Carnot battery; District heating; Energy management; Energy storage; Rankine cycle; Rule-based control strategy; Renewable Energy, Sustainability and the Environment; Nuclear Energy and Engineering; Fuel Technology; Energy Engineering and Power Technology
Abstract :
[en] To encourage decarbonization and promote a widespread penetration of renewable energy sources in all energy sectors, the development of efficient energy storage systems is essential. Interesting grid-scale electricity storage technologies are the Carnot batteries, whose working principle is based on storing electricity in the form of thermal energy. The charging phase is performed through a heat pump cycle, and the discharging phase is conducted through a heat engine. Since both thermal and electric energy flows are involved, Carnot batteries can be adopted to provide more flexibility in heat and power energy systems. To this aim, efficient scheduling strategies are necessary to manage different energy flows. In this context, this work presents a detailed rule-based control strategy to schedule the synergetic work of a 10-kWe reversible heat pump/organic Rankine cycle Carnot battery integrated to a district heating substation and a photovoltaic power plant, to satisfy a local user's thermal and electric demand. The coupling of a Carnot battery with a district heating substation allows for shaving the thermal demand peaks through the thermal energy stored in the Carnot battery storage, allowing for a downsizing of the district heating substation, with a considerable reduction of the investment costs. Due to the multiplicity of the involved energy flows and the numerous modes of operation, a scheduling logic for the Carnot battery has been developed, to minimize the system operating costs, depending on the boundary conditions. To investigate the influence of the main system design parameters, a detailed and accurate model of the Carnot battery is adopted. Two variants of the reference system, with different heat pump cold source arrangements, are investigated. In the first case, the heat pump absorbs thermal energy from free waste heat. In the second case, the heat pump cold source is the return branch of the district heating substation. The simulation results show that, in the first case, the Carnot battery allows the downsizing of the district heating substation by 47 %, resulting in an annual gain of more than 5000 €. About 70 % of the economic benefit is due to the possibility of reducing the power size of the district heating substation, which can be from 300 to more than 500 kW. The payback period is estimated to be lower than 9 years, while in the second case, the Carnot battery is not able to provide a gain. Eventually, the influence of some parameters, such as the photovoltaic power plant surface, the storage volume, the electricity price profile and the reversible heat pump/organic Rankine cycle specific investment cost, on the techno-economic performance of the system, is investigated through a wide sensitivity analysis. According to the results, the photovoltaic panels surface does not significantly affect the economic gain, while the storage capacity strongly affects the system scheduling and the operating costs. Indeed, it is possible to identify that 13 m3 is the size of the storage volume that minimizes the payback period to 8.22 years, for the considered application. An increase in the electricity price without an increase in the thermal energy price leads to a decrease in economic gain because the benefit brought by the downsizing of district heating is less significant on the economic balance. The specific investment cost of the reversible heat pump/organic Rankine cycle does not influence the operating cost; thus, it does not change the Carnot battery management, nor the economic gain. The specific investment cost affects the payback period, which increases from 8.6 years for a specific cost of 2000 €/kWe to 15.7 years for a specific cost of 5000 €/kWe.
Disciplines :
Energy
Author, co-author :
Poletto, Chiara ; University of Bologna, Bologna, Italy
Dumont, Olivier ; Université de Liège - ULiège > Département d'aérospatiale et mécanique > Systèmes énergétiques
De Pascale, Andrea; University of Bologna, Bologna, Italy
Lemort, Vincent ; Université de Liège - ULiège > Département d'aérospatiale et mécanique > Thermodynamique appliquée
Ottaviano, Saverio ; University of Bologna, Bologna, Italy
Thome, Olivier ; Université de Liège - ULiège > Département d'aérospatiale et mécanique > Systèmes de conversion d'énergie pour un dévelopement durable
Language :
English
Title :
Control strategy and performance of a small-size thermally integrated Carnot battery based on a Rankine cycle and combined with district heating
The work documented in this publication has been funded by the 2021 Scholarship of the Knowledge Center on Organic Rankine Cycle technology (www.kcorc.org). The results were obtained by the collaboration of the Thermodynamics Laboratory of the University of Liège, Belgium, and the Department of Industrial Engineering of the University of Bologna, Italy. This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.
Bouckaert S. et al., Net Zero by 2050: A Roadmap for the Global Energy Sector, 2021, Accessed: Oct. 28, 2022. [Online]. Available: https://trid.trb.org/view/1856381.
Vecchi, A., et al. Carnot Battery development: A review on system performance, applications and commercial state-of-the-art. J Energy Storage, 55, Nov. 2022, 105782, 10.1016/j.est.2022.105782.
