Desenvolvimento de plataformas embarcadas aplicadas a implementação de smart buildings com base no framework SmartLVGrid

Detalhes bibliográficos
Autor(a) principal: Fernandes, Rubens de Andrade
Data de Publicação: 2019
Tipo de documento: Trabalho de conclusão de curso
Idioma: por
Título da fonte: Repositório Institucional da Universidade do Estado do Amazonas (UEA)
Texto Completo: http://repositorioinstitucional.uea.edu.br//handle/riuea/2232
Resumo: In the present work, it has developed algorithms for embedded software and hardware devices, associated with microcontrolled and microprocessor platforms, with the purpose of achieving smart building convergence in lighting and energy metering systems without automation, communication and control features. To do so, the approach described in the SmartLVGrid framework is used, a model that uses the retrofit strategy for convergence in intelligent low voltageelectricpowerdistributionnetworks.Thisframeworkwillbeadaptedtoperformbuilding automation at the Embedded Systems Laboratory of the HUB research and development center, associated with the Escola Superior de Tecnologia of the Universidade do Estado do Amazonas. The obtained results indicate the possibility of the smart building convergence without total removal or disposal of the lighting and energy metering systems on site through the retrofit technique, resulting in low implementation costs and fast process of technological transition. ThelightingcontroldeviceswerebasedontheDC-DCconverterBuckLowSideassociatedwith a microcontroller with built-in wireless communication peripherals, allowing the device to be remotely controlled. The energy measuring device has circuits for measuring, conditioning and protecting the system. It also has a microprocessor platform with Linux operational system and integratedcommunicationperipherals.Withtheresults,discussionsandconclusionsofthiswork, it is expected to contribute to a robust and easy implementation method, capable of achieving smart building convergence, with the increase of energy efficiency.
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spelling Desenvolvimento de plataformas embarcadas aplicadas a implementação de smart buildings com base no framework SmartLVGridDevelopment of embedded platforms applied to the implementation of smart buildings based on the SmartLVGrid frameworkSistemas EmbarcadosSmart GridsSmart BuildingsSmart CircuitsEmbedded SystemsMedição, Controle, Correção e Proteção de Sistemas Elétricos de PotênciaIn the present work, it has developed algorithms for embedded software and hardware devices, associated with microcontrolled and microprocessor platforms, with the purpose of achieving smart building convergence in lighting and energy metering systems without automation, communication and control features. To do so, the approach described in the SmartLVGrid framework is used, a model that uses the retrofit strategy for convergence in intelligent low voltageelectricpowerdistributionnetworks.Thisframeworkwillbeadaptedtoperformbuilding automation at the Embedded Systems Laboratory of the HUB research and development center, associated with the Escola Superior de Tecnologia of the Universidade do Estado do Amazonas. The obtained results indicate the possibility of the smart building convergence without total removal or disposal of the lighting and energy metering systems on site through the retrofit technique, resulting in low implementation costs and fast process of technological transition. ThelightingcontroldeviceswerebasedontheDC-DCconverterBuckLowSideassociatedwith a microcontroller with built-in wireless communication peripherals, allowing the device to be remotely controlled. The energy measuring device has circuits for measuring, conditioning and protecting the system. It also has a microprocessor platform with Linux operational system and