Heat integration applied on low thermal energy system: Building complex case study

Ibaaz Khalid; Cherkaoui Moha; Cherkaoui Mohamed; Annaba Khadija

doi:10.1051/e3sconf/202123400046

All issues

Volume 234 (2021)

E3S Web Conf., 234 (2021) 00046

References

Open Access

Issue		E3S Web Conf. Volume 234, 2021 The International Conference on Innovation, Modern Applied Science & Environmental Studies (ICIES2020)


Article Number		00046
Number of page(s)		6
DOI		https://doi.org/10.1051/e3sconf/202123400046
Published online		02 February 2021

C.O. Holliday, « Sustaining human life through sustainable energy », Energy Strategy Rev., Vol. 2, no 3 4, p. 209 210, févr. 2014 [Google Scholar]
MAEE, Moroccan Agency for Energy Efficiency. http://www.amee.ma/index.php?option=com_content&view=article&id=125&Itemid=174&lang=en (last accessed 20 August 2020) [Google Scholar]
MIITDE, Ministry of Industry, Investment, Trade and Digital Economy. http://www.mcinet.gov.ma/en/content/renewable-energy (last accessed August 2020) [Google Scholar]
O. Edenhofer, R. Pichsy, Y. Sokona. IPCC, the Intergovern-mental Panel on Climate Change, Special Report on Renewable Energy Sources and Climate Change Mitigation 2012 [Google Scholar]
MAEE, Maroccan Agency for Energy Efficiency – Energy efficiency in building. https://www.amee.ma/en/node/118 (last accessed August 2020) [Google Scholar]
D. D’Agostino, F. de’ Rossi, M. Marigliano, C. Marino, et F. Minichiello, « Evaluation of the optimal thermal insulation thickness for an office building in different climates by means of the basic and modified “cost-optimal” methodology », J. Build. Eng., Vol. 24, p. 100743, juill. 2019 [Google Scholar]
M. Jerman, I. Palomar, V. Kočí, et R. Černý, « Thermal And Hygric Properties Of Biomaterials Suitable For Interior Thermal Insulation Systems In Historical And Traditional Buildings », Build. Environ., Vol. 154, P. 81 88, Mai 2019 [Google Scholar]
E. M. E. Khattabi, M. Mharzi, M. Zouini et K. Valancius, « Comparative Study of Various Thermal Analyses of Smart Windows in Cubic Building Design », JESTR, Vol. 11, no 5, p. 86 92, oct. 2018 [Google Scholar]
B. Linnhoff et J.R. Flower, « Synthesis of heat exchanger networks: I. Systematic generation of energy optimal networks », AIChE J., Vol. 24, no 4, p. 633 642, juill. 1978 [Google Scholar]
D.W. Townsend et B. Linnhoff, « Heat and power networks in process design. Part I: Criteria for placement of heat engines and heat pumps in process networks », AIChE J., Vol. 29, no 5, p. 742 748, sept. 1983 [Google Scholar]
I.C. Kemp, Pinch analysis and process integration: a user guide on process integration for the efficient use of energy, 2nd ed. Amsterdam ; Boston: Butterworth-Heinemann, 2007 [Google Scholar]
Klemeš, Varbanov, Wan Alwi, Manan, « Process Integration and Intensification: Saving Energy, Water and Resources », p. 269 [Google Scholar]
A. Bertrand, R. Aggoune, et F. Maréchal, « In-building waste water heat recovery: An urban-scale method for the characterisation of water streams and the assessment of energy savings and costs », Appl. Energy, Vol. 192, p. 110 125, avr. 2017 [Google Scholar]
A. Herrera, J. Islas, A. Arriola, « Pinch technology application in a hospital », Applied Thermal Engineering, Vol. 23, p. 127 139. 2003 [Google Scholar]
V. misevičiūtė, V. motuzienė, K. valančius, « the application of the pinch method for the analysis of the heat exchangers network in a ventilation system of a building », applied thermal engineering, vol 129, p. 772-781, january 2018 [Google Scholar]
Ressources Cannada, Pinch Analysis: for the Efficient Use of Energy, Water and Hydrogen http://publications.gc.ca/collections/collection_2012/rncan-nrcan/M39-96-2003-fra.pdf [Google Scholar]
M. Bennajah, N. Chaouni. Echangeurs de Chaleur: Technologie, calcul et design. Edition TECHNIP, 1 rue du Bac, 75007 Paris, 2014 [Google Scholar]
B. Linnhoff, E. Hindmarch, « the pinch design method for heat exchanger networks », Chemical Engineering Science, Vol. 38, No. 5, p. 745-763, 1983 [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.

