References
- ABB,2020. Achieving improved fuel efficiency with waste heat recovery. https://library.e.abb.com/public/5f7cac28e876a9cbc1257a8a003cc6dc/ABB%20Generations_28%20Achieving%20improved%20fuel%20efficiency%20with%20waste%20heat%20recovery.pdf accessed 2020 03 September
- Agarwal, M., 2021. Ship’s main engine lubrication system explained. https://www.marineinsight.com/tech/ships-main-engine-lubrication-system-explained/ (accessed 2022 23 March).
- Akman, M., and S. Ergin. 2019. An investigation of marine waste heat recovery system based on organic Rankine cycle under various engine operating conditions. Proc. Inst. Mech. Eng. Part M: J. Eng. Marit. Environ 233:586–601. https://doi.org/10.1177/2F1475090218770947
- Akman, M., and S. Ergin. 2021. Thermo-environmental analysis and performance optimisation of transcritical organic Rankine cycle system for waste heat recovery of a marine diesel engine. Ships Offshore Struct 16:1104–13. doi:10.1080/17445302.2020.1816744.
- Al‐Nimr, M. D. A., and A. A. Alajlouni. 2018. Internal combustion engine waste heat recovery by a thermoelectric generator inserted at combustion chamber walls. Int. J. Energy Res 42:4853–65. doi:10.1002/er.4241.
- Alshammari, F., M. Usman, and A. Pesyridis. 2018. Expanders for organic Rankine cycle technology. In organic rankine cycle technology for heat recovery, ed. E. Wang, 41–59. London: IntechOpen.
- Andreasen, J. G., A. Meroni, and F. Haglind. 2017. A comparison of organic and steam Rankine cycle power systems for waste heat recovery on large ships. Energies 10:547. doi:10.3390/en10040547.
- ASHRAE, 2019. Standards 15 & 34. https://www.ashrae.org/technical-resources/bookstore/standards-15-34 (accessed 2021 16 January).
- Baek, J. S., E. A. Groll, and P. B. Lawless. 2005. Piston-cylinder work producing expansion device in a transcritical carbon dioxide cycle. Part I: Experimental investigation. Int. J. Refrig 28:141–51. doi:10.1016/j.ijrefrig.2004.08.006.
- Baldasso, E., J. G. Andreasen, A. Meroni, and F. Haglind, 2017. Performance analysis of different organic Rankine cycle configurations on board liquefied natural gas-fuelled vessels, in: Proceedings of ECOS 2017: 30th International Conference on Efficiency, Cost, Optimization, Simulation and Environmental Impact of Energy Systems. San Diego, California.
- Baldasso, E., J. G. Andreasen, M. E. Mondejar, U. Larsen, and F. Haglind. 2019. Technical and economic feasibility of organic Rankine cycle-based waste heat recovery systems on feeder ships: Impact of nitrogen oxides emission abatement technologies. Energy Convers. Manage 183:577–89. doi:10.1016/j.enconman.2018.12.114.
- Baldi, F., and C. Gabrielii. 2015. A feasibility analysis of waste heat recovery systems for marine applications. Energy 80:654–65. doi:10.1016/j.energy.2014.12.020.
- Baldi, F., U. Larsen, and C. Gabrielii. 2015. Comparison of different procedures for the optimisation of a combined diesel engine and organic Rankine cycle system based on ship operational profile. Ocean Eng 110:85–93. doi:10.1016/j.oceaneng.2015.09.037.
- Bao, J., and L. Zhao. 2013. A review of working fluid and expander selections for organic Rankine cycle. Renew. Sustain. Energy Rev 24:325–42. doi:10.1016/j.rser.2013.03.040.
- Bartlett, D. A. 1996. The fundamentals of heat exchangers. The Industrial Physicist 2:18–21.
- Bellolio, S. A. D., V. Lemort, and P. Rico, 2015. Organic Rankine cycles systems for waste heat recovery in marine applications. https://orbi.uliege.be/bitstream/2268/189044/1/University%20of%20Liege%20Bellolio_Marine_ORC_SCC2015.pdf (accessed 2021 28 May).
- Bianchi, G., F. Fatigati, S. Murgia, and R. Cipollone. 2017. Design and analysis of a sliding vane pump for waste heat to power conversion systems using organic fluids. Appl. Therm. Eng 124:1038–48. doi:10.1016/j.applthermaleng.2017.06.083.
- Biederman, T. R., and J. J. Brasz, 2014. Geothermal ORC systems using large screw expanders. https://docs.lib.purdue.edu/icec/2348/ (accessed 2020 18 June).
- Boretti, A. 2012. Recovery of exhaust and coolant heat with R245fa organic Rankine cycles in a hybrid passenger car with a naturally aspirated gasoline engine. Appl. Therm. Eng 36:73–77. doi:10.1016/j.applthermaleng.2011.11.060.
- Bounefour, O., A. Ouadha, and Y. Addad. 2020. An exergy analysis of various layouts of ORC-VCC systems for usage in waste heat recovery onboard ships. Mar. Syst. Ocean Technol 15:26–44. doi:10.1007/s40868-020-00072-6.
- Brückner, S., S. Liu, L. Miró, M. Radspieler, L. F. Cabeza, and E. Lävemann. 2015. Industrial waste heat recovery technologies: An economic analysis of heat transformation technologies. Applied Energy 151:157–67. doi:10.1016/j.apenergy.2015.01.147.
- Campana, F., M. Bianchi, L. Branchini, A. De Pascale, A. Peretto, M. Baresi, A. Fermi, N. Rosetti, and R. Vescovo. 2013. ORC waste heat recovery in European energy intensive industries: energy and GHG savings. Energy Convers. Manage 76:244–52. doi:10.1016/j.enconman.2013.07.041.
- Cao, Y., M. Delpisheh, S. Yousefiasl, H. Athari, M. A. El-Shorbagy, F. Jarad, M. Dahari, and M. Wae-hayee. 2022. Examination and optimization of a novel auxiliary trigeneration system for a ship through waste-to-energy from its engine. Case Stud. Therm. Eng 31:101860. doi:10.1016/j.csite.2022.101860.
- Catapano, F., A. Frazzica, A. Freni, M. Manzan, D. Micheli, V. Palomba, P. Sementa, and B. M. Vaglieco. 2022. Development and experimental testing of an integrated prototype based on Stirling, ORC and a latent thermal energy storage system for waste heat recovery in naval application. Applied Energy 311:118673. doi:10.1016/j.apenergy.2022.118673.
- Champier, D. 2017. Thermoelectric generators: A review of applications. Energy Convers. Manage 140:167–81. doi:10.1016/j.enconman.2017.02.070.
