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Abstract

Due to the low thermo-economic performance of solar ORC plants, several studies are ongoing to investigate the potential merits/demerits of biomass hybridization as a retrofit. Although many of such studies have examined the technical and economic viabilities of various hybrid solar-biomass concepts, due attention has not been directed to the area of their sustainability based on the Second Law of Thermodynamics. This study was aimed at investigating the potential effects of biomass hybridization on the exergetic sustainability of an organic Rankine cycle (ORC) power plant. Design data of an existing solar ORC plant currently operational at Ottana (Italy) were employed for analysis. The referenced ORC plant is rated at about 630 kWe, powered at the moment solely by a concentrated solar power (CSP) field, which integrates linear Fresnel collectors with two-tank thermal energy storage (TES) device. Five different exergetic sustainability indicators were employed in this study to assess the aforementioned ORC plant when fed by hybrid solar-biomass energy resources. Results showed the hybrid plant's destruction factor (DF), exergetic sustainability index (ESI), environmental effect factor (EEF), improvement potential rate (IPR), and recoverability ratio (RECR) of 89.40%, 0.119, 8.435, 4744.8 kW, and 0.89, respectively. Additionally, a comparison of the solar-only and the hybrid solar-biomass schemes revealed that biomass hybridization would improve the exergetic sustainability of the ORC plant. Nevertheless, the high value of IPR obtained suggests that ample opportunities would yet exist to further enhance sustainability indices of the studied ORC plant post biomass hybridization. In sum, biomass hybridization of the solar ORC plant considered in this study would enhance sustainability performance but more opportunities would yet exist to further optimize the system.

Keywords

Organic rankine cycle exergy analysis renewable power plant hybrid solar-biomass plant sustainability assessment

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References

Miller

Sorrell

. The future of oil supply. Phil Trans R Soc A 2014; 372: 20130179. http://dx.doi.org/10.1098/rsta.2013.0179

Barbir

Veziroǧlu

Plass

. Environmental damage due to fossil fuels use. Int J Hydrogen Energy 1990; 15: 739–749.

Martins

Felgueiras

Smitkova

, et al. Analysis of fossil fuel energy consumption and environmental impacts in European countries. Energies 2019; 12: 1–11.

Hayat

Ali

Monyake

, et al. Solar energy—A look into power generation, challenges, and a solar-powered future. Int J Energy Res 2019; 43: 1049–1067.

Sathyakala

Gangadharan SSK

. Minimizing the overall loss coefficient of flat plate solar collector using energy, entropy, and exergy analysis. Proc Inst Mech Eng, Part E: J Process Mech Eng. 2021; 235: 1869–1882. https://dx.doi.org/10.1177/095440892110

Adeli

Sobhnamayan

Alavi

, et al. Experimental exergetic performance evaluation of a photovoltaic thermal (PV/T) air collector and comparison with numerical simulation. Proc Inst Mech Eng Part E J Process Mech Eng 2011; 225: 161–172.

Alva

Liu

Huang

, et al. Thermal energy storage materials and systems for solar energy applications. Renewable Sustainable Energy Rev 2017; 68: 693–706. Elsevier Ltd

Modi

Bühler

Andreasen

, et al. A review of solar energy based heat and power generation systems. Renew Sustain Energy Rev [Internet] 2017; 67: 1047–1064. [cited 2020 Jan 7] Available from: https://www.sciencedirect.com/science/article/pii/S1364032116305664.

Hussain

CMI

Norton

Duffy

. Technological assessment of different solar-biomass systems for hybrid power generation in Europe. Renew Sustain Energy Rev 2017; 68: 1115–1129.

10.

Petrollese

Oyekale

Tola

, et al. Optimal ORC configuration for the combined production of heat and power utilizing solar energy and biomass. In: ECOS 2018 - Proceedings of the 31st International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems. 2018.

11.

Middelhoff

Madden

Ximenes

, et al. Assessing electricity generation potential and identifying possible locations for siting hybrid concentrated solar biomass (HCSB) plants in New South Wales (NSW), Australia. Appl Energy [Internet] 2022; 305: 117942. [cited 2021 Oct 6] Available from: https://linkinghub.elsevier.com/retrieve/pii/S0306261921012526.

12.

Middelhoff

Furtado

Peterseim

, et al. Hybrid concentrated solar biomass (HCSB) plant for electricity generation in Australia: design and evaluation of techno-economic and environmental performance. Energy Convers Manag 2021; 240: 114244.

13.

Tilahun

Bhandari

Mamo

. Design optimization of a hybrid solar-biomass plant to sustainably supply energy to industry: methodology and case study. Energy [Internet] 2021; 220: 119736.

14.

Pina

Lozano

Serra

, et al. Design and thermoeconomic analysis of a solar parabolic trough – ORC – biomass cooling plant for a commercial center. Sol Energy 2021; 215: 92–107.

15.

Wang

Lou

, et al. Operation strategy of a hybrid solar and biomass power plant in the electricity markets. Electr Power Syst Res 2019; 167: 183–191.

16.

