Application of equivalent occupation method as a tool for energy management in hotel sector

At nowadays, the operational control of energy performance indicators based on the equivalent occupation method plays a fundamental role in the rational use of energy for the hotel sector, since it allows in a competitive way to comply with the quality of the service offered by the company in terms...

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Autores:: Valencia Ochoa, Guillermo Eliecer
Cardenas Escorcia, Yulineth del Carmen
Meriño, Lourdes

Tipo de recurso:: Article of journal

Fecha de publicación:: 2018

Institución:: Corporación Universidad de la Costa

Repositorio:: REDICUC - Repositorio CUC

Idioma:: eng

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repository_id_str
dc.title.eng.fl_str_mv	Application of equivalent occupation method as a tool for energy management in hotel sector
title	Application of equivalent occupation method as a tool for energy management in hotel sector
spellingShingle	Application of equivalent occupation method as a tool for energy management in hotel sector Energy management ISO 500001 Energy performance indicators
title_short	Application of equivalent occupation method as a tool for energy management in hotel sector
title_full	Application of equivalent occupation method as a tool for energy management in hotel sector
title_fullStr	Application of equivalent occupation method as a tool for energy management in hotel sector
title_full_unstemmed	Application of equivalent occupation method as a tool for energy management in hotel sector
title_sort	Application of equivalent occupation method as a tool for energy management in hotel sector
dc.creator.fl_str_mv	Valencia Ochoa, Guillermo Eliecer Cardenas Escorcia, Yulineth del Carmen Meriño, Lourdes
dc.contributor.author.spa.fl_str_mv	Valencia Ochoa, Guillermo Eliecer Cardenas Escorcia, Yulineth del Carmen Meriño, Lourdes
dc.subject.eng.fl_str_mv	Energy management ISO 500001 Energy performance indicators
topic	Energy management ISO 500001 Energy performance indicators
description	At nowadays, the operational control of energy performance indicators based on the equivalent occupation method plays a fundamental role in the rational use of energy for the hotel sector, since it allows in a competitive way to comply with the quality of the service offered by the company in terms of the thermal comfort of the occupants, minimizing the environmental impact. Within the framework of the energy diagnosis and implementation of the program of efficient energy management under ISO 50001: 2011, based on the method of equivalent occupation for a hotel company on the Colombian Caribbean coast, the line base, target line by 2015, determining performance control indicators such as accumulative trend and base efficiency index 100, to identify potential savings. From the diagnosis, 9.11% of energy savings were obtained by operational control. Through the implementation of corrective action plans, such as the shutdown of unnecessary equipment in the company, installation of LED lighting modules, the configuration of thermostats, in addition to training and sensitization to staff, and reactive energy control in the hotel effective savings were achieved around 8% of primary energy consumption by 2016.
publishDate	2018
dc.date.accessioned.none.fl_str_mv	2018-11-20T14:37:17Z
dc.date.available.none.fl_str_mv	2018-11-20T14:37:17Z
dc.date.issued.none.fl_str_mv	2018
dc.type.spa.fl_str_mv	Artículo de revista
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dc.identifier.instname.spa.fl_str_mv	Corporación Universidad de la Costa
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identifier_str_mv	2146-4553 Corporación Universidad de la Costa REDICUC - Repositorio CUC
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dc.language.iso.none.fl_str_mv	eng
language	eng
