Please use this identifier to cite or link to this item: https://doi.org/10.21256/zhaw-25032
Publication type: Conference paper
Type of review: Peer review (publication)
Title: Design and optimal integration of seasonal borehole thermal energy storage in district heating and cooling networks
Authors: Fiorentini, Massimo
Vivian, Jacopo
Heer, Philipp
Baldini, Luca
et. al: No
DOI: 10.34641/clima.2022.64
10.21256/zhaw-25032
Proceedings: CLIMA 2022 The 14th REHVA HVAC World Congress,
Conference details: 14th RHEVA HVAC World Congress, Rotterdam, The Netherlands, 22-25 May 2022
Issue Date: 20-Apr-2022
Publisher / Ed. Institution: TU Delft OPEN
ISBN: 978-94-6366-564-3
Language: English
Subjects: Renewable heating and cooling; Seasonal thermal storage; Borehole thermal energy storage (BTES); District heating/cooling network; Design optimization; Optimal management
Subject (DDC): 621.04: Energy engineering
Abstract: Technologies that can close the seasonal gap between summer renewable generation and winter heating demand are crucial in reducing CO2 emissions of energy systems. Borehole thermal energy storage (BTES) systems offer an attractive solution, and their correct sizing is important for their techno-economic success. Most of the BTES design studies either employ detailed modelling and simulation techniques, which are not suitable for numerical optimization, or use significantly simplified models that do not consider the effects of operational variables. This paper proposes a BTES modelling approach and a mixed-integer bilinear programming formulation that can consider the influence of the seasonal BTES temperature swing on its capacity, thermal losses, maximum heat transfer rate and on the efficiency of connected heat pumps or chillers. This enables an accurate assessment of its integration performance in different district heating and cooling networks operated at different temperatures and with different operating modes (e.g. direct discharge of the BTES or via a heat pump). Considering a case study utilizing air sourced heat pumps under seasonally varying CO2 intensity of the electricity, the optimal design and operation of an energy system integrating a BTES and solar thermal collectors were studied. The optimization, aiming at minimizing the annual cost and CO2 emissions of the energy system, was applied to two heating network temperatures and five representative carbon prices. Results show that the optimal BTES design changed in terms of both size and operational conditions, and reductions in emissions up to 43% could be achieved compared to a standard air-source heat pumps based system.
Further description: Conference Proceedings available at: https://proceedings.open.tudelft.nl/index.php/clima2022
URI: https://digitalcollection.zhaw.ch/handle/11475/25032
Fulltext version: Published version
License (according to publishing contract): CC BY 4.0: Attribution 4.0 International
Departement: Architecture, Design and Civil Engineering
Organisational Unit: Centre for Building Technologies and Processes (ZBP)
Appears in collections:Publikationen Architektur, Gestaltung und Bauingenieurwesen

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