integratedcommunicationperipherals.Withtheresults,discussionsandconclusionsofthiswork, it is expected to contribute to a robust and easy implementation method, capable of achieving smart building convergence, with the increase of energy efficiency.No presente trabalho, foram desenvolvidos algorítimos para software embarcado e dispositivos de hardware, associados a plataformas microcontroladas e microprocessadas, com o objetivo de realizar a convergência smart building em sistemas de iluminação e medição de energia elétrica sem recursos de automação, comunicação e controle. Para tanto, é utilizada a abordagem descrita no framework SmartLVGrid, um modelo que utiliza a estratégia de retrofit para convergência em redes elétricas inteligentes de distribuição de energia elétrica em baixa tensão. Este framework será adaptado para realizar automação predial no Laboratório de Sistemas Embarcados do centro de pesquisa e desenvolvimento HUB, associado a Escola Superior de Tecnologia da Universidade do Estado do Amazonas. Os resultados obtidos indicam a possibilidade da convergência smart building sem remoção ou descarte total dos sistemas de iluminação e medição de energia no local através da técnica de retrofit, implicando em baixos custos de implementação e em rápido processo de transição tecnológica. Os dispositivos de controle de iluminação foram baseados no conversor DC-DC Buck Low Side associado a um microcontrolador com periféricos de comunicação wireless embutido, permitindo que o dispositivo possa ser controlado de forma remota. O dispositivo de medição de energia conta com circuitos para medição, condicionamento e proteção do sistema. Além de possuir uma plataforma microprocessada com sistema operacional Linux e com periféricos de comunicação integrados. Com os resultados, discussões e conclusões deste trabalho, espera-se contribuir para um método robusto e de fácil implementação, capaz de realizar a convergência smart building, com o incremento da eficiência energética.Universidade do Estado do AmazonasBrasilUEAEvangelista Neto, João4244097441063312http://lattes.cnpq.br/4244097441063312Gondres Torné, Israel1869557808967575http://lattes.cnpq.br/1869557808967575Oliveira, Jozias Parente deFernandes, Rubens de Andrade2020-03-092020-03-11T14:57:02Z2019-12-172020-03-11T14:57:02Zinfo:eu-repo/semantics/publishedVersioninfo:eu-repo/semantics/bachelorThesisapplication/pdfhttp://repositorioinstitucional.uea.edu.br//handle/riuea/2232porACLARA. I-210+ and I-210+c. 2019. Disponível em: <https://www.aclara.com/ products-and-services/smart-meters/ansi-residential/i-210-and-i-210c/>. ALBINI, L. C. P. Redes de computadores. 2015. ALEXANDER, C. K.; SADIKU, M. N. Fundamentos de circuitos elétricos. [S.l.]: AMGH Editora, 2013. ATZORI, L.; IERA, A.; MORABITO, G. The internet of things: A survey. Computer networks, Elsevier, v. 54, n. 15, p. 2787–2805, 2010. AZAZI, H. et al. Review of passive and active circuits for power factor correction in single phase, low power ac-dc converters. In: Proceedings of the 14th International Middle East Power Systems Conference (MEPCON’10). [S.l.: s.n.], 2010. p. 217. BARROS, E.; CAVALCANTE, S. Introdução aos sistemas embarcados. Artigo apresentado na Universidade Federal de Pernambuco-UFPE, p. 36, 2010. BERG, J. Wi-fi peer-to-peer on linux. In: Linux Plumbers Conference 2010. [S.l.: s.n.], 2010. BINGHAM, R. P. Sags and swells. Manager of Technology and Products Dranetz-BMI 1994, Original Draft September 1994 Revised February 16, 1998, New Durham Road Edison, NJ 08818-4019 USA, 1998. BOYLESTAD, R. L. Introductory circuit analysis. [S.l.]: Pearson Education, 2013. BRAY, T. The javascript object notation (json) data interchange format. 