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District Heating of Buildings by Renewable Energy Using Thermochemical Heat Transmission

Author

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  • Robert E. Critoph

    (School of Engineering, University of Warwick, Coventry CV4 7AL, UK)

  • Angeles M. Rivero Pacho

    (School of Engineering, University of Warwick, Coventry CV4 7AL, UK)

Abstract

The decarbonisation of building heating in urban areas can be achieved by heat pumps connected to district heating networks. These could be ‘third-generation’ (85/75 °C), ‘fourth-generation’ (50/40 or 50/25 °C) or ‘fifth-generation’ (near ambient) water loops. Networks using thermochemical reactions should require smaller pipe diameters than water systems and be more economic. This work investigates thermochemical transmission systems based on liquid–gas absorption intended for application in urban district heating networks where the main heat source might be a MW scale heat pump. Previous studies of absorption for heat transmission have concentrated on long distance (e.g., 50 km) transmission of heat or cold utilizing waste heat from power stations or similar but these are not directly applicable to our application which has not been investigated before. Absorbent-refrigerant pairs are modelled using water, methanol and acetone as absorbates. Thermodynamic properties are obtained from the literature and modelling carried out using thermodynamic analysis very similar to that employed for absorption heat pumps or chillers. The pairs with the best performance (efficiency and power density) both for ambient loop (fifth-generation) and high temperature (fourth-generation) networks use water pairs. The next best pairs use methanol as a refrigerant. Methanol has the advantage of being usable at ambient temperatures below 0 °C. Of the water-based pairs, water–NaOH is good for ambient temperature loops, reducing pipe size by 75%. Specifically, in an ambient loop, heat losses are typically less than 5% and the heat transferred per volume of pumped fluid can be 30 times that of a pumped water network with 10 K temperature change. For high temperature networks the heat losses can reach 30% and the power density is 4 times that of water. The limitation with water–NaOH is the low evaporating temperature when ambient air is the heat source. Other water pairs perform better but use lithium compounds which are prohibitively expensive. For high temperature networks, a few water- and methanol-based pairs may be used, but their performance is lower and may be unattractive.

Suggested Citation

  • Robert E. Critoph & Angeles M. Rivero Pacho, 2022. "District Heating of Buildings by Renewable Energy Using Thermochemical Heat Transmission," Energies, MDPI, vol. 15(4), pages 1-48, February.
    • Handle: RePEc:gam:jeners:v:15:y:2022:i:4:p:1449-:d:750994
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    References listed on IDEAS

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    1. Kang, Y.T & Akisawa, A & Sambe, Y & Kashiwagi, T, 2000. "Absorption heat pump systems for solution transportation at ambient temperature — STA cycle," Energy, Elsevier, vol. 25(4), pages 355-370.
    2. Philipp Geyer & Muhannad Delwati & Martin Buchholz & Alessandro Giampieri & Andrew Smallbone & Anthony P. Roskilly & Reiner Buchholz & Mathieu Provost, 2018. "Use Cases with Economics and Simulation for Thermo-Chemical District Networks," Sustainability, MDPI, vol. 10(3), pages 1-33, February.
    3. Revesz, Akos & Jones, Phil & Dunham, Chris & Davies, Gareth & Marques, Catarina & Matabuena, Rodrigo & Scott, Jim & Maidment, Graeme, 2020. "Developing novel 5th generation district energy networks," Energy, Elsevier, vol. 201(C).
    4. Geyer, Philipp & Buchholz, Martin & Buchholz, Reiner & Provost, Mathieu, 2017. "Hybrid thermo-chemical district networks – Principles and technology," Applied Energy, Elsevier, vol. 186(P3), pages 480-491.
    5. Patil, Kashinath R. & Chaudhari, Shrirang K. & Katti, Sushilendra S., 1991. "Thermodynamic properties of aqueous solutions of lithium iodide: Simplified method for predicting the enthalpies from the vapor-pressure data," Applied Energy, Elsevier, vol. 39(3), pages 189-199.
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