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Year 2021, , 890 - 903, 01.05.2021
https://doi.org/10.18186/thermal.930713

Abstract

References

  • [1] IEA. World Energy Outlook, 2017. [2] Litman T. Efficient vehicles versus efficient transportation. Comparing transportation energy conservation strategies. Transport Policy, 2005;12(2):121-129.
  • [3] Hoseinzadeh S, Hadi Zakeri M, Shirkhani A, Chamkha AJ. Analysis of energy consumption improvements of a zero-energy building in a humid mountainous area. Journal of Renewable and Sustainable Energy, 2019;11: 015103.
  • [4] Belzer, DB. Energy efficiency potential inexisting potential buldings; Review of selected recent studies. Pacific Northwest National Laboratories, US department of Energy, 2009.
  • [5] Abdelaziz EA, Saidur R, Mekhilef S. A review on energy saving strategies in industrial sector. Renewable and Sustainable Energy Reviews, 2011;15(1):150-168.
  • [6] Hoseinzadeh S, Azadi R. Simulation and optimization of a solar-assisted heating and cooling system for a house in Northern of Iran. Journal of Renewable and Sustainable Energy. 2017;9:045101.
  • [7] IEA 2019, France, Energy Efficiency: Industry: The global exchange for energy efficiency policies, data and impacts, Last Accessed 26 July 2019, https://www.iea.org/topics/energyefficiency/industry/.
  • [8] Umeda T, Itoh J, Shiroko K. Heat exchange system synthesis. Chemical Engineering Progress, 1978;73(7): 70-76.
  • [9] Linnhoff B, Flower JR. Synthesis of heat exchanger networks - 1. Systematic generation of energy optimal networks. AIChE Journal, 1978;24(4): 633-642.
  • [10] Shenoy UV. Heat Exchanger Network Synthesis: Process Optimization by Energy and Resource Analysis. Gulf Publishing Co., Houston, TX, USA, 1995.
  • [11] Semra O, Salih D. Application for pinch design of heat exchanger networks by use of a computer code employing an improved problem algorithm table. Energy conversion and management, 2001;42:2043-2051.
  • [12] Smith, R. Chemical Process Design and Integration. John Wiley & Sons Ltd, West Sussex, UK, 2005.
  • [13] Klemes J, Friedler F, Bulatov I, Varbanov P. Sustainability in the Process Industry. Integration and Optimization. McGraw-Hill, New York, US, 2010.
  • [14] Anantharaman R, Nastad I, Nygreen B, Gundersen T. The sequential framework for heat exchanger network synthesis—The minimum number of units sub-problem. Computers and Chemical Engineering 2010;34: 1822–1830.
  • [15] Boland D, Linnhoff B. The preliminary design of networks for heat exchange by systematic methods. Chem. Eng., 1979; 222.
  • [16] Yong JY, Varbanov PS, Klemeš JJ. Matrix representation of the grid diagram for heat exchanger networks. Chemical Engineering Transactions, 2015;45:103-108.
  • [17] Lakshmanan R, Bañares-Alcántara R. A Novel Visualization Tool for Heat Exchanger Network Retrofit, Ind. Eng. Chem. Res., 1996; 35:4507-4522.
  • [18] Nordman R, Berntsson T. New Pinch Technology Based HEN Analysis Methodologies for Cost-Effective Retrofitting. Can. J. Chem. Eng., 2001; 79(4):655-662.
  • [19] Osman A, Abdul Mutalib MI, Shuhaimi M, Amminudin KA. Paths combination for HENs retrofit. Applied Thermal Engineering, 2009; 29(14–15):3103-3109.
  • [20] Wan Alwi SR, Manan ZA. STEP—A new graphical tool for simultaneous targeting and design of a heat exchanger network. Chemical Engineering Journal, 2010;162:106-121.
  • [21] Abbood NK, Manan ZA, Wan Alwi SR. A combined numerical and visualization tool for utility targeting and heat exchanger network retrofitting. Journal of Cleaner Production, 2012; 23:1-7.
  • [22] Gadalla MA. A New Graphical Method for Pinch Analysis and Energy Integration. Chemical Engineering Transactions, 2015;43:1291-1296.
  • [23] Lai YQ, Manan ZA, Wan Alwi SR. Heat Exchanger Network Retrofit Using Individual Stream Temperature vs Enthalpy Plot. Chemical Engineering Transactions, 2017; 61:1651-1656.
  • [24] Yeo YS, Wan Alwi SR, Ahmad S, Manan ZA, Zamzuri NH. A new graphical method for heat exchanger network design involving phase changes. Chemical Engineering Transactions, 2017; 56:1249-1254.
  • [25] Al-Mayyahi MA, Albadran FA, Fares MN. Retrofitting Design of Heat Exchanger Networks Using Supply-Target Diagram. Chemical Engineering Transactions, 2019; 75:625-630.
  • [26] Asante NDK, Zhu XX. An automated and interactive approach for heat exchanger network retrofit. Trans IChemE, 1997; 75:349.
  • [27] Doğan B, Erbay LB. Experimental analysis of the effect of cold fluid inlet temperature on the thermal performance of a heat exchanger. Journal of Thermal Engineering, 1997; 2(1):583-592.
  • [28] Pourfayaz F, Kasaeian A, Fard MM. A proper selection of hot and cold utilities in a plant containing multiple heat exchanger networks. Journal of Thermal Engineering, 2019; 5(4):341-354.