- Chatzopoulou, M. A., M. Simpson, P. Sapin, and C. N. Markides. 2019. Off-design optimisation of organic Rankine cycle (ORC) engines with piston expanders for medium-scale combined heat and power applications. Applied Energy 238:1211–36. doi:10.1016/j.apenergy.2018.12.086.
- Chen, H., D. Y. Goswami, and E. K. Stefanakos. 2010. A review of thermodynamic cycles and working fluids for the conversion of low-grade heat. Renew. Sustain. Energy Rev 14:3059–67. doi:10.1016/j.rser.2010.07.006.
- Chintala, V., S. Kumar, and J. K. Pandey. 2018. A technical review on waste heat recovery from compression ignition engines using organic Rankine cycle. Renew. Sustain. Energy Rev 81:493–509. doi:10.1016/j.rser.2018.03.074.
- Choi, B. C., and Y. M. Kim. 2013. Thermodynamic analysis of a dual loop heat recovery system with trilateral cycle applied to exhaust gases of internal combustion engine for propulsion of the 6800 TEU container ship. Energy 58:404–16. doi:10.1016/j.energy.2013.05.017.
- CIMAC, 2008. Guidelines for the lubrication of medium speed diesel engines. https://www.cimac.com/cms/upload/Publication_Press/Recommendations/Recommendation_29.pdf (accessed 2020 15 September).
- Cision, 2015. Climeon’s groundbreaking heat-power solution wins prestigious award for marine energy savings. https://news.cision.com/climeon/r/climeon-s-groundbreaking-heat-power-solution-wins-prestigious-award-for-marine-energy-savings,c9872748 (accessed 2022 21 March).
- Climeon, 2021a. case study: the scarlet lady. https://climeon.com/case-study-virgin-voyages/ (accessed 2021 29 May).
- Climeon, 2021b. Climeon completes second sea trials with Virgin Voyages and Fincantieri. https://climeon.com/climeon-completes-second-sea-trials-with-virgin-voyages-and-fincantieri/ (accessed 2021 29 May).
- Climeon, 2022. climeon producing heat power on board Maersk vessel. https://climeon.com/climeon-producing-heat-power-on-board-maersk-vessel/ (accessed 2022 31 March).
- Cohen, L., and W. A. Fritz, Jr. 1962. efficiency determination of marine boilers: input-output versus heat-loss method. ASME J. Eng. Power 84:39–43. doi:10.1115/1.3673375.
- Costa, V. A. F., L. A. C. Tarelho, and A. Sobrinho. 2019. Mass, energy and exergy analysis of a biomass boiler: A Portuguese representative case of the pulp and paper industry. Appl. Therm. Eng 152:350–61. doi:10.1016/j.applthermaleng.2019.01.033.
- Couvreur, K., W. Beyne, M. De Paepe, and S. Lecompte. 2020. Hot water storage for increased electricity production with organic Rankine cycle from intermittent residual heat sources in the steel industry. Energy 200:117501. doi:10.1016/j.energy.2020.117501.
- D’Amico, F., P. Pallis, A. D. Leontaritis, S. Karellas, N. M. Kakalis, S. Rech, and A. Lazzaretto. 2018. Semi-empirical model of a multi-diaphragm pump in an organic Rankine cycle (ORC) experimental unit. Energy 143:1056–71. doi:10.1016/j.energy.2017.10.127.
- Danieli, P., S. Rech, and A. Lazzaretto. 2019. Supercritical CO2 and air Brayton-Joule versus ORC systems for heat recovery from glass furnaces: performance and economic evaluation. Energy 168:295–309. doi:10.1016/j.energy.2018.11.089.
- David, G., F. Michel, and L. Sanchez, 2011. Waste heat recovery projects using organic Rankine cycle technology–examples of biogas engines and steel mills applications. https://www.yumpu.com/en/document/view/9238424/orc-whr-applications-enertime (accessed 2021 28 September).
- Dincer, I. 2018. Refrigerants. In comprehensive energy systems. volume 2: energy materials, ed. I. Dincer, 435–74. Amsterdam: Elsevier.
- DNV, 2022. MRV and DCS. https://www.dnv.com/maritime/insights/topics/MRV-and-DCS/index.html (accessed 2022 08 April).
- Dumont, O., R. Dickes, and V. Lemort. 2017. Experimental investigation of four volumetric expanders. Energy Procedia 129:859–66. doi:10.1016/j.egypro.2017.09.206.
- Dumont, O., L. Talluri, D. Fiaschi, G. Manfrida, and V. Lemort, 2019. Comparison of a scroll, a screw, a roots, a piston expander and a Tesla turbine for small-scale organic Rankine cycle. https://orbi.uliege.be/handle/2268/239272 (accessed 2021 02 June).
- Durmusoglu, Y., T. Satir, C. Deniz, and A. Kilic, 2009. A novel energy saving and power production system performance analysis in marine power plant using waste heat, in: Proceedings of 2009 International Conference on Machine Learning and Applications. Florida: IEEE, pp. 751–54. doi:10.1109/ICMLA.2009.34.
- Elson, A., R. Tidball, and A. Hampson, 2015. Waste heat to power market assessment. https://www.osti.gov/biblio/1185773 (accessed 2021 29 September).
- Emhardt, S., G. Tian, and J. Chew. 2018. A review of scroll expander geometries and their performance. Appl. Therm. Eng 141:1020–34. doi:10.1016/j.applthermaleng.2018.06.045.
- EPA, 2020. International actions - the Montreal Protocol on substances that deplete the ozone layer. https://www.epa.gov/ozone-layer-protection/international-actions-montreal-protocol-substances-deplete-ozone-layer#:~:text=The%20Montreal%20Protocol%20is%20signed,most%20successful%20environmental%20global%20action.&text=The%20Montreal%20Protocol%20celebrated%20its%2030th%20anniversary%20in%202017 (accessed 2021 16 January).
- European Commission, 2019. Communication from the commission to the European parliament, the European council, the council, the European economic and social committee and the committee of the regions - the European green deal. https://ec.europa.eu/info/sites/info/files/european-green-deal-communication_en.pdf (accessed 2020 04 September).
- Eyidogan, M., F. C. Kilic, D. Kaya, V. Coban, and S. Cagman. 2016. Investigation of organic Rankine cycle (ORC) technologies in Turkey from the technical and economic point of view. Renew. Sustain. Energy Rev 58:885–95. doi:10.1016/j.rser.2015.12.158.
- Faber, J., S. Hanayama, S. Zhang, P. Pereda, B. Comer, B. Hauerhof, and Kosaka, H. 2020. fourth IMO GHG study 2020 - final report. MEPC 75 (7/15): 1–295. CE Delft, Delft.