dc.relation.references.spa.fl_str_mv	Aguiar, P.R. (2005), Chapter 5: Residential and Commercial Air Conditioning and Heating. IPCC/TEAP Special Report: Safeguarding the Ozone Layer and the Global Climate System. p269-294. AlFaris, F., Adel, J., Francisco, M. (2017), Intelligent homes’ technologies to optimize the energy performance for the net zero energy home. Energy and Buildings, 153, 262-274. Anon. (2016), Annual Energy Outlook 2016. Energy Information Administration. ASHRAE. (1997), Nonresidential Cooling and Heating Load Calculation Procedures. Atlanta, Georgia: Handbook Editor. Ashrafi, A., Hsin, V.S., Lai, S.L., Chew, G.L. (2013), The efficiency of the hotel industry in Singapore. Tourism Management, 37, 31-34. Assaf, A.G., Vincent, M. (2012), Accounting for customer satisfaction in measuring hotel efficiency: Evidence from the us hotel industry. International Journal of Hospitality Management, 31(3), 642-647. Bianco, V., Daniele, R., Federico, S., Luca, A.T. (2017), Modeling energy consumption and efficiency measures in the Italian hotel sector. Energy and Buildings, 149, 329-338. Bodach, S., Werner, L., Thomas, A. (2016), Design guidelines for energyefficient hotels in Nepal. International Journal of Sustainable Built Environment, 5(2), 411-434. Chedwal, R., Jyotirmay, M., Ghanshyam, D.A., Shivraj, D. (2015), Energy saving potential through energy conservation building code and advance energy efficiency measures in hotel buildings of Jaipur City, India. Energy and Buildings, 92, 282-295. Deb, C., Fan, Z., Junjing, Y., Siew, E.L., Kwok, W.S. (2017), A review on time series forecasting techniques for building energy consumption. Renewable and Sustainable Energy Reviews, 74, 902-924. Escorcia, Y.C., Guillermo, V.O., Lourdes, M.S. (2017), Application of an energy management system to develop an energy planning in a pickling line. Contemporary Engineering Science, 10(20), 785-784. Fahad, M., Syed, A.A.N., Muhammad, A., Muhammad, Z., Muhammad,M.S. (2017), Energy management in a manufacturing industry through layout design. Procedia Manufacturing, 8, 168-174. Fleiter, T., Hirzel, S., Worrell, E. (2012), The characteristics of energyefficiency measures e a neglected dimension. Energy policy, 51, 105. Gonzales, S. (2015), Sistema de Regulación Automático Para Controlar El Índice de Confort En Ambientes Climatizados. González, J.P., Charles, Y. (2015), Prioritising energy efficiency measures to achieve a zero net-energy hotel on the Island of Gozo in the central mediterranean. Energy Procedia, 83, 50-59. Idahosa, L.O., Nyankomo, N.M., Joseph, O.A. (2017), Energy (Electricity) consumption in South African hotels: A panel data analysis. Energy and Buildings, 156, 207-217. Kresteniti, A. (2017), Science direct development of a concept for energy optimization of existing greek hotel buildings. Procedia Environmental Sciences, 38, 290-297. Malys, L., Marjorie, M., Christian, I. (2016), Direct and indirect impacts of vegetation on building comfort: A comparative study of lawns, greenwalls and green roofs. Energies, 9(1), 603-610. May, G., Ilaria, B., Bojan, S., Marco, T. (2015), Energy management in production: A novel method to develop key performance indicators for improving energy efficiency. Applied Energy, 149, 46-61. Meschede, H., Heiko, D., Fabian, S., Ron-Hendrik, P., Jens, H. (2017), Assessment of probabilistic distributed factors influencing renewable energy supply for hotels using monte-carlo methods. Energy, 128, 86-100. Oluseyi, P.O., Babatunde, O.M., Babatunde, O.A. (2016), Assessment of energy consumption and carbon footprint from the hotel sector within Lagos, Nigeria. Energy and Buildings, 118, 106-113. Pinto, A., Armando, S.A., António, S.S., Carla, P.R., Fernanda, R. (2017), Nexus water energy for hotel sector efficiency. Energy Procedia, 111, 215-225. Sucic, B., Fouad, A.M., Matevz, P., Tomaz, V. (2015), Context sensitive production planning and energy management approach in energy intensive industries. Energy, 108, 1-11. Tang, C., Linsheng, Z., Pin, N. (2017), Factors that influence the tourism industry’s carbon emissions: A tourism area life cycle model perspective. Energy Policy, 109, 704-718. Thumann, A., William, Y. (2015), 33 Procedia Engineering Energy Audit of an Industrial Site: A Case Study. Valencia, G.E., Yulineth, C., Erni, S.R., Alexis, M., Juan, C.C. (2017), Energy saving in industrial process based on the equivalent production method to calculate energy performance