Techno-economic analysis of a solar district heating system with seasonal thermal storage in the UK

Renaldi, Renaldi; Friedrich, Daniel

doi:10.1016/j.apenergy.2018.11.030

Cited by 121 publications

(40 citation statements)

References 31 publications

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“…Renaldi and Friedrich [60] investigated a hybrid solar-gas system in the UK with both shortand long-term thermal storages included. The conclusion was that while technically feasible, financial incentives such as a carbon tax are needed.…”

Section: Solar Thermal Collectorsmentioning

confidence: 99%

Cost-benefit analysis of district heating systems using heat from nuclear plants in seven European countries

Leurent

Costa

Rämä

et al. 2018

Energy

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Section: Solar Thermal Collectorsmentioning

confidence: 99%

Cost-benefit analysis of district heating systems using heat from nuclear plants in seven European countries

Leurent

Costa

Rämä

et al. 2018

Energy

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“…A simulation-based study showed that 90% of the space heating and domestic hot water could be provided via solar energy, if seasonal storage was integrated in a cold climate [61]. Similarly, other studies have shown the benefits of borehole thermal energy storage in solar based district heating systems, which can provide seasonal flexibility to the district heating systems [62][63][64]. Borehole thermal energy storage (BTES) was studied in the present study due to its flexibility, simple design, and good ground conditions in Finland [3].…”

Section: Introductionmentioning

confidence: 99%

EU Emission Targets of 2050: Costs and CO2 Emissions Comparison of Three Different Solar and Heat Pump-Based Community-Level District Heating Systems in Nordic Conditions

et al. 2020

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In Finland, old apartments (1980s) contribute toward emissions. The objective is to reduce CO2 emissions to reach Europe’s targets of 2050. Three different centralized solar-based district heating systems integrated either with non-renovated or renovated old buildings in the community were simulated and compared against the reference city-level district heating system. The three proposed centralized systems were: Case 1: photovoltaic (PV) with a ground source heat pump (GSHP); Case 2: PV with an air-water heat pump (A2WHP); and Case 3: PV with A2WHPs, seasonal storage, and GSHPs. TRNSYS simulation software was used for dynamic simulation of the systems. Life cycle cost (LCC), CO2 emissions and purchased electricity were calculated and compared. The results show that the community-level district heating system (Case 3) outperformed Case 1, Case 2, and the city-level district heating. With non-renovated buildings, the relative emissions reduction was 83% when the reference energy system was replaced with Case 3 and the emissions reduction cost was 3.74 €/kg.CO2/yr. The relative emissions reduction was 91% when the buildings were deep renovated and integrated with Case 3 when compared to the reference system with non-renovated buildings and the emission reduction cost was 11.9 €/kg.CO2/yr. Such district heating systems could help in meeting Europe’s emissions target for 2050.

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“…Moreover, from the physical system's perspective, the storage system is an excellent choice for compensating for the uncertainties and improving the operational flexibility of the energy system [28,29]. In the MES, the hybrid energy storage system (HESS) consisting of the battery and thermal energy storage can be equipped to provide extra flexibility for both the electrical power system and heating system, such as balance the source and loads and dealing with the RES fluctuations.…”

Section: Introductionmentioning

confidence: 99%

Optimal Hybrid Energy Storage System Planning of Community Multi-Energy System Based on Two-Stage Stochastic Programming

Shen

Luo

Xiong³

et al. 2021

IEEE Access

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The multi-energy system (MES) provides a good environment for the local consumption of renewable energy such as wind and solar power because of its high operational flexibility. In the MES, the hybrid energy storage system (HESS) composed of the battery and thermal storage tank plays an important role in enhancing reliability, economics, and operational flexibility. Hence, determining the optimal size of HESS in the MES is a critical problem but has not received enough attention. In light of this problem, this paper focuses on the optimal HESS planning problem in the community MES (CMES) under diverse uncertainties. Firstly, a two-stage stochastic planning model is proposed for the CMES to coordinate the optimal long-term HESS allocation and the short-term system operation. The thermal inertia in the heating network, space heating demand, and domestic hot water demand is utilized to reduce both the planning and operational cost. Secondly, a deterministic equivalence is proposed for the two-stage planning model to convert it into a mixed-integer linear programming model, which is then solved by off-the-shelf solvers. Finally, simulation results verify the effectiveness of the proposed method. The results reveal that the HESS can enhance the operational flexibility of the CMES but only needs a very few investment costs and prove that the thermal inertia in the CMES can reduce the investment cost of HESS, the fuel, and the operational maintenance cost.INDEX TERMS Battery, community multi-energy system, hybrid energy storage system, mixed-integer linear programming, operational flexibility, renewable energy, thermal storage tank, two-stage stochastic programming, uncertainty.

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Techno-economic analysis of a solar district heating system with seasonal thermal storage in the UK

Cited by 121 publications

References 31 publications

Cost-benefit analysis of district heating systems using heat from nuclear plants in seven European countries

Cost-benefit analysis of district heating systems using heat from nuclear plants in seven European countries

EU Emission Targets of 2050: Costs and CO2 Emissions Comparison of Three Different Solar and Heat Pump-Based Community-Level District Heating Systems in Nordic Conditions

Optimal Hybrid Energy Storage System Planning of Community Multi-Energy System Based on Two-Stage Stochastic Programming

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