Study for the application of renewable energy in the Empresa Provincial de Alimentos de Matanzas
Article Sidebar
Keywords:
Renewable energy, environment
Main Article Content
Abstract
It is carried out an integral study of the most comprehensive possibilities for the application of the renewable sources of energy in the Empresa Provincial de Alimentos de Matanzas. Where intends to take advantage their roofs for the installation of photovoltaic panels, also to substitute their system of pumping for photovoltaic pumps.
All this not alone and will allow to be supplied energy by means of the renewable sources at your disposal, also will also have the possibility of a surplus that can allow at one time the recovery of the investment prudential.
Downloads
Download data is not yet available.
Article Details
How to Cite
Sánchez Ávila, J. L., Orama Ortega, M., Díaz Matos, J. R., & González Ramírez, Y. O. (1). Study for the application of renewable energy in the Empresa Provincial de Alimentos de Matanzas. Eco Solar, (79), 36-44. Retrieved from http://ecosolar.cubaenergia.cu/index.php/ecosolar/article/view/96
Section
Artículo original
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
References
ANDRADE CEDEÑO Y ROGGER JOSÉ (2018), Gestión Energética de una Estación de Bombeo mediante el uso del Control Estadístico de Procesos. Estudio de Caso: Acueducto La Esperanza- Refinería del Pacífico, Revista Politécnica - enero 2018, Vol. 40, No. 2.
ATALLA T. et al (2017). A global degree days database for energy-related applications, Energy 143 (2018) 1048-1055, https://doi.org/10.1016/j.energy.2017.10.134.
BINITA K.C. Y R. MATTHIAS (2017). Estimation and projection of institutional building electricity consumption, Energy and Buildings 143 (2017) 43-52, http://dx.doi.org/10.1016/j.enbuild.2017.03.034.
CHEN, Y., TAN, H., & BERARDI, U. (2017). Day-ahead prediction of hourly electric demand in non-stationary operated commercial buildings: A clustering-based hybrid approach. Energy and Buildings, 148, 228-237.
CUNHA, F. O., & OLIVEIRA, A. C. (2020). Benchmarking for realistic nZEB hotel buildings. Journal of Building Engineering, 30, 101298.
GEET (2014). Exergy Analysis for 120 mw Thermal Power Plant with Different InletTemperature Conditions: International Journal of Research in Engineering&Technology. Volumen.2, pp.21-30.
IDEA, INSTITUTO PARA LA DIVERSIFICACIÓN Y AHORRO DE LA ENERGÍA (2019). Instalaciones de Energía Solar Térmica. Pliego de Condiciones Técnicas de Instalaciones de Baja Temperatura. PET-REV-enero 2019. Disponible en Internet: http:// www.idae.es
IRENA (2021). World Energy Transitions Outlook: 1.5°C Pathway, International Renewable Energy Agency, Abu Dhabi.
JÁCOME, E. A.; L. S. OROZCO et al. (2017). Implementation of energy management system in the hotel industry. Dom. Cien, 2017, 3: 321-340.
L.A. PACE / Journal of Cleaner Production 111 (2016) 409-420
ROSHAN GH. R., A. A. GHANGHERMEH AND S. ATTIA (2017). Determining new threshold temperatures for cooling and heating degree day index of different climatic zones of Iran, Renewable Energy 101 (2017) 156-167.
SÁNCHEZ ÁVILA, J. L. (1999). Desarrollo y aplicación del diagnóstico y pronóstico técnico al mantenimiento de los sistemas centralizados de aire acondicionado. Tesis de Doctorado. Universidad de Matanzas, 129 Páginas, 1999.
SHAFIQ, UMAR (2015). Thermodynamic Analysis of Natural Gas Based Furnace /BoilerIntegrated with Steam Power Plant theoretical Approach. (ISSN 2231-606x), Volumen 5 (12).
WU, J., LIAN, Z., ZHENG, Z., & ZHANG, H. (2020). A method to evaluate building energy consumption based on energy use index of different functional sectors. Sustainable Cities and Society, 53, 101893.
ATALLA T. et al (2017). A global degree days database for energy-related applications, Energy 143 (2018) 1048-1055, https://doi.org/10.1016/j.energy.2017.10.134.
BINITA K.C. Y R. MATTHIAS (2017). Estimation and projection of institutional building electricity consumption, Energy and Buildings 143 (2017) 43-52, http://dx.doi.org/10.1016/j.enbuild.2017.03.034.
CHEN, Y., TAN, H., & BERARDI, U. (2017). Day-ahead prediction of hourly electric demand in non-stationary operated commercial buildings: A clustering-based hybrid approach. Energy and Buildings, 148, 228-237.
CUNHA, F. O., & OLIVEIRA, A. C. (2020). Benchmarking for realistic nZEB hotel buildings. Journal of Building Engineering, 30, 101298.
GEET (2014). Exergy Analysis for 120 mw Thermal Power Plant with Different InletTemperature Conditions: International Journal of Research in Engineering&Technology. Volumen.2, pp.21-30.
IDEA, INSTITUTO PARA LA DIVERSIFICACIÓN Y AHORRO DE LA ENERGÍA (2019). Instalaciones de Energía Solar Térmica. Pliego de Condiciones Técnicas de Instalaciones de Baja Temperatura. PET-REV-enero 2019. Disponible en Internet: http:// www.idae.es
IRENA (2021). World Energy Transitions Outlook: 1.5°C Pathway, International Renewable Energy Agency, Abu Dhabi.
JÁCOME, E. A.; L. S. OROZCO et al. (2017). Implementation of energy management system in the hotel industry. Dom. Cien, 2017, 3: 321-340.
L.A. PACE / Journal of Cleaner Production 111 (2016) 409-420
ROSHAN GH. R., A. A. GHANGHERMEH AND S. ATTIA (2017). Determining new threshold temperatures for cooling and heating degree day index of different climatic zones of Iran, Renewable Energy 101 (2017) 156-167.
SÁNCHEZ ÁVILA, J. L. (1999). Desarrollo y aplicación del diagnóstico y pronóstico técnico al mantenimiento de los sistemas centralizados de aire acondicionado. Tesis de Doctorado. Universidad de Matanzas, 129 Páginas, 1999.
SHAFIQ, UMAR (2015). Thermodynamic Analysis of Natural Gas Based Furnace /BoilerIntegrated with Steam Power Plant theoretical Approach. (ISSN 2231-606x), Volumen 5 (12).
WU, J., LIAN, Z., ZHENG, Z., & ZHANG, H. (2020). A method to evaluate building energy consumption based on energy use index of different functional sectors. Sustainable Cities and Society, 53, 101893.