Sistema de gestión de energía para bancos de baterías en redes distribución activas empleando el algoritmo de optimización aritmética

Galeano Cabrera , Jaiver David; Ochoa Bermúdez , María Fernanda

Sistema de gestión de energía para bancos de baterías en redes distribución activas empleando el algoritmo de optimización aritmética

dc.contributor.advisor	Montoya Giraldo, Oscar Danilo
dc.contributor.author	Galeano Cabrera , Jaiver David
dc.contributor.author	Ochoa Bermúdez , María Fernanda
dc.contributor.orcid	Montoya Giraldo, Oscar Danilo [0000-0001-6051-4925]
dc.date.accessioned	2024-10-30T19:00:32Z
dc.date.available	2024-10-30T19:00:32Z
dc.date.created	2024-06-11
dc.description	El problema de la gestión de la energía en bancos de baterías instalados en redes de distribución activas que operan de forma aislada o conectada a la red, es el problema que se estudia en este trabajo de grado, con el objetivo de mejorar indicadores financieros, técnicos y ambientales. Para ello se formuló un modelo matemático que propone como funciones objetivo la optimización de los costos operativos de la red, la minimización de las pérdidas de energía relacionadas al transporte de energía y la reducción de las emisiones de dióxido de carbono (CO2) asociadas con la generación de energía. En el modelo matemático también considera un conjunto de restricciones involucradas en la operación de una red de distribución activa en un entorno con recursos energéticos distribuidos (sistemas de almacenamiento en baterías y generadores fotovoltaicos). Se propuso como metodología de solución una estrategia maestro-esclavo que combina el algoritmo de optimización aritmética (AOA) y un método de flujo de potencia por hora basado en aproximaciones sucesivas (HSAPF). Para crear los escenarios de prueba se adaptaron dos sistemas de prueba de 27 y 33 nodos documentados en la literatura especializada adaptados a una red aislada y otra red de distribución conectada a la red local, utilizando datos de generación demanda de un día promedio de operación en Capurganá-Chocó (Rural) y Medellín-Antioquia (Urbana). En relación a los dispositivos de energía distribuida, se consideró la integración de tres baterías de iones de litio de diferentes tipos y tres generadores fotovoltaicos distribuidos a las redes eléctricas. Adicionalmente, se determinaron los costos de producción de energía y emisiones de CO2 del combustible diésel en Colombia y de la red local, así como los costos de mantenimiento asociados a los GD fotovoltaicos y a las baterías. Con el propósito de validar la efectividad del método propuesto en términos de solución, repetibilidad y tiempos de procesamiento, se emplearon tres métodos de comparación (PPSO, PVSA y PALO) reportados en la literatura especializada para resolver el problema abordado en este trabajo. En las redes de prueba objeto de estudio, el método de solución propuesto logró los mejores resultados en términos de calidad de la solución, repetibilidad y en cuanto al tiempo de procesamiento su resultado fue competitivo con el de los demás métodos.
dc.description.abstract	The issue of energy management in battery banks installed in active distribution networks, whether operating in isolation or connected to the grid, is the focus of this thesis. The goal is to improve financial, technical, and environmental indicators. To achieve this, a mathematical model was formulated with the objective functions of optimizing the network's operational costs, minimizing energy losses associated with energy transport, and reducing carbon dioxide (CO2) emissions related to energy generation. The mathematical model also considers a set of constraints involved in the operation of an active distribution network in an environment with distributed energy resources (battery storage systems and photovoltaic generators). A master-slave strategy was proposed as the solution methodology, combining the arithmetic optimization algorithm (AOA) and an hourly successive approximation power flow method (HSAPF). To create test scenarios, two test systems with 27 and 33 nodes documented in specialized literature were adapted to an isolated network and a distribution network connected to the local grid, using generation and demand data from an average day of operation in Capurganá-Chocó (Rural) and Medellín-Antioquia (Urban). Regarding distributed energy devices, the integration of three different types of lithium-ion batteries and three photovoltaic generators distributed across the electrical networks was considered. Additionally, the energy production costs and CO2 emissions from diesel fuel in Colombia and the local grid were determined, as well as the maintenance costs associated with the photovoltaic distributed generators and the batteries. To validate the effectiveness of the proposed method in terms of solution quality, repeatability, and processing times, three comparison methods (PPSO, PVSA and PALO) reported in the specialized literature were used to solve the problem addressed in this work. In the test networks studied, the proposed solution method achieved the best results in terms of solution quality, repeatability, and competitive processing times compared to the other methods.