2014. CAFFREY, R. J. The intelligent building: an ASHRAE opportunity. [S.l.]: ASHRAE, 1988. CHAPMAN, S. J. Fundamentos de máquinas elétricas. [S.l.]: AMGH Editora, 2013. CHASE, O.; ALMEIDA, F. Sistemas embarcados. Mídia Eletrônica. Página na internet:< www. sbajovem. org/chase>, capturado em, v. 10, n. 11, p. 13, 2007. CHRISTIANSSON, P. Knowledge representations and information flow in the intelligent building. In: Proceedings of he Eighth International Conference on Computing in Civil and Building Engineering. ICCCBE-VIII 2000 (eds: Fruchter R, Pena-Mora F, Roddis K). [S.l.: s.n.], 2000. p. 14–17. CROW, B. P. et al. Ieee 802.11 wireless local area networks. IEEE Communications magazine, IEEE, v. 35, n. 9, p. 116–126, 1997. CUNHA, A. F. O que são sistemas embarcados. Saber Eletrônica, v. 43, n. 414, p. 1–6, 2007. DEVICES, A. ADE9000 Technical Reference Manual. 2017. DEVICES, A. Datasheet ADE9000. 2017. ELGIN. Catálogo: Iluminação. 2019. ESPRESSIF. Datasheet ESP32 V1.0. 2017. 109 EUROPEANCOMISSION. Smart Building: Energy efficiency application. 2017. Disponível em: <https://ec.europa.eu/growth/tools-databases/dem/monitor/sites/default/files/DTM_Smart% 20building%20-%20energy%20efficiency%20v1.pdf>. FAIRCHILD. Datasheet FQP12N60. 2000. FAIRCHILD. Applications of zero voltage crossing optically isolated triac drivers. AN-3004, FAIRCHILD Inc, 2002. FAIRCHILD. Datasheet 1N4007. 2003. FAIRCHILD. Datasheet MOC63. 2005. FARHANGI, H. The path of the smart grid. In: IEEE power and energy magazine. [S.l.: s.n.], 2010. v. 8, p. 18–28. FENG, Z.; LUO, Y.; HAN, Y. Design of led freeform optical system for road lighting with high luminance/illuminance ratio. Optics express, Optical Society of America, v. 18, n. 21, p. 22020–22031, 2010. FERNANDES, R.; GUIMARÃES, W. Implementation of a buck converter with hysteresis voltage control applied to led chip array package for street lighting. In: IEEE. 2018 Argentine Conference on Automatic Control (AADECA). [S.l.], 2018. p. 1–6. FERNANDES, R. de A. GitHub. 2019. Disponível em: <https://github.com/rdafr>. FRANCO, E. Qualidade de energia–causas, efeitos e soluções. Engecomp tecnologia em automaçao e controle LTDA, 2005. GOMES, R. C. S. et al. Smartlvgrid platform—convergence of legacy low-voltage circuits toward the smart grid paradigm. Energies, Multidisciplinary Digital Publishing Institute, v. 12, n. 13, p. 2590, 2019. GOMES, R. C. S. et al. Automation meta-system applied to smart grid convergence of low voltage distribution legacy grids. In: IEEE. 2017 IEEE International Conference on Smart Energy Grid Engineering (SEGE). [S.l.], 2017. p. 400–413. HEISELBERG, P.; CHRISTIANSSON, P.; REINHOLD, C. Intelligent buildings/smart homes. Smart Wireless Living, 2007. HEYDT, G. T.; AYYANAR, R.; THALLAM, R. Power acceptability. IEEE Power Engineering Review, v. 21, n. 9, p. 12–15, 2001. HOY, M. B. Smart buildings: an introduction to the library of the future. 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dc.title.none.fl_str_mv Desenvolvimento de plataformas embarcadas aplicadas a implementação de smart buildings com base no framework SmartLVGrid
Development of embedded platforms applied to the implementation of smart buildings based on the SmartLVGrid framework
title Desenvolvimento de plataformas embarcadas aplicadas a implementação de smart buildings com base no framework SmartLVGrid
spellingShingle Desenvolvimento de plataformas embarcadas aplicadas a implementação de smart buildings com base no framework SmartLVGrid
Fernandes, Rubens de Andrade
Sistemas Embarcados
Smart Grids
Smart Buildings
Smart Circuits
Embedded Systems
Medição, Controle, Correção e Proteção de Sistemas Elétricos de Potência
title_short Desenvolvimento de plataformas embarcadas aplicadas a implementação de smart buildings com base no framework SmartLVGrid
title_full Desenvolvimento de plataformas embarcadas aplicadas a implementação de smart buildings com base no framework SmartLVGrid
title_fullStr Desenvolvimento de plataformas embarcadas aplicadas a implementação de smart buildings com base no framework SmartLVGrid
title_full_unstemmed Desenvolvimento de plataformas embarcadas aplicadas a implementação de smart buildings com base no framework SmartLVGrid
