1,541 research outputs found
Designing Electricity Distribution Networks: The Impact of Demand Coincidence
With the global effort to reduce carbon emissions, clean technologies such as
electric vehicles and heat pumps are increasingly introduced into electricity
distribution networks. These technologies considerably increase electricity
flows and can lead to more coincident electricity demand. In this paper, we
analyze how such increases in demand coincidence impact future distribution
network investments. For this purpose, we develop a novel model for designing
electricity distribution networks, called the distribution network
reconfiguration problem with line-specific demand coincidence (DNRP-LSDC). Our
analysis is two-fold: (1) We apply our model to a large sample of real-world
networks from a Swiss distribution network operator. We find that a high demand
coincidence due to, for example, a large-scale uptake of electric vehicles,
requires a substantial amount of new network line construction and increases
average network cost by 84 % in comparison to the status quo. (2) We use a set
of synthetic networks to isolate the effect of specific network
characteristics. Here, we show that high coincidence has a more detrimental
effect on large networks and on networks with low geographic consumer
densities, as present in, e. g., rural areas. We also show that expansion
measures are robust to variations in the cost parameters. Our results
demonstrate the necessity of designing policies and operational protocols that
reduce demand coincidence. Moreover, our findings show that operators of
distribution networks must consider the demand coincidence of new electricity
uses and adapt investment budgets accordingly. Here, our solution algorithms
for the DNRP-LSDC problem can support operators of distribution networks in
strategic and operational network design tasks.Comment: Accepted manuscript, to appear in European Journal of Operational
Research (EJOR
Power System Simulation, Control and Optimization
This Special Issue “Power System Simulation, Control and Optimization” offers valuable insights into the most recent research developments in these topics. The analysis, operation, and control of power systems are increasingly complex tasks that require advanced simulation models to analyze and control the effects of transformations concerning electricity grids today: Massive integration of renewable energies, progressive implementation of electric vehicles, development of intelligent networks, and progressive evolution of the applications of artificial intelligence
A Review of Methodological Approaches for the Design and Optimization of Wind Farms
This article presents a review of the state of the art of the Wind Farm Design and Optimization (WFDO) problem. The WFDO problem refers to a set of advanced planning actions needed to extremize the performance of wind farms, which may be composed of a few individual Wind Turbines (WTs) up to thousands of WTs. The WFDO problem has been investigated in different scenarios, with substantial differences in main objectives, modelling assumptions, constraints, and numerical solution methods. The aim of this paper is: (1) to present an exhaustive survey of the literature covering the full span of the subject, an analysis of the state-of-the-art models describing the performance of wind farms as well as its extensions, and the numerical approaches used to solve the problem; (2) to provide an overview of the available knowledge and recent progress in the application of such strategies to real onshore and offshore wind farms; and (3) to propose a comprehensive agenda for future research
Advances in Energy System Optimization
The papers presented in this open access book address diverse challenges in decarbonizing energy systems, ranging from operational to investment planning problems, from market economics to technical and environmental considerations, from distribution grids to transmission grids, and from theoretical considerations to data provision concerns and applied case studies. While most papers have a clear methodological focus, they address policy-relevant questions at the same time. The target audience therefore includes academics and experts in industry as well as policy makers, who are interested in state-of-the-art quantitative modelling of policy relevant problems in energy systems. The 2nd International Symposium on Energy System Optimization (ISESO 2018) was held at the Karlsruhe Institute of Technology (KIT) under the symposium theme “Bridging the Gap Between Mathematical Modelling and Policy Support” on October 10th and 11th 2018. ISESO 2018 was organized by the KIT, the Heidelberg Institute for Theoretical Studies (HITS), the Heidelberg University, the German Aerospace Center and the University of Stuttgart
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Smart Energy Management of Multiple Full Cell Powered Applications