dc.format.mimetype	pdf
dc.identifier.uri	http://hdl.handle.net/11349/42601
dc.language.iso	spa
dc.publisher	Universidad Distrital Francisco José de Caldas
dc.relation.references	Abualigah, L., Diabat, A., Mirjalili, S., Abd Elaziz, M., and Gandomi, A. H. (2021). The arithmetic optimization algorithm. Computer Methods in Applied Mechanics and Engineering, 376:113609.
dc.relation.references	Administración Nacional de Aeronáutica y el Espacio NASA, B. (2024). Prediction of Worldwide Energy Resources https://power.larc.nasa.gov/data-access-viewer/ (acceso 15 de abril de 2024).
dc.relation.references	Adnan, M., Ghadi, Y., Ahmed, I., and Ali, M. (2023). Transmission network planning in super smartgrids: A survey. IEEE Access, 11:77163–77227.
dc.relation.references	Aghdam, F. H., Mudiyanselage, M. W., Mohammadi-Ivatloo, B., and Marzband, M. (2023). Optimal scheduling of multi-energy type virtual energy storage system in reconfigurable distribution networks for congestion management. Applied Energy, 333:120569.
dc.relation.references	Ahmadi, S. E., Marzband, M., Ikpehai, A., and Abusorrah, A. (2022). Optimal stochastic scheduling of plug-in electric vehicles as mobile energy storage systems for resilience enhancement of multi-agent multi-energy networked microgrids. Journal of Energy Storage, 55:105566.
dc.relation.references	Avellaneda-Gomez, L. S., Grisales-Noreña, L. F., Cortés-Caicedo, B., Montoya, O. D., and Bola˜nos, R. I. (2024). Optimal battery operation for the optimization of power distribution networks: An application of the ant lion optimizer. Journal of Energy Storage, 84:110684.
dc.relation.references	Bharatee, A., Ray, P. K., Subudhi, B., and Ghosh, A. (2022). Power management strategies in a hybrid energy storage system integrated ac/dc microgrid: A review.
dc.relation.references	Buchibabu, P. and Somlal, J. (2023). Green energy management in dc microgrids enhanced with robust model predictive control and muddled tuna swarm mppt. Electrical Engineering.
dc.relation.references	Byrne, R. H., Nguyen, T. A., Copp, D. A., Chalamala, B. R., and Gyuk, I. (2017). Energy management and optimization methods for grid energy storage systems. IEEE Access, 6:13231–13260.
dc.relation.references	Chen, J., Zhang, Y., Li, W., Cheng, W., and Zhu, Q. (2022). State of charge estimation for lithium-ion batteries using gated recurrent unit recurrent neural network and adaptive kalman filter. Journal of Energy Storage, 55:105396.
dc.relation.references	Chtita, S., Derouich, A., Motahhir, S., and Ghzizal, A. E. (2023). A new mppt design using arithmetic optimization algorithm for pv energy storage systems operating under partial shading conditions. Energy Conversion and Management, 289:117197.
dc.relation.references	Cortés-Caicedo, B., Grisales-Noreña, L. F., Montoya, O. D., Rodriguez-Cabal, M. A., and Rosero, J. A. (2022). Energy management system for the optimal operation of pv generators in distribution systems using the antlion optimizer: A colombian urban and rural case study. Sustainability, 14(23):16083.
dc.relation.references	dos Santos Neto, P. J., Barros, T. A., Silveira, J. P., Ruppert Filho, E., Vasquez, J. C., and Guerrero, J. M. (2020). Power management techniques for grid-connected dc microgrids: A comparative evaluation. Applied Energy, 269:115057.