indicators. Chemical Engineering Transactions, 57, 709-714. Vujošević, M., Aleksandra, K.F. (2017), The influence of atrium on energy performance of hotel building. Energy and Buildings, 156, 140-150. Yang, Z., Lan, X., Zhe, C. (2017), Performance of Chinese hotel segment markets: Efficiencies measure based on both endogenous and exogenous factors. Journal of Hospitality and Tourism Management, 32, 12-23. Yao, Z., Zhi, Z., Wen, G. (2015), Study on energy use characteristics of hotel buildings in Shanghai. Procedia Engineering, 121, 1977-1982. Yun, G.Y., Jeong, T.K. (2014), Creating sustainable building through exploiting human comfort. Energy Procedia, 62, 590-594.
dc.rights.spa.fl_str_mv	Atribución – No comercial – Compartir igual
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dc.publisher.spa.fl_str_mv	International Journal of Energy Economics and Policy
institution	Corporación Universidad de la Costa
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spelling	Valencia Ochoa, Guillermo Eliecerf48e278e72fed2f5937be19a6c38767eCardenas Escorcia, Yulineth del Carmen03fd6a99d8c63fdc544119cb52765c40Meriño, Lourdesfb131f692a4504a9bf48e4c7968c002e2018-11-20T14:37:17Z2018-11-20T14:37:17Z20182146-4553http://hdl.handle.net/11323/1411Corporación Universidad de la CostaREDICUC - Repositorio CUChttps://repositorio.cuc.edu.co/At nowadays, the operational control of energy performance indicators based on the equivalent occupation method plays a fundamental role in the rational use of energy for the hotel sector, since it allows in a competitive way to comply with the quality of the service offered by the company in terms of the thermal comfort of the occupants, minimizing the environmental impact. Within the framework of the energy diagnosis and implementation of the program of efficient energy management under ISO 50001: 2011, based on the method of equivalent occupation for a hotel company on the Colombian Caribbean coast, the line base, target line by 2015, determining performance control indicators such as accumulative trend and base efficiency index 100, to identify potential savings. From the diagnosis, 9.11% of energy savings were obtained by operational control. Through the implementation of corrective action plans, such as the shutdown of unnecessary equipment in the company, installation of LED lighting modules, the configuration of thermostats, in addition to training and sensitization to staff, and reactive energy control in the hotel effective savings were achieved around 8% of primary energy consumption by 2016.engInternational Journal of Energy Economics and PolicyAtribución – No comercial – Compartir igualinfo:eu-repo/semantics/openAccesshttp://purl.org/coar/access_right/c_abf2Energy managementISO 500001Energy performance indicatorsApplication of equivalent occupation method as a tool for energy management in hotel sectorArtículo de revistahttp://purl.org/coar/resource_type/c_6501http://purl.org/coar/resource_type/c_2df8fbb1Textinfo:eu-repo/semantics/articlehttp://purl.org/redcol/resource_type/ARTinfo:eu-repo/semantics/acceptedVersionAguiar, P.R. (2005), Chapter 5: Residential and Commercial Air Conditioning and Heating. IPCC/TEAP Special Report: Safeguarding the Ozone Layer and the Global Climate System. p269-294. AlFaris, F., Adel, J., Francisco, M. (2017), Intelligent homes’ technologies to optimize the energy performance for the net zero energy home. Energy and Buildings, 153, 262-274. Anon. (2016), Annual Energy Outlook 2016. Energy Information Administration. ASHRAE. (1997), Nonresidential Cooling and Heating Load Calculation Procedures. Atlanta, Georgia: Handbook Editor. Ashrafi, A., Hsin, V.S., Lai, S.L., Chew, G.L. (2013), The efficiency of the hotel industry in Singapore. Tourism Management, 37, 31-34. Assaf, A.G., Vincent, M. (2012), Accounting for customer satisfaction in measuring hotel efficiency: Evidence from the us hotel industry. International Journal of Hospitality Management, 31(3), 642-647. Bianco, V., Daniele, R., Federico, S., Luca, A.T. (2017), Modeling energy consumption and efficiency measures in the Italian hotel sector. Energy and Buildings, 149, 329-338. Bodach, S., Werner, L., Thomas, A. (2016), Design