[1] C.O. Holliday, « Sustaining human life through sustainable energy », Energy Strategy Rev., Vol. 2, no 3 4, p. 209 210, févr. 2014 [Google Scholar]

[2] MAEE, Moroccan Agency for Energy Efficiency. http://www.amee.ma/index.php?option=com_content&view=article&id=125&Itemid=174&lang=en (last accessed 20 August 2020) [Google Scholar]

[3] MIITDE, Ministry of Industry, Investment, Trade and Digital Economy. http://www.mcinet.gov.ma/en/content/renewable-energy (last accessed August 2020) [Google Scholar]

[4] O. Edenhofer, R. Pichsy, Y. Sokona. IPCC, the Intergovern-mental Panel on Climate Change, Special Report on Renewable Energy Sources and Climate Change Mitigation 2012 [Google Scholar]

[5] MAEE, Maroccan Agency for Energy Efficiency – Energy efficiency in building. https://www.amee.ma/en/node/118 (last accessed August 2020) [Google Scholar]

[6] D. D’Agostino, F. de’ Rossi, M. Marigliano, C. Marino, et F. Minichiello, « Evaluation of the optimal thermal insulation thickness for an office building in different climates by means of the basic and modified “cost-optimal” methodology », J. Build. Eng., Vol. 24, p. 100743, juill. 2019 [Google Scholar]

[7] M. Jerman, I. Palomar, V. Kočí, et R. Černý, « Thermal And Hygric Properties Of Biomaterials Suitable For Interior Thermal Insulation Systems In Historical And Traditional Buildings », Build. Environ., Vol. 154, P. 81 88, Mai 2019 [Google Scholar]

[8] E. M. E. Khattabi, M. Mharzi, M. Zouini et K. Valancius, « Comparative Study of Various Thermal Analyses of Smart Windows in Cubic Building Design », JESTR, Vol. 11, no 5, p. 86 92, oct. 2018 [Google Scholar]

[9] B. Linnhoff et J.R. Flower, « Synthesis of heat exchanger networks: I. Systematic generation of energy optimal networks », AIChE J., Vol. 24, no 4, p. 633 642, juill. 1978 [Google Scholar]

[10] D.W. Townsend et B. Linnhoff, « Heat and power networks in process design. Part I: Criteria for placement of heat engines and heat pumps in process networks », AIChE J., Vol. 29, no 5, p. 742 748, sept. 1983 [Google Scholar]

[11] I.C. Kemp, Pinch analysis and process integration: a user guide on process integration for the efficient use of energy, 2nd ed. Amsterdam ; Boston: Butterworth-Heinemann, 2007 [Google Scholar]

[12] Klemeš, Varbanov, Wan Alwi, Manan, « Process Integration and Intensification: Saving Energy, Water and Resources », p. 269 [Google Scholar]

[13] A. Bertrand, R. Aggoune, et F. Maréchal, « In-building waste water heat recovery: An urban-scale method for the characterisation of water streams and the assessment of energy savings and costs », Appl. Energy, Vol. 192, p. 110 125, avr. 2017 [Google Scholar]

[14] A. Herrera, J. Islas, A. Arriola, « Pinch technology application in a hospital », Applied Thermal Engineering, Vol. 23, p. 127 139. 2003 [Google Scholar]

[15] V. misevičiūtė, V. motuzienė, K. valančius, « the application of the pinch method for the analysis of the heat exchangers network in a ventilation system of a building », applied thermal engineering, vol 129, p. 772-781, january 2018 [Google Scholar]

[16] Ressources Cannada, Pinch Analysis: for the Efficient Use of Energy, Water and Hydrogen http://publications.gc.ca/collections/collection_2012/rncan-nrcan/M39-96-2003-fra.pdf [Google Scholar]

[17] M. Bennajah, N. Chaouni. Echangeurs de Chaleur: Technologie, calcul et design. Edition TECHNIP, 1 rue du Bac, 75007 Paris, 2014 [Google Scholar]

[18] B. Linnhoff, E. Hindmarch, « the pinch design method for heat exchanger networks », Chemical Engineering Science, Vol. 38, No. 5, p. 745-763, 1983 [Google Scholar]