Frontiers in Management Research
Analysis of Biomass-fired Boilers in a Polygeneration System for a Hospital
Download PDF (460.3 KB) PP. 1 - 13 Pub. Date: January 20, 2018
Author(s)
- Danielle Bandeira de Mello Delgado
Graduate Program in Renewable Energy, Center of Alternative and Renewable Engineering, Federal University of Paraíba. Cx Postal 5115, Cidade Universitária, João Pessoa, Paraíba, 58059-900, Brazil. - Monica Carvalho*
Graduate Program in Renewable Energy, Center of Alternative and Renewable Engineering, Federal University of Paraíba. Cx Postal 5115, Cidade Universitária, João Pessoa, Paraíba, 58059-900, Brazil. - Luiz Moreira Coelho Junior
Graduate Program in Renewable Energy, Center of Alternative and Renewable Engineering, Federal University of Paraíba. Cx Postal 5115, Cidade Universitária, João Pessoa, Paraíba, 58059-900, Brazil. - Ricardo Chacartegui
Energy Engineering Department, University of Seville, Camino de los Descubrimientos s/n, 41092, Seville, Spain.
Abstract
Keywords
References
[1] R. H. Williams et al., "Advanced energy supply technologies", World energy assessment: energy and the challenge of sustainability, pp. 273-329, 2000.
[2] L. M. Serra et al., “Polygeneration and efficient use of natural resources”, Energy, 34, pp. 575-586, 2009.
[3] Y. Chen, T. A. Adams, and P. I. Barton, "Optimal design and operation of flexible energy polygeneration systems", Industrial & Engineering Chemistry Research, 50.8, pp. 4553-4566, 2011.
[4] Y. E. Yuksel, and M. Ozturk, "Thermodynamic Modeling of an Integrated Energy System for Poly-generation Design." Progress in Clean Energy, Vol. 1, Springer International Publishing, pp. 21-39, 2015.
[5] A. Rong, and R. Lahdelma, "Role of polygeneration in sustainable energy system development challenges and opportunities from optimization viewpoints," Renewable and Sustainable Energy Reviews, vol. 53, pp. 363-372, 2016.
[6] S. Murugan, and B. Horák, "Tri and polygeneration systems-A review," Renewable and Sustainable Energy Reviews, vol.60, pp 1032-1051, 2016.
[7] P. Liu, E. N. Pistikopoulos, and Z. Li, "An energy systems engineering approach to the optimal design of energy systems in commercial buildings", Energy Policy 8.8, pp. 4224-4231, 2010.
[8] C. Rubio-Maya, J. Uche, and J. Pacheco-Ibarra, "Feasibility analysis of a combined cooling-heatingpower and desalted water plant for a non-residential building" Int. J. Energy Environ. Eng, 2, pp. 33-41, 2011.
[9] C. Rubio-Maya et al., "Design optimization of a polygeneration plant fuelled by natural gas and renewable energy sources", Applied Energy, 88.2, pp. 449-457, 2011.
[10] G. Kyriakarakos, and G. Papadakis, "Polygeneration Microgrids for Residential Applications", Handbook of Clean Energy Systems, 2015.
[11] P. Kazempoor, V. Dorer, and F. Ommi, "Modelling and Performance Evaluation of Solid Oxide Fuel Cell for Building Integrated Co-and Polygeneration", Fuel Cells 10.6, pp. 1074-1094, 2010.
[12] A. Piacentino, and F. Cardona. "An original multi-objective criterion for the design of small-scale polygeneration systems based on realistic operating conditions", Applied thermal engineering, 28.17, pp. 2391-2404, 2008.
[13] U. Sahoo et al., "Scope and sustainability of hybrid solar–biomass power plant with cooling, desalination in polygeneration process in India", Renewable and Sustainable Energy Reviews, 51, pp. 304-316, 2015.
[14] D. Ziher, A. Poredos, “Economics of a trigeneration system in a hospital”, Applied Thermal Engineering, vol.7, pp.680-687, 2006.
[15] P. Arcuri, G. Florio, and P. Fragiacomo, “A mixed integer programming model for optimal design of trigeneration in a hospital complex”, Energy, 32 (8), pp.1430-1447, 2007.
[16] M. A. Lozano et al., “Structure optimization of energy supply systems in tertiary sector buildings”, Energy and Buildings, 41 (10), pp.1063-1075, 2009.
[17] A. Romero, M. Carvalho, D. L. Millar, “Application of a polygeneration optimization technique for a hospital in Northern Ontario”, Transactions of the Canadian Society of Mechanical Engineering, vol.1, 2014.
[18] A. Romero, M. Carvalho, D. L. Millar, “Biomass and solar thermal energy in the synthesis and optimization of a polygeneration system”. In: V Congresso Brasileiro De Energia Solar, 2014.
[19] M. Carvalho, R. Charcategui, L. M. Coelho Junior, D. B. M. Delgado, “Optimization of Energy Supply and Conversion in a Northeast Brazil Hospital: Use of photovoltaic panels”. In: 23rd ABCM International Congress Of Mechanical Engineering, 2015.