- Fiaschi, D., G. Manfrida, and F. Maraschiello. 2012. Thermo-fluid dynamics preliminary design of turbo-expanders for ORC cycles. Applied Energy 97:601–08. doi:10.1016/j.apenergy.2012.02.033.
- Fiaschi, D., and L. Talluri. 2019. Design and off-design analysis of a Tesla turbine utilizing CO2 as working fluid. E3S Web Conf 113:03008. doi:10.1051/e3sconf/201911303008.
- Fierro, J. J., A. Escudero-Atehortua, C. Nieto-Londoño, M. Giraldo, H. Jouhara, and L. C. Wrobel. 2020. Evaluation of waste heat recovery technologies for the cement industry. Int. J. Thermofluids 7:100040. doi:10.1016/j.ijft.2020.100040.
- Fuente, S., and A. L. Greig, 2013. Making shipping greener: ORC modelling under realistic operative conditions. https://discovery.ucl.ac.uk/id/eprint/1545538/ (accessed 2020 11 May).
- Fuente, S. S., U. Larsen, R. Pawling, I. G. Kerdan, A. Greig, and R. Bucknall. 2018. Using the forward movement of a container ship navigating in the arctic to air-cool a marine organic Rankine cycle unit. Energy 159:1046–59. doi:10.1016/j.energy.2018.06.143.
- Gerretsen, I., 2022. EU carbon tax puts a price on shipping emissions. https://chinadialogue.net/en/transport/eu-carbon-tax-puts-a-price-on-shipping-emissions/#:~:text=Ships%20emit%20around%20one%20billion,to%20the%20World%20Economic%20Forum (accessed 2022 08 March).
- Haglind, F., M. E. M. Montagud, J. G. Andreasen, L. Pierobon, and A. Meroni, 2017. Organic Rankine cycle unit for waste heat recovery on ships (PilotORC). https://orbit.dtu.dk/en/publications/organic-rankine-cycle-unit-for-waste-heat-recovery-on-ships-pilot (accessed 2021 28 June).
- Havila, 2022. Havila Voyages confirms May start date for second ship. https://www.havilavoyages.com/about-havila/media/venter-havila-castor-i-drift-i-mai (accessed 2022 23 March).
- He, T., H. Lv, Z. Shao, J. Zhang, X. Xing, and H. Ma. 2020. Cascade utilization of LNG cold energy by integrating cryogenic energy storage, organic Rankine cycle and direct cooling. Applied Energy 277:115570. doi:10.1016/j.apenergy.2020.115570.
- Hewitt, G. F., G. L. Shires, and T. R. Bott. 1994. Process Heat Transfer. Boca Raton, FL: CRC press.
- Hood, J., M. Smith, G. Shields, S. Calvert, B. Boykin, and A. Gallagher, 2017. Colorado recycled energy market overview. Updated Report. https://www.colorado.gov/pacific/sites/default/files/atoms/files/CEO%20Recycled%20Energy%20Market%20Overview%20-%20Updated%202017.pdf (accessed 2021 07 September).
- IMO, 2019. Initial IMO GHG strategy. https://www.imo.org/en/MediaCentre/HotTopics/Pages/Reducing-greenhouse-gas-emissions-from-ships.aspx (accessed 2022 08 March).
- Imran, M., M. Usman, B. S. Park, and D. H. Lee. 2016. Volumetric expanders for low grade heat and waste heat recovery applications. Renew. Sustain. Energy Rev 57:1090–109. doi:10.1016/j.rser.2015.12.139.
- Kakac, S., H. Liu, and A. Pramuanjaroenkij. 2020. heat exchangers: selection, rating, and thermal design. fourth ed. Boca Raton: CRC Press.
- Kalikatzarakis, M., and C. Frangopoulos. 2015. Multi-criteria selection and thermo-economic optimization of organic Rankine cycle system for a marine application. Int. J. Thermodyn 18:133–41. doi:10.5541/ijot.5000075305.
- Kaya, İ., A. S. Karakurt, and Y. Üst. 2020. Investigation of waste heat energy in a marine engine with transcritical organic Rankine cycle. J. Therm. Eng 6:282–96. doi:10.18186/thermal.711489.
- Kimball, R., and T. Wallace, 2019. Development of thermoelectric exhaust generator (TEG) heat recovery systems for marine diesels: Final report. https://mainemaritime.edu/metel/wp-content/uploads/sites/15/2019/04/TEG-Final-Report.pdf (accessed 2021 03 May).
- Kobelco,2020. Kobe Steel, Mitsui O.S.K. Lines to conduct long-term operational tests of a binary cycle power generation system installed on an actual ship. https://www.kobelco.co.jp/english/releases/1206451_15581.html (accessed 2021 28 May).
- Kobelco, 2017. Binary cycle power generation system for ships completes sea trials, Kobe Steel to begin sales of the new system in 2019. https://www.kobelco.co.jp/english/releases/1196609_15581.html (accessed 2021 28 May).
- Kolasiński, P. 2020. The method of the working fluid selection for organic Rankine cycle (ORC) systems employing volumetric expanders. Energies 13:573. doi:10.3390/en13030573.
- Konur, O., O. Y. Saatcioglu, S. A. Korkmaz, A. Erdogan, and C. O. Colpan. 2020. Heat exchanger network design of an organic Rankine cycle integrated waste heat recovery system of a marine vessel using pinch point analysis. Int. J. Energy Res 44:12312–28. doi:10.1002/er.5212.
- Koroglu, T., and O. S. Sogut. 2017. Advanced exergy analysis of an organic Rankine cycle waste heat recovery system of a marine power plant. J. Therm. Eng 3:1136–48. doi:10.18186/thermal.298614.
- Kosmadakis, G., and P. Neofytou, 2021. Performance and economic evaluation of a reversible high-temperature heat pump/ORC for waste heat recovery in the marine sector, in: Proceedings of the 6th International Seminar on ORC Power Systems, Munich, Germany. https://mediatum.ub.tum.de/doc/1632824/1632824.pdf (accessed 2022 29 March).
- Lampart, P., and Ł. Jędrzejewski. 2011. Investigations of aerodynamics of Tesla bladeless microturbines. J. Theor. Appl. Mech 49:477–99.
- Larsen, U., L. Pierobon, F. Haglind, and C. Gabrielii. 2013. Design and optimisation of organic Rankine cycles for waste heat recovery in marine applications using the principles of natural selection. Energy 55:803–12. doi:10.1016/j.energy.2013.03.021.