In this research project the University of South Alabama research team has been investigating smart energy management and control of multiple fuel cell power sources when subjected to varying demands of electrical and thermal loads together with demands of hydrogen production. This research has focused on finding the optimal schedule of the multiple fuel cell power plants in terms of electric, thermal and hydrogen energy. The optimal schedule is expected to yield the lowest operating cost. Our team is also investigating the possibility of generating hydrogen using photoelectrochemical (PEC) solar cells through finding materials for efficient light harvesting photoanodes. The goal is to develop an efficient and cost effective PEC solar cell system for direct electrolysis of water. In addition, models for hydrogen production, purification, and storage will be developed. The results obtained and the data collected will be then used to develop a smart energy management algorithm whose function is to maximize energy conservation within a managed set of appliances, thereby lowering O/M costs of the Fuel Cell power plant (FCPP), and allowing more hydrogen generation opportunities. The Smart Energy Management and Control (SEMaC) software, developed earlier, controls electrical loads in an individual home to achieve load management objectives such that the total power consumption of a typical residential home remains below the available power generated from a fuel cell. In this project, the research team will leverage the SEMaC algorithm developed earlier to create a neighborhood level control system
The Power of Scheduling: the Scheduling of Power
Because of the ongoing energy transition, an increasing share of our energy needs is met by electrical energy. At the same time, more and more of this electricity is generated by renewable sources that strongly depend on the weather for their output. This is already causing issues on the Dutch electrical grid. Not only is it increasingly difficult to balance supply and demand, but facilitating the transport of the electrical energy is a growing challenge as well. In this work, we apply scheduling techniques to problems in this context. Primarily, we look at planning/shifting controllable demand to better align the demand with energy production, or to use the limited capacity of the grid more efficiently. We propose scheduling approaches to find good time plans for these situations. These approaches could be applied, for example, to coordinate demand in places where transport capacity is limited, or to better align peaks in supply and demand. We argue the benefits of using scheduling techniques to solve this type of problem. At its core, this work consists of two parts with two chapters each. The first part presents a general class of problems and introduces a framework that can be used to find good solutions. In the second part, two specific examples of electricity scheduling problems are considered: planning demand and supply in a microgrid and e-vehicle charging, and solution methods for these problems are developed
Application of a mobile robot to spatial mapping of radioactive substances in indoor environment
Nuclear medicine requires the use of radioactive substances that can contaminate critical
areas (dangerous or hazardous) where the presence of a human must be reduced or avoided.
The present work uses a mobile robot in real environment and 3D simulation to develop
a method to realize spatial mapping of radioactive substances. The robot should visit all
the waypoints arranged in a grid of connectivity that represents the environment. The
work presents the methodology to perform the path planning, control and estimation
of the robot location. For path planning two methods are approached, one a heuristic
method based on observation of problem and another one was carried out an adaptation
in the operations of the genetic algorithm. The control of the actuators was based on two
methodologies, being the first to follow points and the second to follow trajectories. To
locate the real mobile robot, the extended Kalman filter was used to fuse an ultra-wide
band sensor with odometry, thus estimating the position and orientation of the mobile
agent. The validation of the obtained results occurred using a low cost system with a
laser range finder.A medicina nuclear requer o uso de substâncias radioativas que pode vir a contaminar
áreas críticas, onde a presença de um ser humano deve ser reduzida ou evitada. O presente
trabalho utiliza um robô móvel em ambiente real e em simulação 3D para desenvolver um
método para o mapeamento espacial de substâncias radioativas. O robô deve visitar todos
os waypoinst dispostos em uma grelha de conectividade que representa o ambiente. O trabalho
apresenta a metodologia para realizar o planejamento de rota, controle e estimação
da localização do robô. Para o planejamento de rota são abordados dois métodos, um
baseado na heurística ao observar o problema e ou outro foi realizado uma adaptação nas
operações do algoritmo genético. O controle dos atuadores foi baseado em duas metodologias,
sendo a primeira para seguir de pontos e a segunda seguir trajetórias. Para localizar
o robô móvel real foi utilizado o filtro de Kalman extendido para a fusão entre um sensor
ultra-wide band e odometria, estimando assim a posição e orientação do agente móvel. A
validação dos resultados obtidos ocorreu utilizando um sistema de baixo custo com um
laser range finder
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