[20] Z. Shang, A. Kokossis, “A systematic approach to the synthesis and design of flexible utility systems”, Chemical Engineering Science, 60, pp. 4431-4451, 2005.
[21] Brazilian Agency of Electricity (ANEEL). Brazilian Electricity Atlas. Chapter 5: availability of resources and consumption of biomass. Available at: http://www2.aneel.gov.br/aplicacoes/atlas/biomassa/5_2.htm
[22] Asian Productivity Organization. Biomass as Fuel in Small Boilers. Tokyo: APO, 2009.
[23] E. S. Lora, and R. V. Andrade, "Biomass as energy source in Brazil", Renewable and Sustainable Energy Reviews 13.4, pp. 777-788, 2009.
[24] P. Anselmo Filho, and O. Badr, "Biomass resources for energy in North-Eastern Brazil", Applied Energy, 77.1, pp. 51-67, 2004.
[25] L. Rosendahl, “Biomass combustion science, technology and engineering,” Elsevier, 2013.
[26] S. V. Vassilev, C. G. Vassileva, and V. S. Vassilev, "Advantages and disadvantages of composition and properties of biomass in comparison with coal: an overview", Fuel, 158, pp. 330-350, 2015.
[27] R. Saidur et al., "A review on biomass as a fuel for boilers", Renewable and sustainable energy reviews, 15.5, pp.2262-2289, 2011.
[28] E. Thiffault et al., “Mobilisation of forest bioenergy in the boreal and temperate biomes: Challenges, opportunities and case studies”, Academic Press, 2016.
[29] S. Fujii et al., "Material and heat flow analysis in thermal energy storage and transport system utilizing unused heat from bagasse boiler", Mechanical Engineering Journal, 3.5,16-00334, 2016.
[30] E. F. Cortes-Rodríguez, S. A. Nebra, and J. H. Sosa-Arnao, "Experimental efficiency analysis of sugarcane bagasse boilers based on the first law of thermodynamics", Journal of the Brazilian Society of Mechanical Sciences and Engineering, 39.3, pp.1033-1044, 2017.
[31] L. E. Rincón et al., "Techno-economic analysis of the use of fired cogeneration systems based on sugar cane bagasse in south eastern and mid-western regions of Mexico", Waste and biomass valorization, 5.2, pp. 189-198, 2014.
[32] M. H. Rocha et al. "Life cycle assessment (LCA) for biofuels in Brazilian conditions: a meta-analysis", Renewable and Sustainable Energy Reviews, 37, pp. 435-459, 2014.
[33] D. A. L. Silva et al., "Life cycle assessment of the sugarcane bagasse electricity generation in Brazil", Renewable and Sustainable Energy Reviews, 32, pp. 532-547, 2014.
[34] A. N. N. A. Majchrzycka, "Comparative analysis of individual house heating system based on electricity and combustion of alternative and fossil fuels", Wind energy, 10.53, 6-07, 2016.
[35] J. D. Stephen et al., "Biomass for residential and commercial heating in a remote Canadian aboriginal community", Renewable Energy 86 (2016): 563-575.
[36] L. Paolotti et al., "Economic and environmental assessment of agro-energy wood biomass supply chains", Biomass and Bioenergy, 97, pp. 172-185, 2017.
[37] I. Obernberger, and G. Thek, "The pellet handbook", Earthscan Ltd, 2010.
[38] B. Monteleone et al., "Life cycle analysis of small scale pellet boilers characterized by high efficiency and low emissions", Applied Energy, 155, pp. 160-170, 2015.
[39] L. Carvalho et al., "Performance of a pellet boiler fired with agricultural fuels", Applied energy, 104, pp. 286-296, 2013.
[40] A. ?andeckis et al., "Solar and pellet combisystem for apartment buildings: Heat losses and efficiency improvements of the pellet boiler", Applied energy, 101, pp. 244-252, 2013.
[41] J. G. Sanz-Calcedo et al., "Efficiency of a biomass boiler in a hospital center. Use of olive crushing stones to produce heat", DYNA 86.3 (2011): 343-349.
[42] Hamworthy. Whitchurch Community Hospital case study. 2017. Available at: https://www.hamworthyheating.com/case-studies/hospital-boilers/whitchurch-community-hospital-case-study
[43] Uniconfort. Two Hospitals Choose Solid Biomass Boilers To Heat The Premises. Available at: https://www.uniconfort.com/en/references/biomass-in-the-hospital.html.
[44] US Department of Energy. Oregon Hospital Heats Up with a Biomass Boiler. Available at: https://energy.gov/articles/oregon-hospital-heats-biomass-boiler
[45] M. Daskalakis and V. Iyer, “Finding energy savings with a biomass boiler: biomass boiler saves hospital money, energy”, Heating/Piping/Air Conditioning Engineering, 81.6, 2009.
[46] R. P. Francisco, "Estudo termoquímico da queima de combustíveis em caldeiras usando balan?os de energia", MSc. dissertation, Universidade Federal de S?o Jo?o Del-Rei, 2012. [In Portuguese].