- Larsen, U., J. Wronski, J. G. Andreasen, F. Baldi, and L. Pierobon. 2017. Expansion of organic Rankine cycle working fluid in a cylinder of a low-speed two-stroke ship engine. Energy 119:1212–20. doi:10.1016/j.energy.2016.11.069.
- Latarche, M. 2020. Pounder’s Marine Diesel Engines and Gas Turbines. tenth. UK: Butterworth-Heinemann.
- Lecompte, S., H. Huisseune, M. Van Den Broek, B. Vanslambrouck, and M. De Paepe. 2015. Review of organic Rankine cycle (ORC) architectures for waste heat recovery. Renew. Sustain. Energy Rev 47:448–61. doi:10.1016/j.rser.2015.03.089.
- Lemort, V., L. Guillaume, A. Legros, S. Declaye, and S. Quoilin, 2013. A comparison of piston, screw and scroll expanders for small scale Rankine cycle systems, in: Proceedings of the 3rd International Conference on Microgeneration and Related Technologies Naples, Italy. http://hdl.handle.net/2268/147369 (accessed 2020 23 July).
- Leontaritis, A. D., P. Pallis, S. Karellas, A. Papastergiou, N. Antoniou, P. Vourliotis, N. M. Kakalis, and G. Dimopoulos, 2015. Experimental study on a low temperature ORC unit for onboard waste heat recovery from marine diesel engines. http://asme-orc2015.fyper.com/proceedings/documents/55.pdf (accessed 2021 10 May).
- Li, G. 2016. Organic Rankine cycle performance evaluation and thermoeconomic assessment with various applications part I: Energy and exergy performance evaluation. Renew. Sustain. Energy Rev 53:477–99. doi:10.1016/j.rser.2015.08.066.
- Linde Industrial Gases, 2021. Refrigerants. https://www.linde-gas.com/en/products_and_supply/refrigerants/index.html (accessed 2021 16 January).
- Lindeman, L., V. S. Canales, L. O’donoghue, A. H. Hassan, J. M. Corberan, and J. Payá, 2019. Thermodynamic analysis of a high temperature heat pump coupled with an organic Rankine cycle for energy storage, in: XI National and II International Engineering Thermodynamics Congress Proceedings, Ingles, Albacete, pp. 72–83.
- Line, V., 2014. Viking Grace first ship to install new Swedish heat recovery system. https://www.vikingline.com/globalassets/documents/market_specific/corporate/press/pressrelease-eng/2014/20141201-climeon-eng.pdf (accessed 2022 22 March).
- Line, V., 2019. Viking Glory will be one of the most climate-smart passenger ships in the world. https://www.vikingline.com/press-room-old/press-releases/358C04145790BDD4 (accessed 2022 22 March).
- Lion, S., R. Taccani, I. Vlaskos, P. Scrocco, X. Vouvakos, and L. Kaiktsis. 2019. Thermodynamic analysis of waste heat recovery using organic Rankine cycle (ORC) for a two-stroke low speed marine diesel engine in IMO Tier II and Tier III operation. Energy 183:48–60. doi:10.1016/j.energy.2019.06.123.
- Lion, S., I. Vlaskos, C. Rouaud, and R. Taccani, 2016. First and second law analysis of internal combustion engines and waste heat recovery with organic Rankine cycle (ORC). https://www.researchgate.net/publication/308209345_First_and_Second_Law_Analysis_of_Internal_Combustion_Engines_and_Waste_Heat_Recovery_with_Organic_Rankine_Cycle_ORC (accessed 2021 25 June).
- Liu, C., H. Li, W. Ye, J. Liu, H. Wang, M. Xu, Pan, X., Mao, Z., and Yang, S. 2021a. Simulation research of TEG-ORC combined cycle for cascade recovery of vessel waste heat. Int. J. Green Energy 18:1173–84. doi:10.1080/15435075.2021.1897824.
- Liu, C., J. Liu, W. Ye, H. Li, C. Zhao, H. Wang, Xu, M., and Pan, X. 2021b. Study on a new cascade utilize method for ship waste heat based on TEG‐ORC combined cycle. Environ. Prog. Sustain. Energy 40:e13661. doi:10.1002/ep.13661.
- Liu, X., M. Q. Nguyen, J. Chu, T. Lan, and M. He. 2020a. A novel waste heat recovery system combining steam Rankine cycle and organic Rankine cycle for marine engine. J. Clean. Prod 265:121502. doi:10.1016/j.jclepro.2020.121502.
- Liu, X., M. Q. Nguyen, and M. He. 2020b. Performance analysis and optimization of an electricity-cooling cogeneration system for waste heat recovery of marine engine. Energy Convers. Manage 214:112887. doi:10.1016/j.enconman.2020.112887.
- Liu, C., W. Ye, H. Li, J. Liu, C. Zhao, Z. Mao, and X. Pan. 2021c. Experimental study on cascade utilization of ship’s waste heat based on TEG‐ORC combined cycle. Int. J. Energy Res 45:4184–96. doi:10.1002/er.6083.
- Loni, R., G. Najafi, E. Bellos, F. Rajaee, Z. Said, and M. Mazlan. 2021. A review of industrial waste heat recovery system for power generation with organic Rankine cycle: Recent challenges and future outlook. J. Clean. Prod 287:125070. doi:10.1016/j.jclepro.2020.125070.
- LR, 2022. EEXI - Energy Efficiency Existing Ship Index: don’t wait. act now. https://www.lr.org/en/eexi-energy-efficiency-existing-ship-index/ (accessed 2022 08 April).
- Lu, H., L. Price, and Q. Zhang. 2016. Capturing the invisible resource: analysis of waste heat potential in Chinese industry. Applied Energy 161:497–511. doi:10.1016/j.apenergy.2015.10.060.
- Ma, Z., J. Wu, and Y. Zhang. 2018. Performance optimization of organic Rankine cycles for waste heat recovery for a large diesel engine. Arch. Therm 39:3–23.
- Macchi, E., and M. Astolfi. 2017. Axial flow turbines for organic Rankine cycle applications. In organic Rankine cycle (orc) power systems, ed. E. Macchi and M. Astolfi, 299–319. UK: Woodhead Publishing.
- MAN Diesel & Turbo, 2014a. Waste heat recovery system (WHRS) for the reduction of fuel consumption, emissions and EEDI: Technical paper. https://mandieselturbo.com/docs/librariesprovider6/technical-papers/waste-heat-recovery-system.pdf (accessed 2020 04 December).
- MAN Diesel & Turbo, 2014b. Soot deposits and fires in exhaust gas boilers: Technical report. MAN, Copenhagen, Denmark.
