Publicado

2024-01-30

Impact of the simultaneous integration of DER, DR, and BES strategies in a distribution network

Impacto de la integración simultánea de DER, RD y EAEE en una red de distribución

DOI:

https://doi.org/10.15446/sicel.v11.109987

Palabras clave:

BES strategies, Co-simulation, DER, DR, impacts (en)
Co-simulación, impactos, DER, RD, EAEE (es)

Descargas

Autores/as

  • Alejandra Martinez Peñaloza Universidad Industrial de Santander https://orcid.org/0000-0003-0328-4478
  • César Duarte Universidad Industrial de Santander
  • German Osma Pinto Universidad Industrial de Santander

The massive integration of distributed energy resources into electricity networks has produced impacts on voltage profiles and power losses, among others. Nevertheless, demand response programs or energy saving strategies in buildings are initiatives used to improve the demand profile. Therefore, this paper seeks to analyze the impact of the simultaneous integration of distributed energy resources, demand response programs and energy saving strategies in buildings in a distribution network. A co-simulation in Python and PowerFactory is used to simulate operating scenarios automatically. As a result, the simultaneous integration of the initiatives favors parameters such as voltage levels, power losses and transformer loading. However, it is necessary to set limits on the integration of resources to avoid affecting the operation of electricity networks.

La integración desmedida de los recursos energéticos distribuidos a las redes de eléctricas ha producido impactos en los perfiles de tensión y las pérdidas de potencia, entre otros. Sin embargo, los programas de respuesta de la demanda o las estrategias de ahorro energético en edificaciones son iniciativas empleadas para mejorar el perfil de demanda. Por ello, este trabajo busca analizar el impacto de la integración simultánea de los recursos energéticos distribuidos, los programas de respuesta de la demanda y las estrategias de ahorro energético en edificaciones en una red de distribución. Una co-simulación en Python y PowerFactory es empleada para simular los escenarios de operación de forma automática. Como resultado se observa que la integración simultánea de las iniciativas favorece parámetros como los niveles de tensión, las pérdidas de potencia y la cargabilidad del transformador. No obstante, es necesario establecer límites de integración de recursos para evitar afectaciones en la operación de las redes eléctricas.

Referencias

REN21, “Renewables 2022 - Global Status Report,” Paris, 2022.

IEA, IRENA, UNSD, W. Bank, and WHO, “Tracking SDG7: The Energy Progress Report 2021,” Washington DC, 2021.

B. Parrish, R. Gross, and P. Heptonstall, “On demand: Can demand response live up to expectations in managing electricity systems?,” Energy Res. Soc. Sci., vol. 51, no. November 2018, pp. 107–118, 2019.

J. Teng, P. Wang, X. Mu, and W. Wang, “Energy-saving performance analysis of green technology implications for decision-makers of multi-story buildings,” Environ. Dev. Sustain., vol. 23, no. 15639–15665, 2021.

Z. Huang, J. Ge, K. Zhao, and J. Shen, “Post-evaluation of energy consumption of the green retrofit building,” Energy Procedia, vol. 158, pp. 3608–3613, 2019.

E. Mancini, M. Longo, F. Foiadelli, G. Parrotta, and G. Montinaro, “Different penetration of electric vehicles and impact on developments in the electric grid,” 2020 IEEE Veh. Power Propuls. Conf. VPPC 2020 - Proc., 2020.

M. Katsanevakis, R. A. Stewart, and L. Junwei, “A novel voltage stability and quality index demonstrated on a low voltage distribution network with multifunctional energy storage systems,” Electr. Power Syst. Res., vol. 171, no. March, pp. 264–282, 2019.

S. Ullah, A. M. A. Haidar, P. Hoole, H. Zen, and T. Ahfock, “The current state of Distributed Renewable Generation, challenges of interconnection and opportunities for energy conversion based DC microgrids,” J. Clean. Prod., vol. 273, p. 122777, 2020.

P. Ruset, F. Batrinu, and R. Porumb, “The Challenges of the Electrical Systems of the Future,” UPEC 2020 - 2020 55th Int. Univ. Power Eng. Conf. Proc., pp. 20–23, 2020.

M. Zeraati, M. E. Hamedani Golshan, and J. M. Guerrero, “A Consensus-Based Cooperative Control of PEV Battery and PV Active Power Curtailment for Voltage Regulation in Distribution Networks,” IEEE Trans. Smart Grid, vol. 10, no. 1, pp. 670–680, 2019.

A. M. Howlader, S. Sadoyama, L. R. Roose, and Y. Chen, “Active power control to mitigate voltage and frequency deviations for the smart grid using smart PV inverters,” Appl. Energy, vol. 258, no. April 2019, p. 114000, 2020.

S. Maharjan, D. Sampath Kumar, and A. M. Khambadkone, “Enhancing the voltage stability of distribution network during PV ramping conditions with variable speed drive loads,” Appl. Energy, vol. 264, no. March, p. 114733, 2020.