dc.relation.references	Elattar, E. E., Shaheen, A. M., Elsayed, A. M., and El-Sehiemy, R. A. (2020). Optimal power flow with emerged technologies of voltage source converter stations in meshed power systems. IEEE Access, 8:166963–166979.
dc.relation.references	Elsayed, A. T., Mohamed, A. A., and Mohammed, O. A. (2015). Dc microgrids and distribution systems: An overview.
dc.relation.references	Falaghi, H., Ramezani, M., Haghifam, M.-R., and Milani, K. (2005). Optimal selection of conductors in radial distribution systems with time varying load. In 18th International Conference and Exhibition on Electricity Distribution (CIRED 2005). IEE.
dc.relation.references	García Rendón, J., Gaviria Hinestroza, A., and Salazar Moreno, L. (2011). Determinantes del precio de la energía eléctrica en el mercado no regulado en colombia. Revista Ciencias Estratégicas
dc.relation.references	Garrido-Arévalo, V. M., Gil-González, W., Montoya, O. D., Grisales-Noreña, L. F., and Hernández, J. C. (2024). Optimal dispatch of ders and battery-based ess in distribution grids while considering reactive power capabilities and uncertainties: A second-order cone programming formulation. IEEE Access.
dc.relation.references	Garrido-Arévalo, V. M., Montoya, O. D., Gil-González, W., Grisales-Nore˜na, L. F., and Hernández, J. C. (2024). An sdp relaxation in the complex domain for the efficient coordination of bess and dgs in single-phase distribution grids while considering reactive power capabilities. Journal of Energy Storage, 90:111913.
dc.relation.references	Gawusu, S., Mensah, R. A., and Das, O. (2022). Exploring distributed energy generation for sustainable development: A data mining approach. Journal of Energy Storage, 48:104018.
dc.relation.references	Gil-González, W., Montoya, O. D., Grisales-Noreña, L. F., Cruz-Peragón, F., and Alcal´a, G. (2020). Economic dispatch of renewable generators and bess in dc microgrids using second-order cone optimization. Energies, 13(7):1703.
dc.relation.references	Gil-González, W., Montoya, O. D., Grisales-Nore˜na, L. F., and Escobar-Mejía, A. (2021). Optimal economic– environmental operation of bess in ac distribution systems: A convex multi-objective formulation. Computation, 9(12):137.
dc.relation.references	Gil-González, W., Montoya, O. D., Holguín, E., Garces, A., and Grisales-Noreña, L. F. (2019). Economic dispatch of energy storage systems in dc microgrids employing a semidefinite programming model. Journal of Energy Storage, 21:1–8.
dc.relation.references	Grisales, L. F., Grajales, A., Montoya, O. D., Hincapie, R. A., Granada, M., and Castro, C. A. (2017). Optimal location, sizing and operation of energy storage in distribution systems using multi-objective approach. IEEE Latin America Transactions, 15(6):1084–1090.
dc.relation.references	Grisales-Noreña, L., Cortes-Caicedo, B., Montoya, O. D., Hernández, J., and Alcalá, G. (2023a). A battery energy management system to improve the financial, technical, and environmental indicators of colombian urban and rural networks. Journal of Energy Storage, 65:107199.
dc.relation.references	Grisales-Noreña, L., Gonzalez Montoya, D., and Ramos-Paja, C. (2018). Optimal sizing and location of distributed generators based on pbil and pso techniques. Energies, 11(4):1018.
dc.relation.references	Grisales-Noreña, L., Montoya, O. D., and Ramos-Paja, C. A. (2020a). An energy management system for optimal operation of bss in dc distributed generation environments based on a parallel pso algorithm. Journal of Energy Storage, 29:101488.
dc.relation.references	Grisales-Noreña, L., Restrepo-Cuestas, B., Cortes-Caicedo, B., Montano, J., Rosales-Muñoz, A., and Rivera, M. (2022a). Optimal location and sizing of distributed generators and energy storage systems in microgrids: A review. Energies, 16(1):106.
dc.relation.references	Grisales-Noreña, L. F., Montoya, O. D., Ramos-Paja, C. A., Hernandez-Escobedo, Q., and Perea-Moreno, A.-J. (2020b). Optimal location and sizing of distributed generators in dc networks using a hybrid method based on parallel pbil and pso. Electronics, 9(11):1808.