Zühlsdorf, B., Bühler, F., Bantle, M., Elmegaard, B., Analysis of technologies and potentials for heat pump-based process heat supply above 150 °C. Energy Convers Manag X, 2, Apr. 2019, 100011, 10.1016/j.ecmx.2019.100011.
Lai, C.S., McCulloch, M.D., Levelized cost of electricity for solar photovoltaic and electrical energy storage. Appl Energy 190 (Mar. 2017), 191–203, 10.1016/j.apenergy.2016.12.153.
Song, Z., et al. Multi-objective optimization of a semi-active battery/supercapacitor energy storage system for electric vehicles. Appl Energy 135 (Dec. 2014), 212–224, 10.1016/j.apenergy.2014.06.087.
Díaz-González, F., Sumper, A., Gomis-Bellmunt, O., Bianchi, F.D., Energy management of flywheel-based energy storage device for wind power smoothing. Appl Energy 110 (Oct. 2013), 207–219, 10.1016/j.apenergy.2013.04.029.
Massaro, M.C., Biga, R., Kolisnichenko, A., Marocco, P., Monteverde, A.H.A., Santarelli, M., Potential and technical challenges of on-board hydrogen storage technologies coupled with fuel cell systems for aircraft electrification. J Power Sources, 555, Jan. 2023, 232397, 10.1016/j.jpowsour.2022.232397.
Hendrick, P., Introduction to Hydro Energy Storage. Cabeza, L.F., (eds.) Encyclopedia of Energy, 2022, Elsevier, Oxford, 100–103, 10.1016/B978-0-12-819723-3.00158-X.
Han, Y., Cui, H., Ma, H., Chen, J., Liu, N., Temperature and pressure variations in salt compressed air energy storage (CAES) caverns considering the air flow in the underground wellbore. J Energy Storage, 52, Aug. 2022, 104846, 10.1016/j.est.2022.104846.
Barbour, E.R., Pottie, D.L.F., Adiabatic compressed air energy storage systems. Cabeza, L.F., (eds.) Encyclopedia of Energy, 2022, Elsevier, Oxford, 188–203, 10.1016/B978-0-12-819723-3.00061-5.
Vecchi, A., Li, Y., Ding, Y., Mancarella, P., Sciacovelli, A., Liquid air energy storage (LAES): A review on technology state-of-the-art, integration pathways and future perspectives. Adv Appl Energy, 3, Aug. 2021, 100047, 10.1016/j.adapen.2021.100047.
Dumont O, Frate GF, Pillai A, Lecompte S, De paepe M, Lemort V. Carnot battery technology: A state-of-the-art review. J. Energy Storage, vol. 32, p. 101756, Dec. 2020, doi: 10.1016/j.est.2020.101756.
Gimeno-Gutiérrez, M., Lacal-Arántegui, R., Assessment of the European potential for pumped hydropower energy storage based on two existing reservoirs. Renew Energy 75 (Mar. 2015), 856–868, 10.1016/j.renene.2014.10.068.
Frate, G.F., Ferrari, L., Desideri, U., Multi-criteria investigation of a pumped thermal electricity storage (PTES) system with thermal integration and sensible heat storage. Energy Convers Manag, 208, Mar. 2020, 112530, 10.1016/j.enconman.2020.112530.
Dumont, O., Lemort, V., Mapping of performance of pumped thermal energy storage (Carnot battery) using waste heat recovery. Energy, 211, Nov. 2020, 118963, 10.1016/j.energy.2020.118963.
Ökten, K., Kurşun, B., Thermo-economic assessment of a thermally integrated pumped thermal energy storage (TI-PTES) system combined with an absorption refrigeration cycle driven by low-grade heat source. J Energy Storage, 51, Jul. 2022, 104486, 10.1016/j.est.2022.104486.
Frate, G.F., Antonelli, M., Desideri, U., A novel Pumped Thermal Electricity Storage (PTES) system with thermal integration. Appl Therm Eng 121 (Jul. 2017), 1051–1058, 10.1016/j.applthermaleng.2017.04.127.
Su, Z., Yang, L., Song, J., Jin, X., Wu, X., Li, X., Multi-dimensional comparison and multi-objective optimization of geothermal-assisted Carnot battery for photovoltaic load shifting. Energy Convers Manag, 289, Aug. 2023, 117156, 10.1016/j.enconman.2023.117156.
Zhang, X., et al. The Carnot batteries thermally assisted by the steam extracted from thermal power plants: A thermodynamic analysis and performance evaluation. Energy Convers Manag, 297, Dec. 2023, 117724, 10.1016/j.enconman.2023.117724.
