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HEAT RECOVERY SYSTEM IN AN INDUSTRIAL FURNACE TO GENERATE AIR CONDITIONING THROUGH AN ABSORPTION CHILLER

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Resumen


A case study of a Heat Recovery System is performed in an industrial furnace that uses natural gas to determine the absorption cooling capacity (LiBr – Water) that can be generated for air conditioning. The energy source will be the heat of the flue gas that is eliminated by the furnace stack. Thermodynamic and economic analysis of the entire system (heat recovery exchanger, absorption chiller, cooling tower, etc.) is performed. A methodology to evaluate the Heat Recovery potential of the industrial furnace will be shown, as well as the limitations that must be considered. This methodology also considers the favorable environmental impact that is available to perform a heat recovery project. The results show that under certain operational characteristics and conditions, the heat recovery system is technically and economically feasible (profitable).

Principles of Finned-Tube Heat Exchanger Design for Enhanced Heat Transfer - 2nd Edition by Dipl.-Ing. Friedrich Frass Translated and Edited by Dipl.-Ing. Kohler Manual # TP-6107 Kohler Service Parts Manual Industrial Residential Commercial Engine Model General Motors 5.0 L, General Motors 5.7 L Powertrain Generator Models 50Res 60Res 50Rezg 60Rezg (Preliminary), 50Rzg 60Rzg 50Gsg 60Gsg 50Rzgb 50Gsgb G50u G.


Palabras clave


Heat Recovery, Absorption Chiller, Air Conditioning, Energy Saving

Referencias


B. H. Gebrelassie et al. “Economic performance of an absorption cooling system under uncertainty.” Applied Thermal Engineering, vol. 29, pp. 3491-3500, 2009.

M. Ishimatsu. “Advance Absorption Chillers: Utilization of various heat energies for air conditioning. 1st European” presented at Conference on Polygeneration, 2007.

New Buildings Institute. “Absorption Chillers Guideline.” Internet: www.newbuildings.org ,1998 [2009].

ASHRAE 90.1R. Minimum Efficiency. Code Compliance Manual. U.S. DOE. 2000

P. Kalinowski et al. “Application of waste heat powered absorption refrigeration system to the LNG recovery process.” International journal of refrigeration, vol. 32, no. 4, pp. 687-694, 2009.

S. Man Lai and H. Wai. “Integration of trigeneration system and thermal storage under demand uncertainties.” Applied Energy Journal, vol. 87, no. 9, pp. 2868-2880, 2009.

L. Massagués et al. Estudio comparativo de una instalación de trigeneración con microturbina de gas y un sistema convencional con bomba de calor en un complejo hotelero. Universitat Rovira i Virgili, 2004.

A. Arteconi. “Distributed generation and trigeneration: Energy saving opportunities in Italian supermarket sector.” Applied Thermal Engineering, vol. 29(8-9), pp. 1735-1743, 2009.

Escoa Engineering Manual Online

J.I. Yoon. “A study on the advanced performance of an absorption heater/chiller with a solution preheated using waste gas.” Applied Thermal Engineering, vol. 23, no. 6, pp. 757-767, 2003.

European Commission for Energy. “Energy Savings CHCP plants in the Hotel Sector.” Internet: www.newbuildings.org, 2001[2009].

V. Patnaik. “Absorption technology as a sustainable energy solution in the United States.” Presented in 1st European Conference Polygeneration. Tarragona (Spain), 16-17 October 2007.

P. Srikhirin et al. “A review of absorption refrigeration technologies.” Renewable and Sustainable Energy Reviews, vol. 5, no. 4, pp. 343-372, 2001.

K. Goodheart. “Low Firing Temperature Absorption Chiller System.” Master Degree Thesis of University of Wisconsin, 2000.

H. Kreith, et al. Absorption Chillers and Heat Pumps. CRS Press, 1996

Y. A. Cengel and M.A. Boles. Thermodynamics an Engineer Approach. Table A.2, Fifth edition, McGraw Hill, 2006.

R. William. “Driving Absorption Chillers Using Heat Recovery.” ASHRAE Journal, vol. 46, no. 9, pp. S30-S36, 2004.

K.P.M. Wipplinger et al. “Stainless steel tube heat exchanger design for waste.” Journal of Energy in Southern Africa, vol. 17, no. 2, pp. 47-56, 2006.