- MAN Diesel & Turbo, 2016. MAN Cryo - Marine LNG fuel gas systems. http://www.golng.eu/files/upload/untitled%20MAN%20flyer.pdf (accessed 2021 07 October).
- MAN Energy Solutions, 2017. MAN B&W two-stroke marine engines emission project guide for Marpol annex VI regulations. https://marine.man-es.com/applications/projectguides/2stroke/content/special_pg/PG_7020-0145-10.pdf (accessed 2021 01 January).
- MAN Energy Solutions, 2020. TCX - exponential turbocharging. https://turbocharger.man-es.com/products/tcx (accessed 2020 09 September).
- Manolakos, D., G. Kosmadakis, E. Ntavou, and B. Tchanche. 2019. Test results for characterizing two in-series scroll expanders within a low-temperature ORC unit under partial heat load. Appl. Therm. Eng 163:114389. doi:10.1016/j.applthermaleng.2019.114389.
- Maraver, D., J. Royo, V. Lemort, and S. Quoilin. 2014. Systematic optimization of subcritical and transcritical organic Rankine cycles (ORCs) constrained by technical parameters in multiple applications. Applied Energy 117:11–29. doi:10.1016/j.apenergy.2013.11.076.
- Marine, O., 2012. Commissioning and testing of first reference installation of Opcon technology for ships. http://opconenergysystem.com/wp-content/uploads/2015/10/Opcon-Powerbox-ORC-brochure.pdf (accessed 2019 15 April).
- MEPC, I. M. O. 2012. 2012 guidelines for the development of a ship energy efficiency management plan (SEEMP). Resolution MEPC 213 (63):1–13. MEPC 63/23 Annex 9.
- Mersch, M., 2019. Development of an experimentally validated organic Rankine cycle model using computer-aided molecular design tools for the optimisation of waste-heat recovery systems. M.Sc. Thesis, Imperial College London, London, UK.
- Mitsubishi Heavy Industries, 2016. MHI-MME WHRS – STG: Environment friendly and economical solution. https://www.mhi-mme.com/products/boilerturbine/WHRS_Presentation.pdf (accessed 2020 03 September).
- MIURA, 2008. What is the boiler efficiency. https://www.miuraz.co.jp/en/marine/pdf/news2.pdf (accessed 2021 20 February).
- MOL, 2020. MOL and Kobe Steel start long-term application test of ‘binary cycle power generation system for ships’ - reducing vessel GHG emissions with more effective use of energy -. https://www.mol.co.jp/en/pr/2020/20089.html;2020 (accessed 2021 28 May).
- Mondejar, M. E., F. Ahlgren, M. Thern, and M. Genrup. 2017. Quasi-steady state simulation of an organic Rankine cycle for waste heat recovery in a passenger vessel. Applied Energy 185:1324–35. doi:10.1016/j.apenergy.2016.03.024.
- Mondejar, M. E., J. G. Andreasen, L. Pierobon, U. Larsen, M. Thern, and F. Haglind. 2018. A review of the use of organic Rankine cycle power systems for maritime applications. Renew. Sustain. Energy Rev 91:126–51. doi:10.1016/j.rser.2018.03.074.
- Morais, P. H., A. Lodi, A. Aoki, and M. Modesto. 2020. Energy, exergetic and economic analyses of a combined solar-biomass-ORC cooling cogeneration systems for a Brazilian small plant. Renew. Energy 157:1131–347. doi:10.1016/j.renene.2020.04.147.
- Motorship, 2020. ORC installation economics depend on component trade-offs. https://www.motorship.com/news101/ships-equipment/orc-installation-economics-depend-on-component-trade-offs (accessed 2021 26 May).
- Naveiro, M., M. R. Gómez, I. Arias-Fernández, and Á. B. Insua. 2022. Thermodynamic and environmental analyses of a novel closed loop regasification system integrating ORC and CO2 capture in floating storage regasification units. Energy Convers. Manage 257:115410. doi:10.1016/j.enconman.2022.115410.
- Nawi, Z. M., S. K. Kamarudin, S. S. Abdullah, and S. S. Lam. 2019. The potential of exhaust waste heat recovery (WHR) from marine diesel engines via organic Rankine cycle. Energy 166:17–31. doi:10.1016/j.energy.2018.10.064.
- Ng, C., I. C. Tam, and D. Wu, 2019. Study of a waste energy driven organic Rankine cycle using free piston linear expander for marine applications. https://www.orc2019.com/online/proceedings/documents/55.pdf (accessed 2021 19 March).
- Nielsen, R. F., F. Haglind, and U. Larsen. 2014. Design and modeling of an advanced marine machinery system including waste heat recovery and removal of sulphur oxides. Energy Convers. Manage 85:687–93. doi:10.1016/j.enconman.2014.03.038.
- Nonthakarn, P., M. Ekpanyapong, U. Nontakaew, and E. Bohez. 2019. Design and optimization of an integrated turbo-generator and thermoelectric generator for vehicle exhaust electrical energy recovery. Energies 12:3134. doi:10.3390/en12163134.
- NRCAN, 2018. Boiler system energy losses. https://www.nrcan.gc.ca/mining-materials/publications/boiler-system-energy-losses/5431 (accessed 2021 20 February).
- Orcan Energy AG, 2017. Efficiency & emissions improvements for maritime applications. https://sustainable-maritime-solutions.nl/wp-content/uploads/sites/14/dlm_uploads/2018/03/Efficiency-_emissions-improvements_maritime-applications-Orcan_Energy-version-11.0.pdf (accessed 2021 27 May).
- Orcan Energy AG, 2018. From the docks to the sea - A field report. https://www.orcan-energy.com/en/details/from-the-docks-to-the-sea-a-field-report-64.html (accessed 2021 28 May).
- Orcan Energy AG, 2019. Maximum energy recycling on board: Inland waterway ship “Maranta” uses waste heat with an efficiency PACK from Orcan Energy. https://www.orcan-energy.com/en/details/maximum-energy-recycling-on-board-inland-waterway-ship-maranta-uses-waste-heat-with-an-efficiency-pack-from-orcan-energy.html (accessed 2021 28 May).
- Orcan Energy AG, 2020a. We generate clean electricity from your waste heat. http://www.artidenizcilik.com/images/galeri/09f9594e1f2c45fdab48e50181fac4f3_orcan-energy_marine-presentation_v4.1__2nd-gtsf-_hamburg_mf.pdf (accessed 2021 27 May).