Xia, R., et al. Comprehensive performance analysis of cold storage Rankine Carnot batteries: Energy, exergy, economic, and environmental perspectives. Energy Convers Manag, 293, Oct. 2023, 117485, 10.1016/j.enconman.2023.117485.
Bellos, E., Thermodynamic analysis of a Carnot battery unit with double exploitation of a waste heat source. Energy Convers Manag, 299, Jan. 2024, 117844, 10.1016/j.enconman.2023.117844.
Torricelli N, Branchini L, De Pascale A, Dumont O, Lemort V. Optimal Management of Reversible Heat Pump/Organic Rankine Cycle Carnot Batteries. J Eng. Gas Turbines Power, 145 (4) 2023, doi: 10.1115/1.4055708.
Bianchi, M., et al. Experimental analysis of a micro-ORC driven by piston expander for low-grade heat recovery. Appl Therm Eng 148 (Feb. 2019), 1278–1291, 10.1016/j.applthermaleng.2018.12.019.
Eppinger, B., Steger, D., Regensburger, C., Karl, J., Schlücker, E., Will, S., Carnot battery: Simulation and design of a reversible heat pump-organic Rankine cycle pilot plant. Appl Energy, 288, Apr. 2021, 116650, 10.1016/j.apenergy.2021.116650.
Dumont, O., Lemort, V., Thermo-technical approach to characterize the performance of a reversible heat pump/organic Rankine cycle power system depending on its operational conditions. ECOS 2019, 2019.
Abarr, M., Hertzberg, J., Montoya, L.D., Pumped Thermal Energy Storage and Bottoming System Part B: Sensitivity analysis and baseline performance. Energy 119 (Jan. 2017), 601–611, 10.1016/j.energy.2016.11.028.
Yu, X., Qiao, H., Yang, B., Zhang, H., Thermal-economic and sensitivity analysis of different Rankine-based Carnot battery configurations for energy storage. Energy Convers Manag, 283, May 2023, 116959, 10.1016/j.enconman.2023.116959.
Niu, J., Wang, J., Liu, X., Dong, L., Optimal integration of solar collectors to Carnot battery system with regenerators. Energy Convers Manag, 277, Feb. 2023, 116625, 10.1016/j.enconman.2022.116625.
Tassenoy, R., Couvreur, K., Beyne, W., De Paepe, M., Lecompte, S., Techno-economic assessment of Carnot batteries for load-shifting of solar PV production of an office building. Renew Energy 199 (Nov. 2022), 1133–1144, 10.1016/j.renene.2022.09.039.
Lin, X., Sun, P., Zhong, W., Wang, J., Thermodynamic analysis and operation investigation of a cross-border integrated energy system based on steam Carnot battery. Appl Therm Eng, 220, Feb. 2023, 119804, 10.1016/j.applthermaleng.2022.119804.
Scharrer, D., Bazan, P., Pruckner, M., German, R., Simulation and analysis of a Carnot Battery consisting of a reversible heat pump/organic Rankine cycle for a domestic application in a community with varying number of houses. Energy, 261, Dec. 2022, 125166, 10.1016/j.energy.2022.125166.
Dumont, O., Reyes, A., Lemort, V., Modelling of a thermally integrated Carnot battery using a reversible heat pump/organic Rankine cycle. presented at the ecos conference, 2020.
Dumont, O., Investigation of a heat pump reversible into an organic Rankine cycle and its application in the building sector. PhD Dissertation, 2017.
Ancona, M.A., et al. Solar driven micro-ORC system assessment for residential application. Renew Energy 195 (Aug. 2022), 167–181, 10.1016/j.renene.2022.06.007.
Dickes, R., Dumont, O., Daccord, R., Quoilin, S., Lemort, V., Modelling of organic Rankine cycle power systems in off-design conditions: An experimentally-validated comparative study. Energy 123 (Mar. 2017), 710–727, 10.1016/j.energy.2017.01.130.
Lemort V. Contribution to the characterization of scroll machines in compressor and expander modes. University of Liège; 2008.
Landelle, A., Tauveron, N., Revellin, R., Haberschill, P., Colasson, S., Roussel, V., Performance investigation of reciprocating pump running with organic fluid for organic Rankine cycle. Appl Therm Eng 113 (Feb. 2017), 962–969, 10.1016/j.applthermaleng.2016.11.096.
Dumont O, Charalampidis A, Lemort V. Experimental Investigation Of A Thermally Integrated Carnot Battery Using A Reversible Heat Pump/Organic Rankine Cycle. Int. Refrig. Air Cond. Conf., May 2021, [Online]. Available: https://docs.lib.purdue.edu/iracc/2085.