guidelines for energyefficient hotels in Nepal. International Journal of Sustainable Built Environment, 5(2), 411-434. Chedwal, R., Jyotirmay, M., Ghanshyam, D.A., Shivraj, D. (2015), Energy saving potential through energy conservation building code and advance energy efficiency measures in hotel buildings of Jaipur City, India. Energy and Buildings, 92, 282-295. Deb, C., Fan, Z., Junjing, Y., Siew, E.L., Kwok, W.S. (2017), A review on time series forecasting techniques for building energy consumption. Renewable and Sustainable Energy Reviews, 74, 902-924. Escorcia, Y.C., Guillermo, V.O., Lourdes, M.S. (2017), Application of an energy management system to develop an energy planning in a pickling line. Contemporary Engineering Science, 10(20), 785-784. Fahad, M., Syed, A.A.N., Muhammad, A., Muhammad, Z., Muhammad,M.S. (2017), Energy management in a manufacturing industry through layout design. Procedia Manufacturing, 8, 168-174. Fleiter, T., Hirzel, S., Worrell, E. (2012), The characteristics of energyefficiency measures e a neglected dimension. Energy policy, 51, 105. Gonzales, S. (2015), Sistema de Regulación Automático Para Controlar El Índice de Confort En Ambientes Climatizados. González, J.P., Charles, Y. (2015), Prioritising energy efficiency measures to achieve a zero net-energy hotel on the Island of Gozo in the central mediterranean. Energy Procedia, 83, 50-59. Idahosa, L.O., Nyankomo, N.M., Joseph, O.A. (2017), Energy (Electricity) consumption in South African hotels: A panel data analysis. Energy and Buildings, 156, 207-217. Kresteniti, A. (2017), Science direct development of a concept for energy optimization of existing greek hotel buildings. Procedia Environmental Sciences, 38, 290-297. Malys, L., Marjorie, M., Christian, I. (2016), Direct and indirect impacts of vegetation on building comfort: A comparative study of lawns, greenwalls and green roofs. Energies, 9(1), 603-610. May, G., Ilaria, B., Bojan, S., Marco, T. (2015), Energy management in production: A novel method to develop key performance indicators for improving energy efficiency. Applied Energy, 149, 46-61. Meschede, H., Heiko, D., Fabian, S., Ron-Hendrik, P., Jens, H. (2017), Assessment of probabilistic distributed factors influencing renewable energy supply for hotels using monte-carlo methods. Energy, 128, 86-100. Oluseyi, P.O., Babatunde, O.M., Babatunde, O.A. (2016), Assessment of energy consumption and carbon footprint from the hotel sector within Lagos, Nigeria. Energy and Buildings, 118, 106-113. Pinto, A., Armando, S.A., António, S.S., Carla, P.R., Fernanda, R. (2017), Nexus water energy for hotel sector efficiency. Energy Procedia, 111, 215-225. Sucic, B., Fouad, A.M., Matevz, P., Tomaz, V. (2015), Context sensitive production planning and energy management approach in energy intensive industries. Energy, 108, 1-11. Tang, C., Linsheng, Z., Pin, N. (2017), Factors that influence the tourism industry’s carbon emissions: A tourism area life cycle model perspective. Energy Policy, 109, 704-718. Thumann, A., William, Y. (2015), 33 Procedia Engineering Energy Audit of an Industrial Site: A Case Study. Valencia, G.E., Yulineth, C., Erni, S.R., Alexis, M., Juan, C.C. (2017), Energy saving in industrial process based on the equivalent production method to calculate energy performance indicators. Chemical Engineering Transactions, 57, 709-714. Vujošević, M., Aleksandra, K.F. (2017), The influence of atrium on energy performance of hotel building. Energy and Buildings, 156, 140-150. Yang, Z., Lan, X., Zhe, C. (2017), Performance of Chinese hotel segment markets: Efficiencies measure based on both endogenous and exogenous factors. Journal of Hospitality and Tourism Management, 32, 12-23. Yao, Z., Zhi, Z., Wen, G. (2015), Study on energy use characteristics of hotel buildings in Shanghai. Procedia Engineering, 121, 1977-1982. Yun, G.Y., Jeong, T.K. (2014), Creating sustainable building through exploiting human comfort. 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Application of equivalent occupation method as a tool for energy management in hotel sector

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