dc.relation.references	Grisales-Nore˜na, L. F., Ocampo-Toro, J. A., Montoya-Giraldo, O. D., Montano, J., and Hernández, J. (2023b). Optimal operation of battery storage systems in standalone and grid-connected dc microgrids using parallel metaheuristic optimization algorithms. Journal of Energy Storage, 65:107240.
dc.relation.references	Grisales-Noreña, L. F., Ocampo-Toro, J. A., Rosales-Muñoz, A. A., Cortes-Caicedo, B., and Montoya, O. D. (2022b). An energy management system for pv sources in standalone and connected dc networks considering economic, technical, and environmental indices. Sustainability, 14(24):16429.
dc.relation.references	Grisales Noreña, L. F., Restrepo Cuestas, B. J., and Jaramillo Ramirez, F. E. (2017). Ubicación y dimensionamiento de generación distribuida: Una revisión. Ciencia e Ingeniería Neogranadina, 27(2):157–176.
dc.relation.references	Guerrero, J. M., Vasquez, J. C., Matas, J., de Vicuna, L. G., and Castilla, M. (2011). Hierarchical control of droop-controlled ac and dc microgrids—a general approach toward standardization. IEEE Transactions on Industrial Electronics, 58(1):158–172.
dc.relation.references	Hannan, M. A., Faisal, M., Ker, P. J., Mun, L. H., Parvin, K., Mahlia, T. M. I., and Blaabjerg, F. (2018a). A review of internet of energy based building energy management systems: Issues and recommendations. IEEE Access, 6:38997–39014.
dc.relation.references	Hannan, M. A., Faisal, M., Ker, P. J., Mun, L. H., Parvin, K., Mahlia, T. M. I., and Blaabjerg, F. (2018b). A review of internet of energy based building energy management systems: Issues and recommendations. IEEE Access, 6:38997–39014.
dc.relation.references	Hassan, Q., Jaszczur, M., Przenzak, E., and Abdulateef, J. (2016). The pv cell temperature effect on the energy production and module efficiency.
dc.relation.references	Hussain, B., Asif Ali Naqvi, S., Anwar, S., and Usman, M. (2023). Effect of wind and solar energy production, and economic development on the environmental quality: Is this the solution to climate change? Gondwana Research, 119:27–44.
dc.relation.references	Instituto Colombiano de Normas Técnicas y Certificación ICONTEC, N. (2013). Tensiones y frecuencia nominales en sistemas de energía eléctrica en redes de servicio público NTC 1340.
dc.relation.references	Instituto de Planificación y Promoción de Soluciones Energéticas para Zonas no Interconectadas IPSE, N. (2022). Informes Mensuales de Telemetría https://ipse.gov.co/cnm/informe-mensuales-telemetria/ (acceso 14 de abril de 2024).
dc.relation.references	Jathar, L. D., Ganesan, S., Awasarmol, U., Nikam, K., Shahapurkar, K., Soudagar, M. E. M., Fayaz, H., El-Shafay, A., Kalam, M., Bouadila, S., Baddadi, S., Tirth, V., Nizami, A. S., Lam, S. S., and Rehan, M. (2023). Comprehensive review of environmental factors influencing the performance of photovoltaic panels: Concern over emissions at various phases throughout the lifecycle. Environmental Pollution, 326:121474.
dc.relation.references	Li, X., He, Z., Xia, S., and Yang, Y. (2024). Greenness change associated with construction and operation of photovoltaic solar energy in china. Renewable Energy, 226:120461.
dc.relation.references	Li, Y., Feng, B., Li, G., Qi, J., Zhao, D., and Mu, Y. (2018). Optimal distributed generation planning in active distribution networks considering integration of energy storage. Applied Energy, 210:1073–1081.
dc.relation.references	Liao, X., Zhou, Z., Li, Z., and Huai, Q. (2023). Dynamic reconfiguration of ac/dc hybrid distribution network considering non-ideal linear bes model. Energy Reports, 9:5628–5646.
