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Electric Water Heater Modeling for Distributed Energy Resource Aggregation and ControlClarke, Anne E. 13 June 2018 (has links)
Today's utilities face new challenges due to the continually increasing penetration of residential solar and other distributed, stochastic generation sources. In order to maintain balance and stability in the grid without building costly, large-scale generation plants, utilities are turning to distributed energy resources for use in demand response programs. Demand response is a cost-efficient way to balance grid load/generation without the need for increased capital investment in traditional generation resources. Demand response programs are excellent exploiters of end-user devices that otherwise further accentuate the daily load curve and thus, add to the difficulties created by daily load peaks.
Electric water heaters are excellent candidates for use in demand response programs for a variety of reason. One, electric water heaters represent a large portion of daily household loads due to their high nominal power ratings (1.5 kW - 5.5kW), and frequent use estimated to account for approximately one third of all daily residential power demand. Two, they are composed of strictly resistive elements, which greatly simplifies modeling, aggregation and control. And third, they can be used for load "shedding" during periods of high electrical demand as well as load "absorbing" during periods of excess generation due to their thermal storage capabilities.
With improved access and control, electric water heaters could become a major distributed energy resource for utilities. In order to properly control and use a distributed energy resource, it is important to know how these resources operate and their patterns of behavior in different environments. This thesis presents a single-element, single mass electric water heater model for analyzing the effectiveness of using electric water heaters as distributed energy resources and for participation in demand response programs. The CTA-2045 communication protocol was used for testing demand response signals. The electric water heater is modeled in Python and the communication pathway was built in C++ and Python.
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Aspects of autonomous demand response through frequency based control of domestic water heatersCooper, Douglas John January 2018 (has links)
A dissertation submitted to the Faculty of Engineering and the Built Environment, University of the Witwatersrand, Johannesburg, in fulfilment of the requirements
for the degree of Master of Science in Engineering
in the School of Electrical and Information Engineering, July 2017 / This dissertation presents the design and testing of controllers intended to provide au-
tonomous demand response, through the use of water heater loads and grid frequency
measurements. The controllers use measured frequency as an indication of the strain on
a utility grid, which allows demand side management to be isolated from any form of
central control. Water heaters can operate as
exible loads because their power consump-
tion can be dispatched or deferred without directly impacting users. These properties
make it possible to control individual water heaters based on the functioning of the grid,
rather than end user input. The purpose of this research is to ultimately provide a low-
cost alternative to a traditional Smart Grid, that will improve the resilience of a grid
without negatively impacting users. The controllers presented here focus on ensuring
that users receive hot water, while attempting to reduce any imbalance between power
generated and power consumed on the grid. Simulations of these controllers in various
situations highlight that while the controllers developed respond suitably to variations
in the grid frequency and adequately ensure end users receive hot water, the practical
bene t of the controllers depends largely on the intrinsic characteristics of the grid. / CK2018
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Aggregation of Electric Water Heaters for Peak Shifting and Frequency Response ServicesClarke, Thomas Leighton 07 June 2019 (has links)
The increased penetration of renewable energy sources poses new challenges for grid stability. The stochastic and uncontrollable generation of solar and wind power cannot be adjusted to match the load profile, and the transition away from traditional synchronous generators is reducing the grid capacity to arrest and recover from frequency disturbances.
Additionally, the distributed nature of many renewable energy sources makes centralized control of generation more complicated. The traditional power system paradigm balances the supply and demand of electricity on the grid by regulating generation. As this becomes more difficult, one alternative is to adjust the load instead. This is not entirely novel, and utilities have incentivized large industrial customers to reduce consumption during peak hours for years. However, the residential sector, which constitutes 37% of electricity consumption in the U.S., currently has very little capacity for load control.
Smart electric water heaters provide utilities with an appliance that can be remotely controlled and serves as a form of energy storage. They have very fast response times and make up a large amount of residential energy consumption, making them useful for load peak shifting as well as other ancillary grid services. As smart appliances become increasingly widespread, more and more devices can be brought into the utility's control network and aggregated into a flexible resource on a megawatt scale.
This work demonstrates the usefulness of aggregated electric water heaters for peak shifting and frequency response. Because a large number of assets are required, emulators are developed based on observations of real devices. Emulated water heaters are then connected to an energy resource aggregator using an internet-of-things network. The aggregator successfully uses these assets to shift consumption away from peak hours. An algorithm was developed for detecting upward frequency disturbances in real-time. The aggregator uses this algorithm to show that an aggregation of water heaters is well-suited to respond to these frequency disturbances by quickly adding a large amount of load to the grid.
