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Energy Optimizations for Smart Buildings and Smart Grids
Modern buildings are heavy power consumers. For instance, of the total electricity consumed in the US, 75% is consumed in the residential and commercial buildings. This consumption is not evenly distributed over time. Typical consumption profile exhibits several peaks and troughs. The peakiness, in turn, dictates the electric grid\u27s generation, transmission and distribution costs, and also the associated carbon emissions.
This thesis discusses challenges involved in achieving the sustainability goals in buildings and electric grids. It investigates building and grid energy footprint optimization techniques to achieve the following goals: 1) making buildings energy efficient, 2) cutting building\u27s electricity bills, 3) cutting utility\u27s costs in electricity generation and distribution, 4) reducing carbon footprints, and 5) making the aggregate electricity consumption profile grid-friendly.
In this thesis, we first design SmartCap, a system to enable homes flatten their consumption/demand by scheduling background loads (such as A/Cs, refrigerator), without causing user discomfort and without direct user involvement. Demand flattening facilitates aggregate peak reduction, which in turn enables grids to 1) reduce carbon emissions, and 2) cut installation and operational costs. Our results demonstrate that SmartCap can decrease the average deviation from mean power by over 20% across all periods with high deviation, thereby flattening the peaky demand. Next, we present SmartCharge, an intelligent battery charging system that shifts a building\u27s electricity consumption to off-peak periods by storing low-cost energy for use during high-cost periods, without active user involvement. We show that SmartCharge can typically save 10-15% in bills and can reduce the grid-wide peak demand by up to 20%. We then extend SmartCharge to GreenCharge, which integrates on-site renewables in a building\u27s electricity consumption. Our experiments show that GreenCharge can cut user electricity bills up to 20%. After GreenCharge, we investigate the use of large-scale distributed energy storage at buildings throughout the grid to flatten grid demand, while 1) maintaining end-user incentives for storage adoption at grid-scale, and 2) ensuring grid stability. We design PeakCharge, an online peak-aware charging algorithm to optimize the use of energy storage in the presence of a peak demand surcharge. Empirical evaluations show that total storage capacity required by PeakCharge to flatten grid demand is within 18% of the capacity required by a centralized system. Finally, we examine the efficacy of employing different combinations of energy storage technologies at different levels of the grid’s distribution hierarchy to cut electric utility\u27s daily operational costs. We present an optimization framework for modeling the primary characteristics of various energy storage technologies and important tradeoffs in placing different storage technologies at different levels of the distribution hierarchy. We show that by employing hybrid storage technologies at multiple levels of the distribution hierarchy, utilities can reduce their daily operating costs due to distributing electricity by up to 12%
Optimization-Based Home Energy Management System Under Different Electricity Pricing Schemes
This paper presents an optimization-based home energy management system, by taking advantages of renewable resources and energy storage system for optimally managing the energy consumption and generation of the house. The surplus of renewable generation will be stored in energy storage system or will be injected into the main grid. An optimization algorithm is developed for this system in order to minimize the electricity bill of the house considering electricity tariffs. Four home appliances are considered to be controlled by this system for reducing the consumption in critical periods. The outcomes of optimization problem are the optimal scheduling of the resources including renewable generation, energy storage system, consumption reduction, and power transactions with the grid. In the case study, the developed model will be employed in three different scenarios, which considers simple electricity prices and time-of- use tariffs in order to test and validate the performance of the developed model.The present work was done and funded in the scope of the following projects: H2020 DREAM-GO Project (Marie Sklodowska-Curie grant agreement No 641794); Project GREEDI (ANI|P2020 17822); and UID/EEA/00760/2013 funded by FEDER Funds through COMPETE program and by National Funds through FCT.info:eu-repo/semantics/publishedVersio
Contingency Management in Power Systems and Demand Response Market for Ancillary Services in Smart Grids with High Renewable Energy Penetration.