dc.relation.references	Lopez-Castrillon, Y. U. and Gaviria-Cata˜no, F. A. (2018). Metodología y evaluación de recursos energéticos renovables: implementación de microrredes aisladas. Visión electrónica, 12(2):162–172.
dc.relation.references	Ma, Z., Wang, Y., and Song, W. (2019). A new fitness function with two rankings for evolutionary constrained multiobjective optimization. IEEE Transactions on Systems, Man, and Cybernetics: Systems, 51(8):5005–5016.
dc.relation.references	Mariano-Hern´andez, D., Hern´andez-Callejo, L., Zorita-Lamadrid, A., Duque-Pérez, O., and Santos García, F. (2021). A review of strategies for building energy management system: Model predictive control, demand side management, optimization, and fault detect &; diagnosis. Journal of Building Engineering, 33:101692.
dc.relation.references	Ministerio de Minas y Energía, N. (1998). NTC 2050.
dc.relation.references	Monteiro, V., Monteiro, L. F. C., Franco, F. L., Mandrioli, R., Ricco, M., Grandi, G., and Afonso, J. L. (2021). The role of front-end ac/dc converters in hybrid ac/dc smart homes: Analysis and experimental validation. Electronics, 10(21):2601.
dc.relation.references	Montoya, O. D., Fuentes, J. E., Moya, F. D., Barrios, J. A., and Chamorro, H. R. (2021). Reduction of annual operational costs in power systems through the optimal siting and sizing of statcoms. Applied Sciences, 11(10):4634.
dc.relation.references	Montoya, O. D., Garrido, V. M., Gil-Gonzalez, W., and Grisales-Norena, L. F. (2019). Power flow analysis in dc grids: Two alternative numerical methods. IEEE Transactions on Circuits and Systems II: Express Briefs, 66(11):1865–1869.
dc.relation.references	Montoya, O. D. and Gil-González, W. (2020). Dynamic active and reactive power compensation in distribution networks with batteries: A day-ahead economic dispatch approach. Computers & Electrical Engineering, 85:106710.
dc.relation.references	Montoya, O. D., Gil-González, W., Bola˜nos, R. I., Muñoz-Torres, D. F., Hernández, J. C., and Grisales- Noreña, L. F. (2024). Effective power coordination of besus in distribution grids via the sine-cosine algorithm.
dc.relation.references	Montoya, O. D., Grajales, A., Garces, A., and Castro, C. A. (2017). Distribution systems operation considering energy storage devices and distributed generation. IEEE Latin America Transactions, 15(5):890–900.
dc.relation.references	Papari, B., Edrington, C. S., and Gonsoulin, D. (2019). Optimal energy-emission management in hybrid ac-dc microgrids with vehicle-2-grid technology. Journal of Renewable and Sustainable Energy, 11(1).
dc.relation.references	Parhizi, S., Lotfi, H., Khodaei, A., and Bahramirad, S. (2015). State of the art in research on microgrids: A review.
dc.relation.references	Pham, V. C., Kim, H., Choi, J.-H., Nyongesa, A. J., Kim, J., Jeon, H., and Lee, W.-J. (2022). Effectiveness of the speed reduction strategy on exhaust emissions and fuel oil consumption of a marine generator engine for dc grid ships. Journal of Marine Science and Engineering, 10(7):979.
dc.relation.references	Quashie, M., Marnay, C., Bouffard, F., and Joós, G. (2018). Optimal planning of microgrid power and operating reserve capacity. Applied Energy, 210:1229–1236.
dc.relation.references	Raihan, A. (2023). A review of the global climate change impacts, adaptation strategies, and mitigation options in the socio-economic and environmental sectors. Journal of Environmental Science and Economics, 2(3):36–58.
dc.relation.references	Saeed, M. H., Fangzong, W., Kalwar, B. A., and Iqbal, S. (2021). A review on microgrids’ challenges &; perspectives. IEEE Access, 9:166502–166517.
dc.relation.references	Sandgani, M. R. and Sirouspour, S. (2017). Coordinated optimal dispatch of energy storage in a network of grid-connected microgrids. IEEE Transactions on Sustainable Energy, 8:1166–1176.