- Orcan Energy AG, 2020b. Optimised energy recycling on board: clean, energy-efficient ferries commence their journeys on the Wadden Sea with waste heat recovery technology from Orcan Energy. https://www.orcan-energy.com/en/details/optimised-energy-recycling-on-board-clean-energy-efficient-ferries-commence-their-journeys-on-the-wadden-sea-with-waste-heat-recovery-technology-from-orcan-energy.html (accessed 2021 26 May).
- Orcan Energy AG, 2020c. Waste heat recovery technology from Orcan Energy on energy efficient tanker for the first time. https://www.orcan-energy.com/en/details/waste-heat-recovery-technology-from-orcan-energy-on-energy-efficient-tanker-for-the-first-time.html (accessed 2021 25 May).
- Orcan Energy AG, 2020d. Largest order for Orcan Energy in the company’s history in the marine sector: Eight efficiency PACKs for offshore installation ship “Green Jade.” https://www.orcan-energy.com/en/details/largest-order-for-orcan-energy-in-the-companys-history-in-the-marine-sector.html (accessed 2021 28 May).
- Orcan Energy AG, 2021. Van Oord relies on waste heat recovery: Maritime energy efficiency solution from Orcan Energy installed for the first time on two dredgers. https://www.orcan-energy.com/en/details/van-oord-relies-on-waste-heat-recovery-maritime-energy-efficiency-solution-from-orcan-energy-installed-for-the-first-time-on-two-dredgers.html (accessed 2022 22 March).
- Ouyang, T., G. Huang, Y. Lu, B. Liu, and X. Hu. 2021a. Multi-criteria assessment and optimization of waste heat recovery for large marine diesel engines. J. Clean. Prod 309:127307. doi:10.1016/j.jclepro.2021.127307.
- Ouyang, T., J. Tan, S. Xie, W. Wu, and Z. Su. 2021b. A new scheme for large marine vessels LNG cold energy utilization from thermodynamic and thermoeconomic viewpoints. Energy Convers. Manage 229:113770. doi:10.1016/j.enconman.2020.113770.
- Oyewunmi, O. A., A. M. Pantaleo, and C. N. Markides. 2017. ORC cogeneration systems in waste-heat recovery applications. Energy Procedia 142:1736–42. doi:10.1016/j.egypro.2017.12.557.
- Öhman, H., and P. Lundqvist. 2013. Comparison and analysis of performance using low temperature power cycles. Appl. Therm. Eng 52:160–69. doi:10.1016/j.applthermaleng.2012.11.024.
- Pallis, P., E. Varvagiannis, K. Braimakis, T. Roumpedakis, A. D. Leontaritis, and S. Karellas. 2021. Development, experimental testing and techno-economic assessment of a fully automated marine organic rankine cycle prototype for jacket cooling water heat recovery. Energy 228:120596. doi:10.1016/j.energy.2021.120596.
- Pantaleo, A. M., J. Fordham, O. A. Oyewunmi, P. De Palma, and C. N. Markides. 2018. Integrating cogeneration and intermittent waste-heat recovery in food processing: Microturbines vs. ORC systems in the coffee roasting industry. Applied Energy 225:782–96. doi:10.1016/j.apenergy.2018.04.097.
- Pantano, F., and R. Capata. 2017. Expander selection for an on board ORC energy recovery system. Energy 141:1084–96. doi:10.1016/j.energy.2017.09.142.
- Papapetrou, M., G. Kosmadakis, A. Cipollina, U. La Commare, and G. Micale. 2018. Industrial waste heat: estimation of the technically available resource in the EU per industrial sector, temperature level and country. Appl. Therm. Eng 138:207–16. doi:10.1016/j.applthermaleng.2018.04.043.
- Peris, B., J. Navarro-Esbrí, F. Molés, and A. Mota-Babiloni. 2015. Experimental study of an ORC (organic Rankine cycle) for low grade waste heat recovery in a ceramic industry. Energy 85:534–42. doi:10.1016/j.energy.2015.03.065.
- Power, M., 2020. Products. https://power.mhi.com/products (accessed 2020 03 September).
- Qu, J., Y. Feng, Y. Zhu, S. Zhou, and W. Zhang. 2021. Design and thermodynamic analysis of a combined system including steam Rankine cycle, organic Rankine cycle, and power turbine for marine low-speed diesel engine waste heat recovery. Energy Convers. Manage 245:114580. doi:10.1016/j.enconman.2021.114580.
- Quoilin, S., M. Van Den Broek, S. Declaye, P. Dewallef, and V. Lemort. 2013. Techno-economic survey of organic Rankine cycle (ORC) systems. Renew. Sustain. Energy Rev 22:168–86. doi:10.1016/j.rser.2013.01.028.
- Radulovic, J., 2016a. Exergo-economic analysis of waste heat organic Rankine cycle. https://repository.up.ac.za/handle/2263/62091 (accessed 2021 10 August).
- Radulovic, J. 2016b. Performance of low GWP fluids in heat pump systems. J. Therm. Eng 2:748–53.
- Rech, S., S. Zandarin, A. Lazzaretto, and C. A. Frangopoulos. 2017. Design and off-design models of single and two-stage ORC systems on board a LNG carrier for the search of the optimal performance and control strategy. Applied Energy 204:221–41. doi:10.1016/j.apenergy.2017.06.103.
- Report, R., 2020. Refrigerant report. https://www.bitzer-refrigerantreport.com/fileadmin/user_upload/A-501-20.pdf (accessed 2021 16 January).
- Rosset, K., V. Mounier, E. Guenat, and J. Schiffmann. 2018. Multi-objective optimization of turbo-ORC systems for waste heat recovery on passenger car engines. Energy 159:751–65. doi:10.1016/j.energy.2018.06.193.
- Ryu, B. R., D. P. Anh, Y. H. Lee, and H. K. Kang. 2021. Study on LNG cold energy recovery using combined refrigeration and ORC system: LNG-fueled refrigerated cargo carriers. J. Korean Soc. Mar. Eng 45:70–78. doi:10.5916/jamet.2021.45.2.70.
- Saadon, S., and S. M. S. Islam. 2019. A recent review in performance of organic Rankine cycle (ORC). In Organic Rankine cycles for waste heat recovery - analysis and applications, ed. S. Lasala, 1–16. London: IntechOpen.
- Saghlatoun, S., W. Zhuge, and Y. Zhang. 2014. Review of expander selection for small-scale organic Rankine cycle. In fluids engineering division summer meeting ASME Fluids Engineering Division , V01BT10A041. Chicago, Illinois: ASME. doi:10.1115/FEDSM2014-21904.
- Sanguri, M., 2019. Slow steaming of ships: Checks and precautions. https://www.marineinsight.com/main-engine/slow-steaming-of-ships-checks-and-precautions/#:~:text=Avoid%20water%20condensation%20in%20air,hot%20well%20by%20bypass%20valve (accessed 2020 03 September).