P. Johansson, M. Vendel, and C. Nuur, “Integrating distributed energy resources in electricity distribution systems: An explorative study of challenges facing DSOs in Sweden,” Util. Policy, vol. 67, no. April, p. 101117, 2020.

A. Alzahrani, H. Alharthi, and M. Khalid, “Minimization of power losses through optimal battery placement in a distributed network with high penetration of photovoltaics,” Energies, vol. 13, no. 1, p. 140, 2020.

C. Jankowiak, A. Zacharopoulos, C. Brandoni, P. Keatley, P. MacArtain, and N. Hewitt, “Assessing the benefits of decentralised residential batteries for load peak shaving,” J. Energy Storage, vol. 32, no. July, p. 101779, 2020.

A. K. Karmaker, S. Roy, and M. R. Ahmed, “Analysis of the Impact of Electric Vehicle Charging Station on Power Quality Issues,” in 2019 International Conference on Electrical, Computer and Communication Engineering (ECCE), 2019.

F. M. Camilo, V. F. Pires, R. Castro, and M. E. Almeida, “The impact of harmonics compensation ancillary services of photovoltaic microgeneration in low voltage distribution networks,” Sustain. Cities Soc., vol. 39, no. November 2017, pp. 449–458, 2018.

J. H. Angelim and C. de M. Affonso, “Probabilistic assessment of voltage quality on solar-powered electric vehicle charging station,” Electr. Power Syst. Res., vol. 189, no. April, p. 106655, 2020.

A. Elkholy, “Harmonics assessment and mathematical modeling of power quality parameters for low voltage grid connected photovoltaic systems,” Sol. Energy, vol. 183, no. March, pp. 315–326, 2019.

M. R. Mansouri, M. Simab, and B. B. Firouzi, “Impact of demand response on reliability enhancement in distribution networks,” Sustain., vol. 13, no. 23, p. 13201, 2021.

H. Dehghani and B. Vahidi, “Evaluating the effects of demand response programs on distribution cables life expectancy,” Electr. Power Syst. Res., vol. 213, no. June, p. 108710, 2022.

W. K. Alhuwayil, M. Abdul Mujeebu, and A. M. M. Algarny, “Impact of external shading strategy on energy performance of multi-story hotel building in hot-humid climate,” Energy, vol. 169, pp. 1166–1174, Feb. 2019.

R. Qiao and T. Liu, “Impact of building greening on building energy consumption: A quantitative computational approach,” J. Clean. Prod., vol. 246, p. 119020, 2020.

A. Ragab and A. Abdelrady, “Impact of green roofs on energy demand for cooling in egyptian buildings,” Sustain., vol. 12, no. 14, pp. 1–13, 2020.

A. Aboelata, “Assessment of green roof benefits on buildings’ energy-saving by cooling outdoor spaces in different urban densities in arid cities,” Energy, vol. 219, p. 119514, 2021.

Y. Movahed, A. Bakhtiari, S. Eslami, and Y. Noorollahi, “Investigation of single-storey residential green roof contribution to buildings energy demand reduction in different climate zones of Iran,” Int. J. Green Energy, vol. 18, no. 1, pp. 100–110, 2021.

L. V. de Abreu-Harbich, V. L. A. Chaves, and M. C. G. O. Brandstetter, “Evaluation of strategies that improve the thermal comfort and energy saving of a classroom of an institutional building in a tropical climate,” Build. Environ., vol. 135, pp. 257–268, May 2018.

G. Osma-Pinto and G. Ordóñez-Plata, “Measuring factors influencing performance of rooftop PV panels in warm tropical climates,” Sol. Energy, vol. 185, no. April, pp. 112–123, 2019.

J. Caballero-Peña, C. Cadena-Zarate, and G. Osma-Pinto, “Hourly characterization of the integration of DER in a network from deterministic and probabilistic approaches using Co-simulation PowerFactory-Python,” Alexandria Eng. J., vol. 63, no. August, pp. 283–305, 2023.

J. Garcia-Villalobos, I. Zamora, M. Marinelli, P. Eguia, and J. I. San Martin, “Co-simulation with DIgSILENT powerfactory and MATLAB: Optimal integration of plug-in electric vehicles in distribution networks,” in Advanced Smart Grid Functionalities Based on PowerFactory, Springer International Publishing, 2018, pp. 67–91.

A. Jahic, M. Eskander, and D. Schulz, “Charging schedule for load peak minimization on large-scale electric bus depots,” Appl. Sci., vol. 9, no. 9, p. 1748, 2019.

C. D. Lopez, M. Cvetkovic, and P. Palensky, “Enhancing PowerFactory Dynamic Models with Python for Rapid Prototyping,” in 2019 IEEE 28th International Symposium on Industrial Electronics (ISIE), 2019, vol. 2019-June, pp. 93–99.

J. Caballero-Peña, C. Cadena-Zarate, and G. Osma-Pinto, “Análisis de la operación en estado estable de una red eléctrica de baja tensión con inyección de potencia de sistemas fotovoltaicos,” Rev. UIS Ing., vol. 19, no. 4, pp. 89–101, 2020.