title_sort Desenvolvimento de plataformas embarcadas aplicadas a implementação de smart buildings com base no framework SmartLVGrid
author Fernandes, Rubens de Andrade
author_facet Fernandes, Rubens de Andrade
author_role author
dc.contributor.none.fl_str_mv Evangelista Neto, João
4244097441063312
http://lattes.cnpq.br/4244097441063312
Gondres Torné, Israel
1869557808967575
http://lattes.cnpq.br/1869557808967575
Oliveira, Jozias Parente de
dc.contributor.author.fl_str_mv Fernandes, Rubens de Andrade
dc.subject.por.fl_str_mv Sistemas Embarcados
Smart Grids
Smart Buildings
Smart Circuits
Embedded Systems
Medição, Controle, Correção e Proteção de Sistemas Elétricos de Potência
topic Sistemas Embarcados
Smart Grids
Smart Buildings
Smart Circuits
Embedded Systems
Medição, Controle, Correção e Proteção de Sistemas Elétricos de Potência
description In the present work, it has developed algorithms for embedded software and hardware devices, associated with microcontrolled and microprocessor platforms, with the purpose of achieving smart building convergence in lighting and energy metering systems without automation, communication and control features. To do so, the approach described in the SmartLVGrid framework is used, a model that uses the retrofit strategy for convergence in intelligent low voltageelectricpowerdistributionnetworks.Thisframeworkwillbeadaptedtoperformbuilding automation at the Embedded Systems Laboratory of the HUB research and development center, associated with the Escola Superior de Tecnologia of the Universidade do Estado do Amazonas. The obtained results indicate the possibility of the smart building convergence without total removal or disposal of the lighting and energy metering systems on site through the retrofit technique, resulting in low implementation costs and fast process of technological transition. ThelightingcontroldeviceswerebasedontheDC-DCconverterBuckLowSideassociatedwith a microcontroller with built-in wireless communication peripherals, allowing the device to be remotely controlled. The energy measuring device has circuits for measuring, conditioning and protecting the system. It also has a microprocessor platform with Linux operational system and integratedcommunicationperipherals.Withtheresults,discussionsandconclusionsofthiswork, it is expected to contribute to a robust and easy implementation method, capable of achieving smart building convergence, with the increase of energy efficiency.
publishDate 2019
dc.date.none.fl_str_mv 2019-12-17
2020-03-09
2020-03-11T14:57:02Z
2020-03-11T14:57:02Z
dc.type.status.fl_str_mv info:eu-repo/semantics/publishedVersion
dc.type.driver.fl_str_mv info:eu-repo/semantics/bachelorThesis
format bachelorThesis
status_str publishedVersion
dc.identifier.uri.fl_str_mv http://repositorioinstitucional.uea.edu.br//handle/riuea/2232
url http://repositorioinstitucional.uea.edu.br//handle/riuea/2232
dc.language.iso.fl_str_mv por
language por
dc.relation.none.fl_str_mv ACLARA. I-210+ and I-210+c. 2019. Disponível em: <https://www.aclara.com/ products-and-services/smart-meters/ansi-residential/i-210-and-i-210c/>. ALBINI, L. C. P. Redes de computadores. 2015. ALEXANDER, C. K.; SADIKU, M. N. Fundamentos de circuitos elétricos. [S.l.]: AMGH Editora, 2013. ATZORI, L.; IERA, A.; MORABITO, G. The internet of things: A survey. Computer networks, Elsevier, v. 54, n. 15, p. 2787–2805, 2010. AZAZI, H. et al. Review of passive and active circuits for power factor correction in single phase, low power ac-dc converters. In: Proceedings of the 14th International Middle East Power Systems Conference (MEPCON’10). [S.l.: s.n.], 2010. p. 217. BARROS, E.; CAVALCANTE, S. Introdução aos sistemas embarcados. Artigo apresentado na Universidade Federal de Pernambuco-UFPE, p. 36, 2010. BERG, J. Wi-fi peer-to-peer on linux. In: Linux Plumbers Conference 2010. [S.l.: s.n.], 2010. BINGHAM, R. P. Sags and swells. Manager of Technology and Products Dranetz-BMI 1994, Original Draft September 1994 Revised February 16, 1998, New Durham Road Edison, NJ 08818-4019 USA, 1998. BOYLESTAD, R. L. Introductory circuit analysis. [S.l.]: Pearson Education, 2013. BRAY, T. The javascript object notation (json) data interchange format. 