V. Ganapathy. “Design and Evaluate Finned Tube Bundles,” in Hydrocarbon Processing, vol. 75, no. 9, pp. 103-112, 1996.

C. Taylor. “Measurement of finned-tube heat exchanger performance.” Master Thesis, Georgia Institute Technology, 2004.

ESCOA Engineering Manual. “Fintube Technologies, Inc.” Internet: www.fintubetech.com [2009].

P.F. Ostwald and T.S. McLaren. Cost analysis and estimating for engineering and management. New Jersey: Pearson education Inc., 2004.

W.G. Sullivan et al. Engineering Economy. 12th edition, New Jersey: Pearson education Inc., 2003.

Kawasaki Thermal Engineering. Waste heat energy application for absorption chillers. 3th International District Cooling Conference & Trade Show, Dubai, 2008.

M.J. Moran and H.N. Shapiro. Fundamentos de Termodinámica Técnica. 2th edition, Ed. Reverte, 2004.

Waste Heat Recovery. Internet: http://wasteheatrecovery.com/ [2014].

F.J. Wang et al. “Economic feasibility of waste heat to power conversion.” Applied Energy Journal, vol. 84, no. 4, pp. 442-454, 2007.

S. Popli et al. “Gas turbine efficiency enhancement using waste heat powered absorption chillers in the oil and gas industry.” Applied Thermal Engineering, vol. 50, no. 1, pp. 919-931, 2013.

A. Huicochea. “Thermodynamic analysis of a trigeneration system consisting of a micro gas turbine and a double effect absorption chiller.” In Energy, vol. 67(16), pp. 548-556, 2014.


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ESTADÍSTICAS DEL ARTICULO
Resumen : 447
ARCHIVO PDF ABSTRACT : 86
ARCHIVO PDF RESUMEN : 47
ARCHIVO PDF FULL ARTICLE : 294


Copyright (c) 2018 Revista Investigación & Desarrollo
Este obra está bajo una licencia de Creative Commons Reconocimiento-NoComercial-CompartirIgual 4.0 Internacional.

HEAT RECOVERY SYSTEM IN AN INDUSTRIAL FURNACE TO GENERATE AIR CONDITIONING THROUGH AN ABSORPTION CHILLER


Resumen


A case study of a Heat Recovery System is performed in an industrial furnace that uses natural gas to determine the absorption cooling capacity (LiBr – Water) that can be generated for air conditioning. The energy source will be the heat of the flue gas that is eliminated by the furnace stack. Thermodynamic and economic analysis of the entire system (heat recovery exchanger, absorption chiller, cooling tower, etc.) is performed. A methodology to evaluate the Heat Recovery potential of the industrial furnace will be shown, as well as the limitations that must be considered. This methodology also considers the favorable environmental impact that is available to perform a heat recovery project. The results show that under certain operational characteristics and conditions, the heat recovery system is technically and economically feasible (profitable).

Palabras clave


Heat Recovery, Absorption Chiller, Air Conditioning, Energy Saving

Referencias


B. H. Gebrelassie et al. “Economic performance of an absorption cooling system under uncertainty.” Applied Thermal Engineering, vol. 29, pp. 3491-3500, 2009.

M. Ishimatsu. “Advance Absorption Chillers: Utilization of various heat energies for air conditioning. 1st European” presented at Conference on Polygeneration, 2007.

New Buildings Institute. “Absorption Chillers Guideline.” Internet: www.newbuildings.org ,1998 [2009].

ASHRAE 90.1R. Minimum Efficiency. Code Compliance Manual. U.S. DOE. 2000

P. Kalinowski et al. “Application of waste heat powered absorption refrigeration system to the LNG recovery process.” International journal of refrigeration, vol. 32, no. 4, pp. 687-694, 2009.

S. Man Lai and H. Wai. “Integration of trigeneration system and thermal storage under demand uncertainties.” Applied Energy Journal, vol. 87, no. 9, pp. 2868-2880, 2009.