A SYSTEMATIC GRAPHICAL METHOD FOR SYNTHESIS OF HEAT EXCHANGER NETWORKS

Year 2021, , 890 - 903, 01.05.2021
https://doi.org/10.18186/thermal.930713

Abstract

Heat exchanger networks (HENs) play a significant role in the energy conservation of any process industry. The HENs are used to maximize heat recovery by exchanging heat between hot and cold process streams. Therefore, the optimum design of HENs is extremely important to reach the maximum efficiency of energy systems. Many graphical methods have been developed during the last four decades for synthesizing of heat exchanger networks (HENs). However, most of these methods have only been evaluated for retrofitting design of HENs. In the grassroots design situation, these methods are often complicated and tedious. This paper introduces a new and simple graphical approach for HEN grassroots design. The new approach based on a single graph called Supply-Target Diagram (ST-D). The ST-D is formulated by plotting supply temperatures versus target temperatures of streams. Streams matching can easily be applied in the ST-D and splitting of streams is clearly visualized and evaluated. A case study is used to illustrate the application of the new graphical method for grassroots design of HENs.

References

  • [1] IEA. World Energy Outlook, 2017. [2] Litman T. Efficient vehicles versus efficient transportation. Comparing transportation energy conservation strategies. Transport Policy, 2005;12(2):121-129.
  • [3] Hoseinzadeh S, Hadi Zakeri M, Shirkhani A, Chamkha AJ. Analysis of energy consumption improvements of a zero-energy building in a humid mountainous area. Journal of Renewable and Sustainable Energy, 2019;11: 015103.
  • [4] Belzer, DB. Energy efficiency potential inexisting potential buldings; Review of selected recent studies. Pacific Northwest National Laboratories, US department of Energy, 2009.
  • [5] Abdelaziz EA, Saidur R, Mekhilef S. A review on energy saving strategies in industrial sector. Renewable and Sustainable Energy Reviews, 2011;15(1):150-168.
  • [6] Hoseinzadeh S, Azadi R. Simulation and optimization of a solar-assisted heating and cooling system for a house in Northern of Iran. Journal of Renewable and Sustainable Energy. 2017;9:045101.
  • [7] IEA 2019, France, Energy Efficiency: Industry: The global exchange for energy efficiency policies, data and impacts, Last Accessed 26 July 2019, https://www.iea.org/topics/energyefficiency/industry/.
  • [8] Umeda T, Itoh J, Shiroko K. Heat exchange system synthesis. Chemical Engineering Progress, 1978;73(7): 70-76.
  • [9] Linnhoff B, Flower JR. Synthesis of heat exchanger networks - 1. Systematic generation of energy optimal networks. AIChE Journal, 1978;24(4): 633-642.
  • [10] Shenoy UV. Heat Exchanger Network Synthesis: Process Optimization by Energy and Resource Analysis. Gulf Publishing Co., Houston, TX, USA, 1995.
  • [11] Semra O, Salih D. Application for pinch design of heat exchanger networks by use of a computer code employing an improved problem algorithm table. Energy conversion and management, 2001;42:2043-2051.
  • [12] Smith, R. Chemical Process Design and Integration. John Wiley & Sons Ltd, West Sussex, UK, 2005.
  • [13] Klemes J, Friedler F, Bulatov I, Varbanov P. Sustainability in the Process Industry. Integration and Optimization. McGraw-Hill, New York, US, 2010.
  • [14] Anantharaman R, Nastad I, Nygreen B, Gundersen T. The sequential framework for heat exchanger network synthesis—The minimum number of units sub-problem. Computers and Chemical Engineering 2010;34: 1822–1830.
  • [15] Boland D, Linnhoff B. The preliminary design of networks for heat exchange by systematic methods. Chem. Eng., 1979; 222.
  • [16] Yong JY, Varbanov PS, Klemeš JJ. Matrix representation of the grid diagram for heat exchanger networks. Chemical Engineering Transactions, 2015;45:103-108.
  • [17] Lakshmanan R, Bañares-Alcántara R. A Novel Visualization Tool for Heat Exchanger Network Retrofit, Ind. Eng. Chem. Res., 1996; 35:4507-4522.
  • [18] Nordman R, Berntsson T. New Pinch Technology Based HEN Analysis Methodologies for Cost-Effective Retrofitting. Can. J. Chem. Eng., 2001; 79(4):655-662.
  • [19] Osman A, Abdul Mutalib MI, Shuhaimi M, Amminudin KA. Paths combination for HENs retrofit. Applied Thermal Engineering, 2009; 29(14–15):3103-3109.
  • [20] Wan Alwi SR, Manan ZA. STEP—A new graphical tool for simultaneous targeting and design of a heat exchanger network. Chemical Engineering Journal, 2010;162:106-121.
  • [21] Abbood NK, Manan ZA, Wan Alwi SR. A combined numerical and visualization tool for utility targeting and heat exchanger network retrofitting. Journal of Cleaner Production, 2012; 23:1-7.
  • [22] Gadalla MA. A New Graphical Method for Pinch Analysis and Energy Integration. Chemical Engineering Transactions, 2015;43:1291-1296.
  • [23] Lai YQ, Manan ZA, Wan Alwi SR. Heat Exchanger Network Retrofit Using Individual Stream Temperature vs Enthalpy Plot. Chemical Engineering Transactions, 2017; 61:1651-1656.
  • [24] Yeo YS, Wan Alwi SR, Ahmad S, Manan ZA, Zamzuri NH. A new graphical method for heat exchanger network design involving phase changes. Chemical Engineering Transactions, 2017; 56:1249-1254.
  • [25] Al-Mayyahi MA, Albadran FA, Fares MN. Retrofitting Design of Heat Exchanger Networks Using Supply-Target Diagram. Chemical Engineering Transactions, 2019; 75:625-630.
  • [26] Asante NDK, Zhu XX. An automated and interactive approach for heat exchanger network retrofit. Trans IChemE, 1997; 75:349.
  • [27] Doğan B, Erbay LB. Experimental analysis of the effect of cold fluid inlet temperature on the thermal performance of a heat exchanger. Journal of Thermal Engineering, 1997; 2(1):583-592.
  • [28] Pourfayaz F, Kasaeian A, Fard MM. A proper selection of hot and cold utilities in a plant containing multiple heat exchanger networks. Journal of Thermal Engineering, 2019; 5(4):341-354.
There are 27 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Mohammad Al-mayyahia This is me 0000-0003-3773-5505