- Santarossa, S., and A. Barbon, 2020. Save the heat – Boost your cement process waste gas (Turboden). https://www.worldcement.com/sustainability/presentations/turboden/ (accessed 2020 19 December).
- Sellers, C. 2017. Field operation of a 125kW ORC with ship engine jacket water. Energy Proceedia 129:495–502. doi:10.1016/j.egypro.2017.09.168.
- Shah, R. K., and D. P. Sekulic. 2003. fundamentals of heat exchanger design. New Jersey: John Wiley & Sons.
- Shi, L., G. Shu, H. Tian, and S. Deng. 2018. A review of modified organic Rankine cycles (ORCs) for internal combustion engine waste heat recovery (ICE-WHR). Renew. Sustain. Energy Rev 92:95–110. doi:10.1016/j.rser.2018.04.023.
- Sivaramakrishnaiah, M., Y. S. K. Reddy, and G. S. Reddy. 2017. Study and design of bladeless Tesla turbine. Int. J. Theor. Appl. Mech 12:881–89.
- Smith, D. W., J. Crawford, and P. S. Moore. 2016. Marine auxiliary machinery. sixth ed. London, UK: Butterworths.
- Smith, T. W. P., J. P. Jalkanen, B. A. Anderson, J. J. Corbett, J. Faber, S. Hanayama, and C. Raucci. 2014. Third IMO GHG study 2014. London: International Maritime Organization (IMO).
- Soffiato, M., C. A. Frangopoulos, G. Manente, S. Rech, and A. Lazzaretto. 2015. Design optimization of ORC systems for waste heat recovery on board a LNG carrier. Energy Convers. Manage 92:523–34. doi:10.1016/j.enconman.2014.12.085.
- Song, J., Y. Li, C. W. Gu, and L. Zhang. 2014. Thermodynamic analysis and performance optimization of an ORC (organic Rankine cycle) system for multi-strand waste heat sources in petroleum refining industry. Energy 71:673–80. doi:10.1016/j.energy.2014.05.014.
- Song, J., Y. Song, and C. W. Gu. 2015. Thermodynamic analysis and performance optimization of an Organic Rankine Cycle (ORC) waste heat recovery system for marine diesel engines. Energy 82:976–85. doi:10.1016/j.energy.2015.01.108.
- Sun, Z., J. Lai, S. Wang, and T. Wang. 2018. Thermodynamic optimization and comparative study of different ORC configurations utilizing the exergies of LNG and low grade heat of different temperatures. Energy 147:688–700. doi:10.1016/j.energy.2018.01.085.
- Sung, T., and K. C. Kim. 2016. Thermodynamic analysis of a novel dual-loop organic Rankine cycle for engine waste heat and LNG cold. Appl. Therm. Eng 100:1031–41. doi:10.1016/j.applthermaleng.2016.02.102.
- Sung, T., and K. C. Kim. 2017. An organic Rankine cycle for two different heat sources: Steam and hot water. Energy Procedia 129:883–90. doi:10.1016/j.egypro.2017.09.251.
- Talluri, L., O. Dumont, G. Manfrida, V. Lemort, and D. Fiaschi. 2020. Experimental investigation of an organic Rankine cycle Tesla turbine working with R1233zd (E). Appl. Therm. Eng 174:115293. doi:10.1016/j.applthermaleng.2020.115293.
- Tartière, T., and M. Astolfi. 2017. A world overview of the organic Rankine cycle market. Energy Procedia 129:2–9. doi:10.1016/j.egypro.2017.09.159.
- Tchanche, B. F., G. Lambrinos, A. Frangoudakis, and G. Papadakis. 2011. Low-grade heat conversion into power using organic Rankine cycles – A review of various applications. Renew. Sustain. Energy. Rev 15:3963–79. doi:10.1016/j.rser.2011.07.024.
- Thimmanoor, S., 2018. Organic Rankine cycle as waste heat recovery system for marine application: Screening methodology, modelling and analysis. M.Sc. Thesis, Delft, Delft University of Technology.
- Thulukkanam, K. 2013. Heat Exchanger Design Handbook. second ed. Boca Raton: CRC press.
- Tian, Z., Y. Yue, B. Gu, W. Gao, and Y. Zhang. 2020. Thermo‐economic analysis and optimization of a combined organic Rankine cycle (ORC) system with LNG cold energy and waste heat recovery of dual‐fuel marine engine. Int. J. Energy Res 44:9974–94. doi:10.1002/er.5529.
- Tian, Z., W. Zeng, B. Gu, Y. Zhang, and X. Yuan. 2021. Energy, exergy, and economic (3E) analysis of an organic Rankine cycle using zeotropic mixtures based on marine engine waste heat and LNG cold energy. Energy Convers. Manage 228:113657. doi:10.1016/j.enconman.2020.113657.
- Tocci, L., T. Pal, I. Pesmazoglou, and B. Franchetti. 2017. Small scale organic Rankine cycle (ORC): A techno-economic review. Energies 10:413. doi:10.3390/en10040413.
- Tsougranis, E. L., and D. Wu. 2018. A feasibility study of organic Rankine cycle (ORC) power generation using thermal and cryogenic waste energy on board an LNG passenger vessel. Int. J. Energy Res 42:3121–42. doi:10.1002/er.4047.
- Turboden, 2014. The first electric arc furnace waste heat recovery ORC-based system is in commercial operation at Feralpi steel plant in Germany. https://www.turboden.com/company/media/press/press-releases/1541/the-first-electric-arc-furnace-waste-heat-recovery-orc-based-system-is-in-commercial-operation-at-feralpi-steel-plant-in-germany (accessed 2020 19 December).
- Turboden, 2017. Turboden to supply a 6 MW ORC unit for a glass factory in Turkey. https://www.turboden.com/company/media/press/press-releases/1672/turboden-to-supply-a-6-mw-orc-unit-for-a-glass-factory-in-turkey (accessed 2020 19 December).
- TÜV NORD, 2019. A brief history of the internal combustion engine. https://www.tuev-nord.de/explore/en/remembers/a-brief-history-of-the-internal-combustion-engine/ (accessed 2020 04 December).
- Ustaoglu, A., M. Alptekin, and M. E. Akay. 2017. Thermal and exergetic approach to wet type rotary kiln process and evaluation of waste heat powered ORC (organic Rankine cycle). Appl. Therm. Eng 112:281–95. doi:10.1016/j.applthermaleng.2016.10.053.