Powell, K.M., Edgar, T.F., An adaptive-grid model for dynamic simulation of thermocline thermal energy storage systems. Energy Convers Manag 76 (Dec. 2013), 865–873, 10.1016/j.enconman.2013.08.043.
Nash, A.L., Badithela, A., Jain, N., Dynamic modeling of a sensible thermal energy storage tank with an immersed coil heat exchanger under three operation modes. Appl Energy 195 (Jun. 2017), 877–889, 10.1016/j.apenergy.2017.03.092.
Patankar, S., Numerical Heat Transfer and Fluid Flow. Boca Raton: CRC Press, 2018, 10.1201/9781482234213.
“JRC Photovoltaic Geographical Information System (PVGIS) - European Commission.” Accessed: Feb. 10, 2023. [Online]. Available: https://re.jrc.ec.europa.eu/pvg_tools/it/#MR.
Kang, A., Korolija, I., Rovas, D., Photovoltaic Thermal District Heating: A review of the current status, opportunities and prospects. Appl Therm Eng, 217, Nov. 2022, 119051, 10.1016/j.applthermaleng.2022.119051.
Obalanlege, M.A., Mahmoudi, Y., Douglas, R., Ebrahimnia-Bajestan, E., Davidson, J., Bailie, D., Performance assessment of a hybrid photovoltaic-thermal and heat pump system for solar heating and electricity. Renew Energy 148 (Apr. 2020), 558–572, 10.1016/j.renene.2019.10.061.
Mi, P., Zhang, J., Han, Y., Guo, X., Study on energy efficiency and economic performance of district heating system of energy saving reconstruction with photovoltaic thermal heat pump. Energy Convers Manag, 247, Nov. 2021, 114677, 10.1016/j.enconman.2021.114677.
Parra, D., Walker, G.S., Gillott, M., Are batteries the optimum PV-coupled energy storage for dwellings? Techno-economic comparison with hot water tanks in the UK. Energy Build 116 (Mar. 2016), 614–621, 10.1016/j.enbuild.2016.01.039.
Pakere, I., Lauka, D., Blumberga, D., Solar power and heat production via photovoltaic thermal panels for district heating and industrial plant. Energy 154 (Jul. 2018), 424–432, 10.1016/j.energy.2018.04.138.
Bell IH, Wronski J, Quoilin S, Lemort V. Pure and Pseudo-pure Fluid Thermophysical Property Evaluation and the Open-Source Thermophysical Property Library CoolProp. Ind. Eng. Chem. Res., vol. 53, no. 6, Art. no. 6, Feb. 2014, doi: 10.1021/ie4033999.
Yuan, X., Liang, Y., Hu, X., Xu, Y., Chen, Y., Kosonen, R., Waste heat recoveries in data centers: A review. Renew Sustain Energy Rev, 188, Dec. 2023, 113777, 10.1016/j.rser.2023.113777.
Villasmil, W., Fischer, L.J., Worlitschek, J., A review and evaluation of thermal insulation materials and methods for thermal energy storage systems. Renew Sustain Energy Rev 103 (Apr. 2019), 71–84, 10.1016/j.rser.2018.12.040.
Lemmens S. Cost Engineering Techniques and Their Applicability for Cost Estimation of Organic Rankine Cycle Systems. Energies, vol. 9, no. 7, Art. no. 7, Jul. 2016, doi: 10.3390/en9070485.
Shamoushaki, M., Niknam, P.H., Talluri, L., Manfrida, G., Fiaschi, D., Development of cost correlations for the economic assessment of power plant equipment. Energies, 14(9), 2021, 10.3390/en14092665.
Dumont, O., Carmo, C., Georges, E., Quoilin, S., Lemort, V., Economic assessment of electric energy storage for load shifting in positive energy building. Int J Energy Environ Eng 8:1 (Mar. 2017), 25–35, 10.1007/s40095-016-0224-2.
Résimont MT. Strategic outline and sizing of district heating networks using a geographic information system.” Accessed: Apr. 18, 2023. [Online]. Available: https://www.fsa.uliege.be/cms/c_7790914/en/strategic-outline-and-sizing-of-district-heating-networks-using-a-geographic-information-system.
Baetens, R., et al. Assessing electrical bottlenecks at feeder level for residential net zero-energy buildings by integrated system simulation. Appl Energy 96 (Aug. 2012), 74–83, 10.1016/j.apenergy.2011.12.098.
Lecompte S. Performance evaluation of organic Rankine cycle architectures : application to waste heat valorisation, dissertation, Ghent University, 2016. Accessed: Mar. 09, 2023. [Online]. Available: http://hdl.handle.net/1854/LU-7223134.
