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On the robustness, effectiveness and reliability of chemical and mechanical heat pumps for low-temperature heat source district heating: A comparative simulation-based analysis and evaluation

Author

Listed:
  • Ajah, A.N.
  • Mesbah, A.
  • Grievink, J.
  • Herder, P.M.
  • Falcao, P.W.
  • Wennekes, S.

Abstract

Our physical environment is endowed with unlimited amount of natural and artificial sources of energy at various low exergetic levels which leaves them almost impossible to be thermally utilized at such source states. The thermal upgrading of these low exergetic energy sources could render them amenable to various practical thermal usages. This paper provides a comparative study through simulations, of the effectiveness, robustness and reliability of the often two most promising heat upgrading technologies (the chemical and mechanical heat pumps) systems for the sustainable heat upgrading of low-temperature heat sources for district heating. The simulation results reveal that for a low to medium energy demand, low-temperature heat source upgrading using the chemical heat pumps seems more promising than the mechanical heat pumps, while the mechanical heat pump is best suited for high energy demand space heating. In the simulation, use was made of an artificial low-temperature heat source (a nearby pharmaceutical industry waste heat) with source temperature state of between 25 and 35°C as the feed to the upgrading units. The high energy demand (assumed to be able to serve the space heating energy requirements of a given locality) was estimated to be 923TJ/annum at a consumer-side temperature level of about 95°C.

Suggested Citation

  • Ajah, A.N. & Mesbah, A. & Grievink, J. & Herder, P.M. & Falcao, P.W. & Wennekes, S., 2008. "On the robustness, effectiveness and reliability of chemical and mechanical heat pumps for low-temperature heat source district heating: A comparative simulation-based analysis and evaluation," Energy, Elsevier, vol. 33(6), pages 908-929.
    • Handle: RePEc:eee:energy:v:33:y:2008:i:6:p:908-929
    DOI: 10.1016/j.energy.2007.12.003
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    Cited by:

    1. Sanaye, Sepehr & Chahartaghi, Mahmood, 2010. "Thermal modeling and operating tests for the gas engine-driven heat pump systems," Energy, Elsevier, vol. 35(1), pages 351-363.
    2. Sayegh, M.A. & Danielewicz, J. & Nannou, T. & Miniewicz, M. & Jadwiszczak, P. & Piekarska, K. & Jouhara, H., 2017. "Trends of European research and development in district heating technologies," Renewable and Sustainable Energy Reviews, Elsevier, vol. 68(P2), pages 1183-1192.
    3. Oluleye, Gbemi & Jiang, Ning & Smith, Robin & Jobson, Megan, 2017. "A novel screening framework for waste heat utilization technologies," Energy, Elsevier, vol. 125(C), pages 367-381.
    4. Privat, Romain & Qian, Jun-Wei & Alonso, Dominique & Jaubert, Jean-Noël, 2013. "Quest for an efficient binary working mixture for an absorption-demixing heat transformer," Energy, Elsevier, vol. 55(C), pages 594-609.
    5. Elgendy, E. & Schmidt, J., 2010. "Experimental study of gas engine driven air to water heat pump in cooling mode," Energy, Elsevier, vol. 35(6), pages 2461-2467.
    6. Lund, Rasmus & Persson, Urban, 2016. "Mapping of potential heat sources for heat pumps for district heating in Denmark," Energy, Elsevier, vol. 110(C), pages 129-138.
    7. Zhong, Wei & Feng, Hongcui & Wang, Xuguang & Wu, Dingfei & Xue, Minghua & Wang, Jian, 2015. "Online hydraulic calculation and operation optimization of industrial steam heating networks considering heat dissipation in pipes," Energy, Elsevier, vol. 87(C), pages 566-577.
    8. Blarke, Morten B. & Dotzauer, Erik, 2011. "Intermittency-friendly and high-efficiency cogeneration: Operational optimisation of cogeneration with compression heat pump, flue gas heat recovery, and intermediate cold storage," Energy, Elsevier, vol. 36(12), pages 6867-6878.
    9. Elías-Maxil, J.A. & van der Hoek, Jan Peter & Hofman, Jan & Rietveld, Luuk, 2014. "Energy in the urban water cycle: Actions to reduce the total expenditure of fossil fuels with emphasis on heat reclamation from urban water," Renewable and Sustainable Energy Reviews, Elsevier, vol. 30(C), pages 808-820.
    10. Xu, Min & Cai, Jun & Guo, Jiangfeng & Huai, Xiulan & Liu, Zhigang & Zhang, Hang, 2017. "Technical and economic feasibility of the Isopropanol-Acetone-Hydrogen chemical heat pump based on a lab-scale prototype," Energy, Elsevier, vol. 139(C), pages 1030-1039.
    11. Lund, H. & Möller, B. & Mathiesen, B.V. & Dyrelund, A., 2010. "The role of district heating in future renewable energy systems," Energy, Elsevier, vol. 35(3), pages 1381-1390.
    12. Yildirim, Nurdan & Toksoy, Macit & Gokcen, Gulden, 2010. "Piping network design of geothermal district heating systems: Case study for a university campus," Energy, Elsevier, vol. 35(8), pages 3256-3262.
    13. Kapil, Ankur & Bulatov, Igor & Smith, Robin & Kim, Jin-Kuk, 2012. "Process integration of low grade heat in process industry with district heating networks," Energy, Elsevier, vol. 44(1), pages 11-19.
    14. Tereshchenko, Tymofii & Nord, Natasa, 2016. "Energy planning of district heating for future building stock based on renewable energies and increasing supply flexibility," Energy, Elsevier, vol. 112(C), pages 1227-1244.
    15. van de Bor, D.M. & Infante Ferreira, C.A., 2013. "Quick selection of industrial heat pump types including the impact of thermodynamic losses," Energy, Elsevier, vol. 53(C), pages 312-322.

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