2014. CAFFREY, R. J. The intelligent building: an ASHRAE opportunity. [S.l.]: ASHRAE, 1988. CHAPMAN, S. J. Fundamentos de máquinas elétricas. [S.l.]: AMGH Editora, 2013. CHASE, O.; ALMEIDA, F. Sistemas embarcados. Mídia Eletrônica. Página na internet:< www. sbajovem. org/chase>, capturado em, v. 10, n. 11, p. 13, 2007. CHRISTIANSSON, P. Knowledge representations and information flow in the intelligent building. In: Proceedings of he Eighth International Conference on Computing in Civil and Building Engineering. ICCCBE-VIII 2000 (eds: Fruchter R, Pena-Mora F, Roddis K). [S.l.: s.n.], 2000. p. 14–17. CROW, B. P. et al. Ieee 802.11 wireless local area networks. IEEE Communications magazine, IEEE, v. 35, n. 9, p. 116–126, 1997. CUNHA, A. F. O que são sistemas embarcados. Saber Eletrônica, v. 43, n. 414, p. 1–6, 2007. DEVICES, A. ADE9000 Technical Reference Manual. 2017. DEVICES, A. Datasheet ADE9000. 2017. ELGIN. Catálogo: Iluminação. 2019. ESPRESSIF. Datasheet ESP32 V1.0. 2017. 109 EUROPEANCOMISSION. Smart Building: Energy efficiency application. 2017. Disponível em: <https://ec.europa.eu/growth/tools-databases/dem/monitor/sites/default/files/DTM_Smart% 20building%20-%20energy%20efficiency%20v1.pdf>. FAIRCHILD. Datasheet FQP12N60. 2000. FAIRCHILD. Applications of zero voltage crossing optically isolated triac drivers. AN-3004, FAIRCHILD Inc, 2002. FAIRCHILD. Datasheet 1N4007. 2003. FAIRCHILD. Datasheet MOC63. 2005. FARHANGI, H. The path of the smart grid. In: IEEE power and energy magazine. [S.l.: s.n.], 2010. v. 8, p. 18–28. FENG, Z.; LUO, Y.; HAN, Y. Design of led freeform optical system for road lighting with high luminance/illuminance ratio. Optics express, Optical Society of America, v. 18, n. 21, p. 22020–22031, 2010. FERNANDES, R.; GUIMARÃES, W. Implementation of a buck converter with hysteresis voltage control applied to led chip array package for street lighting. In: IEEE. 2018 Argentine Conference on Automatic Control (AADECA). [S.l.], 2018. p. 1–6. FERNANDES, R. de A. GitHub. 2019. Disponível em: <https://github.com/rdafr>. FRANCO, E. Qualidade de energia–causas, efeitos e soluções. Engecomp tecnologia em automaçao e controle LTDA, 2005. GOMES, R. C. S. et al. Smartlvgrid platform—convergence of legacy low-voltage circuits toward the smart grid paradigm. Energies, Multidisciplinary Digital Publishing Institute, v. 12, n. 13, p. 2590, 2019. GOMES, R. C. S. et al. Automation meta-system applied to smart grid convergence of low voltage distribution legacy grids. In: IEEE. 2017 IEEE International Conference on Smart Energy Grid Engineering (SEGE). [S.l.], 2017. p. 400–413. HEISELBERG, P.; CHRISTIANSSON, P.; REINHOLD, C. Intelligent buildings/smart homes. Smart Wireless Living, 2007. HEYDT, G. T.; AYYANAR, R.; THALLAM, R. Power acceptability. IEEE Power Engineering Review, v. 21, n. 9, p. 12–15, 2001. HOY, M. B. Smart buildings: an introduction to the library of the future. Medical reference services quarterly, Taylor & Francis, v. 35, n. 3, p. 326–331, 2016. HU,C.etal.stube+:aniotcommunicationsharingarchitectureforsmartafter-salesmaintenance in buildings. ACM Transactions on Sensor Networks (TOSN), ACM, v. 14, n. 3-4, p. 29, 2018. HUMFREY, N. Arduino Library List. 2019. Disponível em: <https://www.arduinolibraries.info/ >. JÚNIOR, C. et al. Um medidor de energia elétrica integrado em redes de comunicações. [sn], 2014. 110 KADAH, A. S. Solid state/electromechanical hybrid relay. [S.l.]: Google Patents, 1997. US Patent 5,699,218. LABS, S. 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