- Uusitalo, A., J. Nerg, A. Grönman, S. Nikkanen, and M. Elg. 2019. Numerical analysis on utilizing excess steam for electricity production in cruise ships. J. Clean. Prod 209:424–38. doi:10.1016/j.jclepro.2018.10.279.
- Vallero, D. A. 2019. Air pollution biogeochemistry. In Air pollution calculations: quantifying pollutant formation, transport, transformation, fate and risks, ed. D. A. Vallero, 175–206. Oxford, UK: Elsevier.
- Vance, D., S. Nimbalkar, A. Thekdi, K. Armstrong, T. Wenning, J. Cresko, and M. Jin. 2019. Estimation of and barriers to waste heat recovery from harsh environments in industrial processes. J. Clean. Prod 222:539–49. doi:10.1016/j.jclepro.2019.03.011.
- Virgin, 2022. Virgin Voyages welcomes its second ship Valiant Lady. https://www.virgin.com/about-virgin/latest/virgin-voyages-welcomes-its-second-ship-valiant-lady (accessed 2022 22 March).
- Wang, X., Shu, G.Q., Tian, H., Liang, Y., Wang, X., 2014. Simulation and analysis of an ORC-desalination combined system driven by the waste heat of charge air at variable operation conditions. SAE Tech. Pap. 2014-01-1949, 1–10. https://doi.org/10.4271/2014-01-1949.
- Wang, F., L. Wang, H. Zhang, L. Xia, H. Miao, and J. Yuan. 2021. Design and optimization of hydrogen production by solid oxide electrolyzer with marine engine waste heat recovery and ORC cycle. Energy Convers. Manage 229:113775. doi:10.1016/j.enconman.2020.113775.
- Wartsila, 2020. Gas turbine for power generation: Introduction. https://www.wartsila.com/energy/learn-more/technical-comparisons/gas-turbine-for-power-generation-introduction (accessed 2020 03 September).
- Weiß, A. P., 2015. Volumetric expander versus turbine–which is the better choice for small ORC plants. http://asme-orc2015.fyper.com/uploads/File/Presentation%20022.pdf (accessed 2021 15 March).
- Woodyard, D. 2009. Pounder’s Marine Diesel Engines and Gas Turbines. ninth. UK: Butterworth-Heinemann.
- Yang, M. H. 2016. Optimizations of the waste heat recovery system for a large marine diesel engine based on transcritical Rankine cycle. Energy 113:1109–24. doi:10.1016/j.energy.2016.07.152.
- Yang, M. H. 2018. Payback period investigation of the organic Rankine cycle with mixed working fluids to recover waste heat from the exhaust gas of a large marine diesel engine. Energy Convers. Manage 162:189–202. doi:10.1016/j.enconman.2018.02.032.
- Yang, M. H., and R. H. Yeh. 2014. Analyzing the optimization of an organic Rankine cycle system for recovering waste heat from a large marine engine containing a cooling water system. Energy Convers. Manage 88:999–1010. doi:10.1016/j.enconman.2014.09.044.
- Yang, M. H., and R. H. Yeh. 2015a. Thermodynamic and economic performances optimization of an organic Rankine cycle system utilizing exhaust gas of a large marine diesel engine. Applied Energy 149:1–12. doi:10.1016/j.apenergy.2015.03.083.
- Yang, M. H., and R. H. Yeh. 2015b. Thermo-economic optimization of an organic Rankine cycle system for large marine diesel engine waste heat recovery. Energy 82:256–68. doi:10.1016/j.energy.2015.01.036.
- Yu, H., J. Eason, L. T. Biegler, and X. Feng. 2017. Simultaneous heat integration and techno-economic optimization of organic Rankine cycle (ORC) for multiple waste heat stream recovery. Energy 119:322–33. doi:10.1016/j.energy.2016.12.061.
- Yuksek, E. L., and P. Mirmobin, 2015. Waste heat utilization of main propulsion engine jacket water in marine application. http://asme-orc2015.fyper.com/uploads/File/All-Papers-ORC2015.pdf (accessed 2021 15 March).
- Yuksel, O., Y. Gulmez, O. Konur, S. A. Korkmaz, A. Erdogan, and C. O. Colpan. 2019. Performance assessment of a marine freshwater generator through exergetic optimization. J. Clean. Prod 219:326–35. doi:10.1016/j.jclepro.2019.02.083.
- Yuksel, O., and B. Koseoglu. 2022. Numerical simulation of the hybrid ship power distribution system and an analysis of its emission reduction potential. Ships and Offshore Structures 1–17. doi:10.1080/17445302.2022.2028435.
- Yun, E., H. Park, S. Y. Yoon, and K. C. Kim. 2015. Dual parallel organic Rankine cycle (ORC) system for high efficiency waste heat recovery in marine application. J. Mech. Sci. Technol 29:2509–15. doi:10.1007/s12206-015-0548-5.
- Zhang, X., L. Wu, X. Wang, and G. Ju. 2016. Comparative study of waste heat steam SRC, ORC and S-ORC power generation systems in medium-low temperature. Appl. Therm. Eng 106:1427–39. doi:10.1016/j.applthermaleng.2016.06.108.
- Zhang, X., C. Zhang, M. He, and J. Wang. 2019. Selection and evaluation of dry and isentropic organic working fluids used in organic Rankine cycle based on the turning point on their saturated vapor curves. J. Therm. Sci 28:643–58. doi:10.1007/s11630-019-1149-x.
- Zhu, Y., W. Li, G. Sun, and H. Li. 2018. Thermo-economic analysis based on objective functions of an organic Rankine cycle for waste heat recovery from marine diesel engine. Energy 158:343–56. doi:10.1016/j.energy.2018.06.047.
- Zhu, S., K. Zhang, and K. Deng. 2020. A review of waste heat recovery from the marine engine with highly efficient bottoming power cycles. Renew. Sustain. Energy Rev 120:109611. doi:10.1016/j.rser.2019.109611.
- Ziviani, D., A. Beyene, and M. Venturini. 2014. Advances and challenges in ORC systems modeling for low grade thermal energy recovery. Applied Energy 121:79–95. doi:10.1016/j.apenergy.2014.01.074.
- Zogogianni, C. G., N. A. Zarkadis, and E. C. Tatakis, 2016. Energy savings in marine applications using thermoelectric modules and high step-up DC/DC converter. https://ieeexplore.ieee.org/document/7739491 (accessed 2021 02 June).
- Zywica, G., T. Z. Kaczmarczyk, and E. Ihnatowicz. 2016. A review of expanders for power generation in small-scale organic Rankine cycle systems: performance and operational aspects. Proc. IMechE, Part A: J. Power and Energy 230:669–84. doi:10.1177/0957650916661465. accessed 30 march 2022