Ph.D. Thesis. University of Hawaiʻi at Mānoa 2017
Future Smart Grid Systems
This book focuses on the analysis, design and implementation of future smart grid systems. This book contains eleven chapters, which were originally published after rigorous peer-review as a Special Issue in the International Journal of Energies (Basel). The chapters cover a range of work from authors across the globe and present both the state-of-the-art and emerging paradigms across a range of topics including sustainability planning, regulations and policy, estimation and situational awareness, energy forecasting, control and optimization and decentralisation. This book will be of interest to researchers, practitioners and scholars working in areas related to future smart grid systems
A Generalized hierarchical transactive energy management framework for residential microgrids
This work develops a transactive energy management system in order to automate the operation and efficiently utilize the energy generated from the solar PV unit and BESS in a single house as well as in the microgrid and provides cost-benefit analysis
Optimization of Household Energy Management Based on the Simplex Algorithm
Small scale intermittent renewable energy consisting of roof-mounted photovoltaic generators and micro wind turbines for the household residential have been widely integrated into the power grid. Meanwhile, more and more home appliances are utilized, including schedulable and non-schedulable home appliances. With the deployment of smart technologies, the control strategies of home energy management system are developed and this provides the possibility to minimize the energy bill and improve the energy efficiency by scheduling the controllable home appliances without sacrificing preference of the customer.
In this thesis, an optimization strategy based on the Simplex algorithm has been proposed. The target is to optimize the energy consumption in households by scheduling the household appliances, considering the day-ahead electricity price from Nord Pool market and the roof-mounted PV production. Firstly, the schedules are generated from the optimization algorithm and then interpreted to control the appliances to achieve energy bill saving.
In order to evaluate the optimization algorithm, the water boiler is used as the controllable load. Two case studies for 24-hour illustrate that the implementation controlled by HEMS using this algorithm can contribute greatly to the energy bill savings. According to the two implementations, around 43% of reduction for the energy bill can be achieved. Considering the PV production integrated into HEMS and support from the distribution network operators, the more benefits can be achieved.
The switch panel in the AC Microgrid laboratory acts a crucial part in the implementations and it has seven 3-phase channels that can be utilized to connect with electrical appliances, home energy storage systems, and distributed generations such as micro wind turbines and roof-mounted PV panels. Each channel is equipped with two connectors to control the operation, the top of which is controlled by HEMS computer using wireless Z-Wave and the other one is controlled by dSpace which can be used to emulate the consumption pattern in the households. The algorithm and Z-wave interface are implemented in Matlab / Simulink environment and Z-wave makes it possible to control the boiler or other loads in real-time
Optimal Online Charging Coordination of Plug in Electric Vehicles in Unbalanced Grids for Ancillary Voltage Support
This PhD thesis will propose an optimal online charge control through genetic algorithm for G2V coordination of PEVs (OL-C-TP) in unbalanced systems. Moreover the algorithm will be extended to also include V2G coordination and offer ancillary voltage support (OL-CD-TPQ) by considering two different methods based on the utility time-of-day prices for exporting reactive power and droop controller for decentralized exporting of reactive power. Then the performance of OL-CD-TPQ by switching PEVs in three phase unbalanced networks is improved
Decision support for participation in electricity markets considering the transaction of services and electricity at the local level
[EN] The growing concerns regarding the lack of fossil fuels, their costs, and their
impact on the environment have led governmental institutions to launch energy
policies that promote the increasing installation of technologies that use
renewable energy sources to generate energy. The increasing penetration of
renewable energy sources brings a great fluctuation on the generation side,
which strongly affects the power and energy system management. The control of
this system is moving from hierarchical and central to a smart and distributed
approach. The system operators are nowadays starting to consider the final end users (consumers and prosumers) as a part of the solution in power system
operation activities. In this sense, the end-users are changing their behavior from
passive to active players. The role of aggregators is essential in order to empower
the end-users, also contributing to those behavior changes. Although in several
countries aggregators are legally recognized as an entity of the power and energy
system, its role being mainly centered on representing end-users in wholesale
market participation.
This work contributes to the advancement of the state-of-the-art with
models that enable the active involvement of the end-users in electricity markets
in order to become key participants in the management of power and energy
systems. Aggregators are expected to play an essential role in these models,
making the connection between the residential end-users, electricity markets,
and network operators. Thus, this work focuses on providing solutions to a wide
variety of challenges faced by aggregators.
The main results of this work include the developed models to enable
consumers and prosumers participation in electricity markets and power and
energy systems management. The proposed decision support models consider
demand-side management applications, local electricity market models,
electricity portfolio management, and local ancillary services.
The proposed models are validated through case studies based on real data.
The used scenarios allow a comprehensive validation of the models from
different perspectives, namely end-users, aggregators, and network operators.