[47] Globo.Com. Hospital saves R$ 6,3 million with energy from donated sugarcane bagasse. Available at: http://g1.globo.com/sp/ribeirao-preto-franca/noticia/2015/10/hospital-economiza-r-63-milhoes-com-energia-debagaco-de-cana-doada.html [In Portuguese].
[48] EBSERH, Brazilian Company of Hospital Services. Lauro Wanderley University Hospital/UFPB: Design of assistance services and management of teaching and research. Available at: http://www.ebserh.mec.gov.br/ images/pdf/contratos_adesao_huf/ufpb/dimensionamento_de_servicos_hulw_ufpb.pdf> [In Portuguese].
[49] D. G. Erbs, S. A. Klein, and W. A. Beckman, “Estimation of degree-days and ambient temperature bin data from monthly-average temperatures”, ASHARE Journal, 25 (6), pp. 60-65, 1983.
[50] CLIMATICUS 4.2. Climate Data Base. Design strategies for 58 Brazilian cities. INMET 1961-1990 Database. Beta Version. Faculty of Architecture and Urbanism of the S?o Paulo University - Department of Technology - Laboratory of environmental comfort and energy efficiency, Available at: www.fau.usp.br/pesquisa/laboratorios/ labaut/conforto/Climaticus_2011(beta).xlsm
[51] M. H. A. Nepote, I. U. Monteiro, E. Hardy, “Association between operational indices and occupation rates of a general surgery center”, Rev. Latino-Am. Enfermagem [online], 17 (4), 2009.
[52] M. M. D. Araújo, “Methodological contribution for the exergy diagnosis of thermal and electrical systems - study case at the Lauro Wanderley University Hospital” M.Sc. dissertation in Mechanical Engineering, Department of Mechanical Engineering, Federal University of Paraíba, 2004. [In Portuguese].
[53] Energisa. Energisa Paraíba, Available at: http://www.energisa.com.br/Paginas/informacoes/taxas-prazos-enormas/tipos-tarifas.aspx [In Portuguese].
[54] PBGáS, Gas Company of Paraíba. Tariffs. Available at: http://www.pbgas.com.br/?page_id=1477. [In Portuguese].
[55] Nova Cana, Sugar and Ethanol companies in the state of Paraíba. Available: http://www.novacana.com/usinasbrasil/nordeste/paraiba/ [In Portuguese].
[56] I. E. Grossmann, J. A. Caballero, and H. Yeomans, “Advances in mathematical programming for the synthesis of process systems” Latin American Applied Research;30(4), pp. 263–284,2000.
[57] MULTINOX, MULTINOX Of Brasil. Available at: http://www.multinoxdobrasil.com/caldeiras.html [In Portuguese].
[58] Brasil, EPE, Energy Research Company. National Energy Balance, 2014. Available at: https://ben.epe.gov.br/downloads/Relatorio_Final_BEN_2014.pdf [In Portuguese].
[59] Op??o Verde. Biomass consultancy. Available at: http://www.opcaoverde.com.br/biomassa [In Portuguese].
[60] SOS SERT?O, “Business Plan of the Malhada Association”, p.39, 2014.
[61] MFRURAL. Agribusiness starts here. Available: http://www.mfrural.com.br/busca.aspx?palavras=bagaco+cana [In Portuguese].
[62] ENVALMA, Technical report. Available at: http://www.envalma.com/wa_files/Nota_20T_C3_A9cnica_203Metros_20Cubicos_20x_20Metro_20Estereo.pdf [In Portuguese].
[63] J. L. P. Rezende, A. D. Oliveira, “Economic and Social analyses of forestry projects”, MSc. dissertation, Federal University of Vi?osa, 2001.
[64] Pellet Nordeste. Available: http://www.pelletsnordeste.com/?page_id=53&lang=pt-br [In Portuguese].
[65] J. C. A. Dornelas. “Entrepreneurship: transforming ideas in businesses,” Elsevier, 2012.
[66] M. Carvalho, M. A. Lozano, and L. M. Serra, "Multicriteria synthesis of trigeneration systems considering economic and environmental aspects", Applied Energy, 91.1, pp. 245-254, 2012.
[67] M. Carvalho, L. M. Serra, and M. A. Lozano, "Optimal synthesis of trigeneration systems subject to environmental constraints", Energy 36.6 (2011): 3779-3790.
[68] M. Carvalho, D. B. M. Delgado, "Potential of photovoltaic solar energy to reduce the carbon footprint of the Brazilian electricity matrix ", Revista Latino Americana de Avalia??o do Ciclo de Vida – LALCA, vol. 1, n.1, pp.64-85, 2017.
[69] Ecoinvent database. Available at: http://www.ecoinvent.ch
[70] Simapro software. Available at: http://www.simapro.nl
[71] IPCC. 2014. 2013 Revised Supplementary Methods and Good Practice Guidance Arising from the Kyoto Protocol. Available at: http://www.ipcc-nggip.iges.or.jp/public/kpsg/
[72] D. B. M. Delgado, M. Carvalho, R. Chacartegui, L. M. Coelho Junior, “Optimization of energy supply and conversion in a northeast Brazil hospital: use of photovoltaic panels” In: 23rd ABCM Internationa Congress of Mechanical Engineering, 2015.