Mohammad Fares This is me 0000-0003-3089-7026

Nabeel Abbood This is me

Publication Date May 1, 2021
Submission Date May 10, 2019
Published in Issue Year 2021

Cite

APA Al-mayyahia, M., Fares, M., & Abbood, N. (2021). A SYSTEMATIC GRAPHICAL METHOD FOR SYNTHESIS OF HEAT EXCHANGER NETWORKS. Journal of Thermal Engineering, 7(4), 890-903. https://doi.org/10.18186/thermal.930713
AMA Al-mayyahia M, Fares M, Abbood N. A SYSTEMATIC GRAPHICAL METHOD FOR SYNTHESIS OF HEAT EXCHANGER NETWORKS. Journal of Thermal Engineering. May 2021;7(4):890-903. doi:10.18186/thermal.930713
Chicago Al-mayyahia, Mohammad, Mohammad Fares, and Nabeel Abbood. “A SYSTEMATIC GRAPHICAL METHOD FOR SYNTHESIS OF HEAT EXCHANGER NETWORKS”. Journal of Thermal Engineering 7, no. 4 (May 2021): 890-903. https://doi.org/10.18186/thermal.930713.
EndNote Al-mayyahia M, Fares M, Abbood N (May 1, 2021) A SYSTEMATIC GRAPHICAL METHOD FOR SYNTHESIS OF HEAT EXCHANGER NETWORKS. Journal of Thermal Engineering 7 4 890–903.
IEEE M. Al-mayyahia, M. Fares, and N. Abbood, “A SYSTEMATIC GRAPHICAL METHOD FOR SYNTHESIS OF HEAT EXCHANGER NETWORKS”, Journal of Thermal Engineering, vol. 7, no. 4, pp. 890–903, 2021, doi: 10.18186/thermal.930713.
ISNAD Al-mayyahia, Mohammad et al. “A SYSTEMATIC GRAPHICAL METHOD FOR SYNTHESIS OF HEAT EXCHANGER NETWORKS”. Journal of Thermal Engineering 7/4 (May 2021), 890-903. https://doi.org/10.18186/thermal.930713.
JAMA Al-mayyahia M, Fares M, Abbood N. A SYSTEMATIC GRAPHICAL METHOD FOR SYNTHESIS OF HEAT EXCHANGER NETWORKS. Journal of Thermal Engineering. 2021;7:890–903.
MLA Al-mayyahia, Mohammad et al. “A SYSTEMATIC GRAPHICAL METHOD FOR SYNTHESIS OF HEAT EXCHANGER NETWORKS”. Journal of Thermal Engineering, vol. 7, no. 4, 2021, pp. 890-03, doi:10.18186/thermal.930713.
Vancouver Al-mayyahia M, Fares M, Abbood N. A SYSTEMATIC GRAPHICAL METHOD FOR SYNTHESIS OF HEAT EXCHANGER NETWORKS. Journal of Thermal Engineering. 2021;7(4):890-903.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK http://eds.yildiz.edu.tr/journal-of-thermal-engineering