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Contribution au pilotage de la charge pour accroître la flexibilité du système électrique.Saker, Nathalie 30 January 2013 (has links) (PDF)
Les défis environnementaux et l'augmentation de la population viennent en preuve de l'importance de réfléchir à d'autres moyens de production tout en maintenant la sécurité et la fiabilité du système électrique. La sûreté du système électrique exige à tout moment que la production soit égale à la demande des consommateurs, pour ça, différentes solutions sont déjà mises en place, ces solutions consistent à mettre en marche des moyens de pointes couteux et polluants pendant les périodes de pointes, mais comme les moyens de production son insuffisants et vue la difficulté d'exploitation de nouveaux moyens de production, une nouvelle réflexion sur la gestion de la demande est apparue; celle-ci se base sur la possibilité à gérer la demande du consommateur final au lieu de la satisfaire.L'objectif de la thèse est d'étudier la possibilité à rendre des services au système électrique en appliquant des actions de contrôle dites de DR (Demand Response), sur différents types de charges électriques. Ces actions de DR représentent des interruptions partielles appliquées sur les charges électriques de type thermique. Notre choix s'est basé sur ces types de charges parce que celles-ci emmagasinent de la chaleur respectivement dans l'air et dans l'eau; qui peut être restituée pendant la période de contrôle ou d'interruption. Néanmoins, il existe un effet négatif qui suit le contrôle de ces charges car l'énergie effacée de ces charges est reportée à l'instant de reconnexion de celles-ci; ce report prend la forme d'un pic de consommation nommé CLPU (Cold Load Pick-Up) et qui apparait au moment de la reconnexion. Le CLPU représente un problème qui doit être géré, et sa magnitude dépend des types d'actions de contrôle qu'on veut implanter et aussi des conditions du système électrique (contingence, défaillance d'une unité de production ou besoin de réserve de puissance). Pendant la thèse, le CLPU est contrôlé et optimisé ainsi que la puissance effacée. Un cas d'étude est présenté sur la contribution des actions de gestion de la demande à l'ajustement entre la demande et la production et l'effet généré sur le réglage secondaire de fréquence.
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Contribution au pilotage de la charge pour accroître la flexibilité du système électrique. / The contribution of load control in increasing electric system flexibilitySaker, Nathalie 30 January 2013 (has links)
Les défis environnementaux et l’augmentation de la population viennent en preuve de l’importance de réfléchir à d’autres moyens de production tout en maintenant la sécurité et la fiabilité du système électrique. La sûreté du système électrique exige à tout moment que la production soit égale à la demande des consommateurs, pour ça, différentes solutions sont déjà mises en place, ces solutions consistent à mettre en marche des moyens de pointes couteux et polluants pendant les périodes de pointes, mais comme les moyens de production son insuffisants et vue la difficulté d’exploitation de nouveaux moyens de production, une nouvelle réflexion sur la gestion de la demande est apparue; celle-ci se base sur la possibilité à gérer la demande du consommateur final au lieu de la satisfaire.L’objectif de la thèse est d’étudier la possibilité à rendre des services au système électrique en appliquant des actions de contrôle dites de DR (Demand Response), sur différents types de charges électriques. Ces actions de DR représentent des interruptions partielles appliquées sur les charges électriques de type thermique. Notre choix s’est basé sur ces types de charges parce que celles-ci emmagasinent de la chaleur respectivement dans l’air et dans l’eau; qui peut être restituée pendant la période de contrôle ou d’interruption. Néanmoins, il existe un effet négatif qui suit le contrôle de ces charges car l’énergie effacée de ces charges est reportée à l’instant de reconnexion de celles-ci; ce report prend la forme d’un pic de consommation nommé CLPU (Cold Load Pick-Up) et qui apparait au moment de la reconnexion. Le CLPU représente un problème qui doit être géré, et sa magnitude dépend des types d’actions de contrôle qu’on veut implanter et aussi des conditions du système électrique (contingence, défaillance d’une unité de production ou besoin de réserve de puissance). Pendant la thèse, le CLPU est contrôlé et optimisé ainsi que la puissance effacée. Un cas d’étude est présenté sur la contribution des actions de gestion de la demande à l‘ajustement entre la demande et la production et l’effet généré sur le réglage secondaire de fréquence. / Environmental challenges and the increasing in electric demand show the importance of considering other form of production while maintaining the safety and reliability of the electrical system. The electrical power systems stability lays on a fundamental constraint: supply and demand must be equal at each instant, so, different solutions are already in place, these solutions include controlling generators’ production during peak periods. But, power units (mainly nuclear, thermal, hydro) capacities are not always sufficient and flexible to follow the demand variations during these periods; an alternative solution to this insufficiency is to make the demand following the electrical power generation by providing bulks of electrical power to the power system by curtailing consumer’s electric load consumption. Such a solution that represents a new organization in the power system industry can be done by Demand Side Management (DSM) actions. The aim of the thesis is to study the possibility to offer services to the electrical system by applying control actions called DR (Demand Response) on different types of electric loads. These DR actions represent partial interruptions of electrical loads’ consumption and especially thermal loads’ consumption.Our choice was based on the thermal electric loads because they store heat respectively in air and water, which can be restored during the control period or interruption. However, there is a negative effect that follows the control of these type of loads because the reduced energy during curtailment period is deferred at the time of reconnection, this deferred power takes the form of a power peak named CLPU (Cold Load Pick-Up), which appears at the time of reconnection. The CLPU is a problem that must be managed, and its magnitude depends on the type of control actions and on the electric system conditions (ie: contingency or failure of a generating unit). In the thesis, the CLPU is controlled and optimized as well as the load reduction during curtailment period. The contribution of control actions in balancing mechanisms and the effect produced on the secondary control of frequency are analyzed.