dc.relation.references	Shawon, S. M. R. H., Liang, X., and Janbakhsh, M. (2023). Optimal placement of distributed generation units for microgrid planning in distribution networks. IEEE Transactions on Industry Applications, 59(3):2785–2795.
dc.relation.references	Sheikhinejad, R., Gharehpetian, G., and Rastegar, H. (2024). Active distribution network expansion planning considering microgrids for supplying critical loads. Sustainable Energy, Grids and Networks, 38:101281.
dc.relation.references	Temel, P., Kentel, E., and Alp, E. (2023). Development of a site selection methodology for run-of-river hydroelectric power plants within the water-energy-ecosystem nexus. Science of The Total Environment, 856:159152.
dc.relation.references	Thirunavukkarasu, G. S., Seyedmahmoudian, M., Jamei, E., Horan, B., Mekhilef, S., and Stojcevski, A. (2022). Role of optimization techniques in microgrid energy management systems—a review.
dc.relation.references	Téllez Gutiérrez, S. M., Rosero García, J., and Céspedes Gandarillas, R. (2018). Advanced metering infrastructure in colombia: benefits, challenges and opportunities. Ingeniería y Desarrollo, 36(2):469– 488.
dc.relation.references	XM Administradores del mercado eléctrico, B. (2020). En Colombia factor de emisión de CO2 por generación eléctrica del sistema interconectado 164.38 gramos de CO2 por kilovatio hora https://www.xm.com.co/noticias/en-colombia-factor-de-emision-de-co2-por-generacion-electricadel- sistema-interconectado (Acceso el 21 de abril de 2024).
dc.relation.references	XM Administradores del mercado eléctrico, B. (2023). Sinergox Database https://sinergox.xm.com.co/Paginas/Home.aspx (acceso el 21 de abril de 2024).
dc.relation.references	Yıldız, B. S., Kumar, S., Panagant, N., Mehta, P., Sait, S. M., Yildiz, A. R., Pholdee, N., Bureerat, S., and Mirjalili, S. (2023). A novel hybrid arithmetic optimization algorithm for solving constrained optimization problems. Knowledge-Based Systems, 271:110554.
dc.relation.references	Zheng, Y., Hill, D. J., and Dong, Z. Y. (2017). Multi-agent optimal allocation of energy storage systems in distribution systems. IEEE Transactions on Sustainable Energy, 8(4):1715–1725.
dc.relation.references	Zia, M. F., Elbouchikhi, E., and Benbouzid, M. (2018). Microgrids energy management systems: A critical review on methods, solutions, and prospects.
dc.rights.acceso	Abierto (Texto Completo)
dc.rights.accessrights	OpenAccess
dc.subject	Algoritmo de optimización aritmética
dc.subject	Técnicas de optimización
dc.subject	Sistemas de almacenamiento de baterías
dc.subject	Optimización de costos de energía
dc.subject	Minimización de pérdidas de energía
dc.subject	Reducción del impacto ambiental
dc.subject.keyword	Arithmetic optimization algorithm
dc.subject.keyword	Optimization techniques
dc.subject.keyword	Battery storage systems
dc.subject.keyword	Energy cost optimization
dc.subject.keyword	Energy loss minimization
dc.subject.keyword	Environmental impact reduction
dc.subject.lemb	Ingeniería Eléctrica -- Tesis y disertaciones académicas
dc.subject.lemb	Gestión de energía en bancos de baterías
dc.subject.lemb	Optimización de redes de distribución activas
dc.subject.lemb	Reducción de emisiones de CO2 en generación de energía
dc.subject.lemb	Integración de sistemas de almacenamiento y generadores fotovoltaicos
dc.title	Sistema de gestión de energía para bancos de baterías en redes distribución activas empleando el algoritmo de optimización aritmética
dc.title.titleenglish	Energy management system for battery banks in active distribution networks using the arithmetic optimization algorithm
dc.type	bachelorThesis
dc.type.coar	http://purl.org/coar/resource_type/c_7a1f
dc.type.degree	Monografía
dc.type.driver	info:eu-repo/semantics/bachelorThesis

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