The considered case studies were carefully selected to demonstrate the characteristics of each model, and to demonstrate how each of them contributes
to answering the research questions defined to this work.[ES] La creciente preocupación por la escasez de combustibles fósiles, sus costos
y su impacto en el medio ambiente ha llevado a las instituciones
gubernamentales a lanzar políticas energéticas que promuevan la creciente
instalación de tecnologías que utilizan fuentes de energía renovables para
generar energía. La creciente penetración de las fuentes de energía renovable trae
consigo una gran fluctuación en el lado de la generación, lo que afecta
fuertemente la gestión del sistema de potencia y energía. El control de este
sistema está pasando de un enfoque jerárquico y central a un enfoque inteligente
y distribuido. Actualmente, los operadores del sistema están comenzando a
considerar a los usuarios finales (consumidores y prosumidores) como parte de
la solución en las actividades de operación del sistema eléctrico. En este sentido,
los usuarios finales están cambiando su comportamiento de jugadores pasivos a
jugadores activos. El papel de los agregadores es esencial para empoderar a los
usuarios finales, contribuyendo también a esos cambios de comportamiento.
Aunque en varios países los agregadores están legalmente reconocidos como una
entidad del sistema eléctrico y energético, su papel se centra principalmente en
representar a los usuarios finales en la participación del mercado mayorista.
Este trabajo contribuye al avance del estado del arte con modelos que
permiten la participación activa de los usuarios finales en los mercados eléctricos
para convertirse en participantes clave en la gestión de los sistemas de potencia
y energía. Se espera que los agregadores desempeñen un papel esencial en estos
modelos, haciendo la conexión entre los usuarios finales residenciales, los
mercados de electricidad y los operadores de red. Por lo tanto, este trabajo se
enfoca en brindar soluciones a una amplia variedad de desafíos que enfrentan los
agregadores.
Los principales resultados de este trabajo incluyen los modelos
desarrollados para permitir la participación de los consumidores y prosumidores
en los mercados eléctricos y la gestión de los sistemas de potencia y energía. Los
modelos de soporte de decisiones propuestos consideran aplicaciones de gestión
del lado de la demanda, modelos de mercado eléctrico local, gestión de cartera
de electricidad y servicios auxiliares locales.
Los modelos propuestos son validan mediante estudios de casos basados en
datos reales. Los escenarios utilizados permiten una validación integral de los
modelos desde diferentes perspectivas, a saber, usuarios finales, agregadores y
operadores de red. Los casos de estudio considerados fueron cuidadosamente
seleccionados para demostrar las características de cada modelo y demostrar
cómo cada uno de ellos contribuye a responder las preguntas de investigación
definidas para este trabajo
Understanding potential users of energy community information system:a thematic analysis
Abstract. The continuing global growth of energy consumers, the war in Europe, and climate change are the driving factors for energy revolution. One solution to this concerning issue has been the transformation of energy consumers to become energy producers. Prosumers can be grouped to establish energy communities. Prosumers, energy communities, and other distributed energy resources (DERs) are possible sustainable energy resources that can be connected to the smart grid.
The literature review of existing research about smart grids, distributed energy resources, and energy communities, is conducted to gain a better understanding of the complex system and its stakeholders. The Second part of the literature review follows the behaviour of the potential smart grid users and its recent studies.
The research questions focus on understanding energy prosumer’s perspectives on information system usage in order to discover the advantages and disadvantages of potential information system within an energy community context.
The data were gathered from semi-structured interviews with people who voluntarily replied to application forms which were distributed prior to this study. Qualitative research methods were chosen to be used. A thematic analysis was conducted and as a result a thematic map in which two main themes, 15 sub-themes, and 25 codes were identified.
It was discovered that positive user experience, desired functionalities, monitoring, economic benefits, user interface, beneficial information, and platform availability were the driving factors seen as an advantage of the potential information system. On the other hand, data leaks, undesired functionalities, energy community problems, and negative user experience were seen as disadvantages of the information system.
This study contributes to the field of sustainable human-computer interaction and the findings of this thesis can be used as a foundation for future research and to design and develop the smart grids from the prosumer’s perspective. Due to several requests from participants, the text of the thesis has been written with accessibility in mind, so that the text does not require special expertise in the field of sustainable human-computer interaction
Smart Energy Management for Smart Grids
This book is a contribution from the authors, to share solutions for a better and sustainable power grid. Renewable energy, smart grid security and smart energy management are the main topics discussed in this book
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