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Análise do impacto do chuveiro elétrico em redes de distribuição no contexto da tarifa horossazonal / Impact analysis of the electric shower in distribution networksTomé, Mauricio de Castro, 1980- 25 August 2018 (has links)
Orientador: Luiz Carlos Pereira da Silva / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Elétrica e de Computação / Made available in DSpace on 2018-08-25T04:17:06Z (GMT). No. of bitstreams: 1
Tome_MauriciodeCastro_M.pdf: 1294997 bytes, checksum: 7f957ff745612ef36a77596912782f07 (MD5)
Previous issue date: 2014 / Resumo: O presente trabalho procura analisar o aquecimento elétrico de água no setor residencial e seu impacto no perfil de tensão, perdas e energia total acumulada. Por meio de simulações computacionais com uma rede de teste, juntamente com dados de uso dos eletrodomésticos mais comuns no ambiente residencial (separados por região, devido às diferentes condições e padrões de consumo das mesmas), foi possível estimar a quantidade de energia utilizada referente ao chuveiro elétrico, bem como o impacto no perfil de tensão e as perdas na distribuição decorrentes do uso do mesmo. Além disso, também foram analisadas as propostas de tarifação branca da ANEEL e as propostas homologadas pelas concessionárias, e seu impacto na conta de luz do consumidor residencial, para três padrões de consumo: consumo total não modificado, consumo do chuveiro deslocado e consumo do chuveiro eliminado. Na parte de impactos na rede de distribuição, confirmou-se que a utilização do chuveiro elétrico, que é praticamente uma exclusividade brasileira, representa uma parcela significativa do consumo total de uma residência, além de ser um dos maiores responsáveis pelo pico de consumo no setor residencial, o que causa um afundamento no perfil de tensão e aumento nas perdas na distribuição, características indesejadas na operação do sistema elétrico. Já na parte do consumo residencial, foi visto que os postos tarifários homologados pelas concessionárias reduzem em muito os ganhos possíveis com o deslocamento do horário de carga do chuveiro, de forma que a chance de uma adoção significativa da tarifa branca pelos consumidores é baixa. Por outro lado, uma adesão maciça dos consumidores poderia fazer com que o consumo do chuveiro fosse deslocado do horário de ponta e se concentrasse no horário imediatamente posterior, o que pode agravar a situação atual em termos de pico de consumo / Abstract: This thesis presents an analysis of the electricity based water heating in the Brazilian residential sector and its impacts on the electric grid voltage profile, losses and total energy consumption. Using computer simulation through a test network, and considering the most common household appliances' usage data, it was possible to estimate the total energy used by the electric shower, as well as its impact on voltage profile and distribution losses. Moreover, it is also analysed the time of use (TOU) tariff proposed by ANEEL and the consolidated tariffs proposed by the Brazilian utilities, and its impacts in the customers' energy bill, for three load patterns: unmodified, electric shower demand moved off-peak, and without electric shower. Results about the impact on distribution networks confirmed that the electric shower usage (which is almost exclusive to Brazil) represents a large amount of the electric energy used by the residential customers, and, in addition, it is a major contributor to the peak loading of the residential sector, causing voltage drop and increased distribution losses, which are undesired in electric distribution systems. In terms of household consumption, it was possible to conclude that the utilities' approved time-of-use tariffs give little margin for possible savings in the electricity bill in comparison with ANEEL's initial tariff proposal, so that TOU adoption will probably be very low. On the other hand, a massive adoption of the off-peak shower usage by the customers could cause a concentration in its usage in a later time, which would eventually worsen the actual peak hour scenario / Mestrado / Energia Eletrica / Mestre em Engenharia Elétrica
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