programme

grid code

embedded generators

An integrated energy storage scheme for a dispatchable wind and solar powered energy system

Garrison, Jared Brett

23 August 2010

Wind and solar technologies have experienced rapid market growth recently as a result of the growing interest for implementation of renewable energy. However, the intermittency of wind and solar power is a major obstacle to their broader use. The additional risks of unexpected interruptions and mismatch with demand have hindered the expansion of these two primary renewable resources. The goal of this research is to analyze an integrated energy system that includes a novel configuration of wind and solar coupled with two storage methods to make both wind and solar sources dispatchable during peak demand, thereby enabling their broader use. Named DSWiSS for Dispatchable Solar Wind Storage System, the proposed system utilizes compressed air energy storage (CAES) that is driven from wind energy and thermal storage supplied by concentrating solar thermal power in order to achieve this desired dispatchability. Although DSWiSS mimics the operation of a typical CAES facility, the replacement of energy derived from fossil fuels with energy generated from renewable resources makes this system unique. While current CAES facilities use off peak electricity to power their compressors, this system uses power from wind turbines. Also, rather than using natural gas for heating of the compressed air before its expansion through a turbine, DSWiSS uses solar thermal energy and thermal storage. For this research, two models were created; the first is a dynamic model of a 1.5 MW variable speed wind turbine, programmed in PSCAD/EMTDC, that utilizes rotor resistive control to maintain rated power output. This model simulates the dynamic response of the wind turbine to changing wind conditions as well as the nominal performance parameters at all wind speeds. The second model is a steady state thermodynamic simulation of the turbomachinery power unit in the DSWiSS facility. By assuming conditions similar to those of a currently operating CAES facility in McIntosh, Alabama, the model calculates the performance parameters of DSWiSS and estimates the relative energy input requirements. By combining these models with a levelized lifetime cost analysis estimates of the power system performance and the cost of energy for the DSWiSS facility were estimated. The combination of these components yielded an efficiency greater than 46% for the main power block and a nearly equal utilization of both renewable resources. It was also estimated that the overall system is only slightly more expensive per unit of electricity generated than the current technologies employed today, namely coal, nuclear, and natural gas, but is comparable to a stand-alone solar thermal facility. However, this economic analysis, though accurate with regard to the technologies chosen, will not be complete until cost values can be placed on some of the externalities associated with power generation such as fuel cost volatility, national security, and emissions. / text

Renewable energy

Compressed air energy storage

Energy storage

Cost of electricity

Dispatchable power

Wind turbine

Thermal energy storage

Concentrating solar power

Wind energy

Solar energy

Comparação dos custos de geração de energia elétrica entre tecnologias despacháveis e intermitentes no Brasil

Silva, Leonardo Ribeiro Madeira da

05 May 2017

Submitted by Leonardo Madeira (leoribmad@hotmail.com) on 2017-05-24T20:49:04Z No. of bitstreams: 1 Dissertação_Leonardo_Madeira v4 - revEdson VF IMPRESSA.pdf: 497221 bytes, checksum: edd8c6618d1bbcf4135abc1f146a6980 (MD5) / Approved for entry into archive by GILSON ROCHA MIRANDA (gilson.miranda@fgv.br) on 2017-05-29T14:55:52Z (GMT) No. of bitstreams: 1 Dissertação_Leonardo_Madeira v4 - revEdson VF IMPRESSA.pdf: 497221 bytes, checksum: edd8c6618d1bbcf4135abc1f146a6980 (MD5) / Made available in DSpace on 2017-05-30T12:49:39Z (GMT). No. of bitstreams: 1 Dissertação_Leonardo_Madeira v4 - revEdson VF IMPRESSA.pdf: 497221 bytes, checksum: edd8c6618d1bbcf4135abc1f146a6980 (MD5) Previous issue date: 2017-05-05 / This study seeks to evaluate the financial differences of power generation between a huge array of technologies, splitting them in Dispatchable and Intermittent. Tacitly accepted all over the world as a financial tool to compare any kind of technology, the Levelized Cost of Energy, LCOE, might originate inappropriate conclusions assumptions once it considers the life cycle of some power generation source with a homogeneous generation profile. Containing a huge framework of data source and a simple metric, the study puts the Joskow (2011) study into Brazil electric sector context. / Este trabalho busca avaliar as diferenças financeiras de geração de energia entre uma grande gama de tecnologias, separando-as em Despacháveis e Intermitentes. Aceito na grande maioria dos países como instrumento de comparação financeira entre fontes de geração, o Custo Nivelado de Energia (LCOE) também é amplamente utilizado no Brasil. Com base em Joskow (2011) e em dados para empreendimentos brasileiros, mostra-se que esta métrica, o LCOE, pode gerar conclusões equivocadas devido ao fato de considerar, em um ciclo de vida dos projetos, um perfil de geração homogêneo, o que não é compatível com as características de despachabilidade das diversas fontes.

Levelized Cost of Energy

Energy

Power generation

Dispatchable resources

Custo nivelado de energia

Setor elétrico

Geração de Energia

Despachabilidade

Ciências sociais

Sistemas de energia elétrica

Generic design and investigation of solar cooling systems

Saulich, Sven

January 2013

This thesis presents work on a holistic approach for improving the overall design of solar cooling systems driven by solar thermal collectors. Newly developed methods for thermodynamic optimization of hydraulics and control were used to redesign an existing pilot plant. Measurements taken from the newly developed system show an 81% increase of the Solar Cooling Efficiency (SCEth) factor compared to the original pilot system. In addition to the improvements in system design, new efficiency factors for benchmarking solar cooling systems are presented. The Solar Supply Efficiency (SSEth) factor provides a means of quantifying the quality of solar thermal charging systems relative to the usable heat to drive the sorption process. The product of the SSEth with the already established COPth of the chiller, leads to the SCEth factor which, for the first time, provides a clear and concise benchmarking method for the overall design of solar cooling systems. Furthermore, the definition of a coefficient of performance, including irreversibilities from energy conversion (COPcon), enables a direct comparison of compression and sorption chiller technology. This new performance metric is applicable to all low-temperature heat-supply machines for direct comparison of different types or technologies. The achieved findings of this work led to an optimized generic design for solar cooling systems, which was successfully transferred to the market.

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