Pinna-Hernández

Martínez-Soler

Díaz Villanueva

, et al. Selection of biomass supply for a gasification process in a solar thermal hybrid plant for the production of electricity. Ind Crops Prod 2019; 137: 339–346.

17.

Dincer

Rosen

. Exergy. Amsterdam: Elsevier Ltd, 2013.

18.

Midilli

Dincer

. Development of some exergetic parameters for PEM fuel cells for measuring environmental impact and sustainability. Int J Hydrogen Energy [Internet] 2009; 34: 3858–3872. https://dx.doi.org/10.1016/j.ijhydene.2009.02.066.

19.

Caliskan

Dincer

Hepbasli

. Exergetic and sustainability performance comparison of novel and conventional air cooling systems for building applications. Energy Build [Internet] 2011; 43: 1461–1472. https://dx.doi.org/10.1016/j.enbuild.2011.02.006.

20.

Aydin

. Exergetic sustainability analysis of LM6000 gas turbine power plant with steam cycle. Energy [Internet] 2013; 57: 766–774. https://dx.doi.org/10.1016/j.energy.2013.05.018.

21.

Oruc

Baklacioglu

Turan

, et al. Modeling of environmental effect factor and exergetic sustainability index with cuckoo search algorithm for a business jet. Aircr Eng Aerosp Technol [Internet] 2022. https://doi.org/10.1108/AEAT-08-2021-0251 (ahead-of-print).

22.

Maruf

Rabbani

Ashique

, et al. Exergy based evaluation of power plants for sustainability and economic performance identification. Case Stud Therm Eng [Internet] 2021; 28: 101393.

23.

Yildiz

Ergun

Gürel

, et al. Exergy, sustainability and performance analysis of ground source direct evaporative cooling system. Case Stud Therm Eng 2022; 31: 101810.

24.

Soltanian

Kalogirou

Ranjbari

, et al. Exergetic sustainability analysis of municipal solid waste treatment systems: a systematic critical review. Renew Sustain Energy Rev [Internet] 2022; 156: 111975.

25.

Oyekale

Petrollese

Cau

. Modified auxiliary exergy costing in advanced exergoeconomic analysis applied to a hybrid solar-biomass organic Rankine cycle plant. Appl Energy [Internet] 2020; 268: 114888

26.

Oyekale

Petrollese

Heberle

, et al. Exergetic and integrated exergoeconomic assessments of a hybrid solar-biomass organic Rankine cycle cogeneration plant. Energy Convers Manag [Internet] 2020; 215: 112905.

27.

Moharramian

Soltani

Rosen

, et al. Modified exergy and modified exergoeconomic analyses of a solar based biomass co-fired cycle with hydrogen production. Energy 2019; 167: 715–729.

28.

Anvari

Khalilarya

Zare

. Exergoeconomic and environmental analysis of a novel configuration of solar-biomass hybrid power generation system. Energy [Internet] 2018; 165: 776–789. [cited 2019 Aug 19] Available from: https://www.sciencedirect.com/science/article/pii/S0360544218319996.

29.

Sahoo

Kumar

Singh

, et al. Energy, exergy, economic analysis and optimization of polygeneration hybrid solar-biomass system. Appl Therm Eng [Internet] 2018; 145: 685–692. [cited 2019 Aug 20] Available from: https://www.sciencedirect.com/science/article/pii/S135943111832009X.

30.

Oyekale

Heberle

Petrollese

, et al. Biomass retrofit for existing solar organic rankine cycle power plants: conceptual hybridization strategy and techno-economic assessment. Energy Convers Manag [Internet] 2019; 196: 831–845. Available from: https://linkinghub.elsevier.com/retrieve/pii/S0196890419307344.

31.

Petrollese

Cau

Cocco

. The ottana solar facility: dispatchable power from small-scale CSP plants based on ORC systems. Renew Energy [Internet] 2020; 147: 2932–2943. https://doi.org/10.1016/j.renene.2018.07.013.

32.

Oyekale

Petrollese

Vittorio

, et al. Conceptual design and preliminary analysis of a CSP-biomass organic rankine cycle plant. In: 31st International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems, ECOS 2018, Guimaraes; Portugal. 2018.

33.

Kotas

. The exergy method of thermal plant analysis. Butterworths, 1985; 311, pp. 99–161.

34.

Petela

. Exergy of heat radiation. J Heat Transfer 2012; 86: 187.

35.

Cau

Cocco

. Comparison of medium-size concentrating solar power plants based on parabolic trough and linear Fresnel collectors. Energy Procedia [Internet] 2014; 45: 101–110. https://dx.doi.org/10.1016/j.egypro.2014.01.012.

36.

Tsatsaronis

Morosuk

. A general exergy-based method for combining a cost analysis with an environmental impact analysis. Part II - application to a cogeneration system. In: ASME Int Mech Eng Congr Exposition, Proc [Internet] 2009: 463–469. https://www.scopus.com/inward/record.uri?Eid=2-s2.0-70349107997&doi=10.1115%2FIMECE2008-67218&partnerid=40&md5=7fbb0d8361fd9c119b2fa1702b02875b.

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Impacts of biomass hybridization on exergetic sustainability of a solar organic Rankine cycle power plant

Abstract

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