L. Massagués et al. Estudio comparativo de una instalación de trigeneración con microturbina de gas y un sistema convencional con bomba de calor en un complejo hotelero. Universitat Rovira i Virgili, 2004.

A. Arteconi. “Distributed generation and trigeneration: Energy saving opportunities in Italian supermarket sector.” Applied Thermal Engineering, vol. 29(8-9), pp. 1735-1743, 2009.

J.I. Yoon. “A study on the advanced performance of an absorption heater/chiller with a solution preheated using waste gas.” Applied Thermal Engineering, vol. 23, no. 6, pp. 757-767, 2003.

European Commission for Energy. “Energy Savings CHCP plants in the Hotel Sector.” Internet: www.newbuildings.org, 2001[2009].

V. Patnaik. “Absorption technology as a sustainable energy solution in the United States.” Presented in 1st European Conference Polygeneration. Tarragona (Spain), 16-17 October 2007.

P. Srikhirin et al. “A review of absorption refrigeration technologies.” Renewable and Sustainable Energy Reviews, vol. 5, no. 4, pp. 343-372, 2001.

K. Goodheart. “Low Firing Temperature Absorption Chiller System.” Master Degree Thesis of University of Wisconsin, 2000.

H. Kreith, et al. Absorption Chillers and Heat Pumps. CRS Press, 1996

Y. A. Cengel and M.A. Boles. Thermodynamics an Engineer Approach. Table A.2, Fifth edition, McGraw Hill, 2006.

R. William. “Driving Absorption Chillers Using Heat Recovery.” ASHRAE Journal, vol. 46, no. 9, pp. S30-S36, 2004.

K.P.M. Wipplinger et al. “Stainless steel tube heat exchanger design for waste.” Journal of Energy in Southern Africa, vol. 17, no. 2, pp. 47-56, 2006.

V. Ganapathy. “Design and Evaluate Finned Tube Bundles,” in Hydrocarbon Processing, vol. 75, no. 9, pp. 103-112, 1996.

C. Taylor. “Measurement of finned-tube heat exchanger performance.” Master Thesis, Georgia Institute Technology, 2004.

ESCOA Engineering Manual. “Fintube Technologies, Inc.” Internet: www.fintubetech.com [2009].

P.F. Ostwald and T.S. McLaren. Cost analysis and estimating for engineering and management. New Jersey: Pearson education Inc., 2004.

W.G. Sullivan et al. Engineering Economy. 12th edition, New Jersey: Pearson education Inc., 2003.

Kawasaki Thermal Engineering. Waste heat energy application for absorption chillers. 3th International District Cooling Conference & Trade Show, Dubai, 2008.

Engineering

M.J. Moran and H.N. Shapiro. Fundamentos de Termodinámica Técnica. 2th edition, Ed. Reverte, 2004.

Waste Heat Recovery. Internet: http://wasteheatrecovery.com/ [2014].

F.J. Wang et al. “Economic feasibility of waste heat to power conversion.” Applied Energy Journal, vol. 84, no. 4, pp. 442-454, 2007.

Escoa Engineering Manual 2017

Software

S. Popli et al. “Gas turbine efficiency enhancement using waste heat powered absorption chillers in the oil and gas industry.” Applied Thermal Engineering, vol. 50, no. 1, pp. 919-931, 2013.

A. Huicochea. “Thermodynamic analysis of a trigeneration system consisting of a micro gas turbine and a double effect absorption chiller.” In Energy, vol. 67(16), pp. 548-556, 2014.


Enlaces refback

  • No hay ningún enlace refback.


ESTADÍSTICAS DEL ARTICULO
Resumen : 447
ARCHIVO PDF ABSTRACT : 86
ARCHIVO PDF RESUMEN : 47
ARCHIVO PDF FULL ARTICLE : 294


Copyright (c) 2018 Revista Investigación & Desarrollo

Escola Engineering Manual Pdf


Escoa Engineering Manual Free

Este obra está bajo una licencia de Creative Commons Reconocimiento-NoComercial-CompartirIgual 4.0 Internacional.