J. Caballero-Peña, C. Cadena-Zarate, A. Parrado-Duque, and G. Osma-Pinto, “Distributed energy resources on distribution networks: A systematic review of modelling, simulation, metrics, and impacts,” Int. J. Electr. Power Energy Syst., vol. 138, no. June, p. 107900, 2022.

C.-M. Hsieh, J.-J. Li, L. Zhang, and B. Schwegler, “Effects of tree shading and transpiration on building cooling energy use,” Energy Build., vol. 159, pp. 382–397, Jan. 2018.

X. Cui, M. R. Islam, and K. J. Chua, “Experimental study and energy saving potential analysis of a hybrid air treatment cooling system in tropical climates,” Energy, vol. 172, pp. 1016–1026, Apr. 2019.

X. Cui, X. Yang, S. Qin, X. Meng, L. Jin, and K. J. Chua, “Performance investigation of an evaporative pre-cooled air-conditioning system in tropics,” in Energy Procedia, 2019, vol. 158, pp. 5673–5678.

R. M. Reffat and R. M. Ahmad, “Determination of optimal energy-efficient integrated daylighting systems into building windows,” Sol. Energy, vol. 209, no. September, pp. 258–277, 2020.

Cómo citar

APA

Martinez Peñaloza, A., Duarte, C. y Osma Pinto, G. (2024). Impact of the simultaneous integration of DER, DR, and BES strategies in a distribution network. Simposio Internacional sobre la Calidad de la Energía Eléctrica - SICEL, 11. https://doi.org/10.15446/sicel.v11.109987

ACM

[1]
Martinez Peñaloza, A., Duarte, C. y Osma Pinto, G. 2024. Impact of the simultaneous integration of DER, DR, and BES strategies in a distribution network. Simposio Internacional sobre la Calidad de la Energía Eléctrica - SICEL. 11, (ene. 2024). DOI:https://doi.org/10.15446/sicel.v11.109987.

ACS

(1)
Martinez Peñaloza, A.; Duarte, C.; Osma Pinto, G. Impact of the simultaneous integration of DER, DR, and BES strategies in a distribution network. SICEL 2024, 11.

ABNT

MARTINEZ PEÑALOZA, A.; DUARTE, C.; OSMA PINTO, G. Impact of the simultaneous integration of DER, DR, and BES strategies in a distribution network. Simposio Internacional sobre la Calidad de la Energía Eléctrica - SICEL, [S. l.], v. 11, 2024. DOI: 10.15446/sicel.v11.109987. Disponível em: https://revistas.unal.edu.co/index.php/SICEL/article/view/109987. Acesso em: 8 feb. 2025.

Chicago

Martinez Peñaloza, Alejandra, César Duarte, y German Osma Pinto. 2024. «Impact of the simultaneous integration of DER, DR, and BES strategies in a distribution network». Simposio Internacional Sobre La Calidad De La Energía Eléctrica - SICEL 11 (enero). https://doi.org/10.15446/sicel.v11.109987.

Harvard

Martinez Peñaloza, A., Duarte, C. y Osma Pinto, G. (2024) «Impact of the simultaneous integration of DER, DR, and BES strategies in a distribution network», Simposio Internacional sobre la Calidad de la Energía Eléctrica - SICEL, 11. doi: 10.15446/sicel.v11.109987.

IEEE

[1]
A. Martinez Peñaloza, C. Duarte, y G. Osma Pinto, «Impact of the simultaneous integration of DER, DR, and BES strategies in a distribution network», SICEL, vol. 11, ene. 2024.

MLA

Martinez Peñaloza, A., C. Duarte, y G. Osma Pinto. «Impact of the simultaneous integration of DER, DR, and BES strategies in a distribution network». Simposio Internacional sobre la Calidad de la Energía Eléctrica - SICEL, vol. 11, enero de 2024, doi:10.15446/sicel.v11.109987.

Turabian

Martinez Peñaloza, Alejandra, César Duarte, y German Osma Pinto. «Impact of the simultaneous integration of DER, DR, and BES strategies in a distribution network». Simposio Internacional sobre la Calidad de la Energía Eléctrica - SICEL 11 (enero 30, 2024). Accedido febrero 8, 2025. https://revistas.unal.edu.co/index.php/SICEL/article/view/109987.

Vancouver

1.
Martinez Peñaloza A, Duarte C, Osma Pinto G. Impact of the simultaneous integration of DER, DR, and BES strategies in a distribution network. SICEL [Internet]. 30 de enero de 2024 [citado 8 de febrero de 2025];11. Disponible en: https://revistas.unal.edu.co/index.php/SICEL/article/view/109987

Descargar cita

CrossRef Cited-by

CrossRef citations0

Dimensions

PlumX

Visitas a la página del resumen del artículo

118

Descargas

Los datos de descargas todavía no están disponibles.