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An experimental study of energy balance in low heat rejection diesel engine

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  • Taymaz, Imdat

Abstract

In a conventional internal combustion engine, approximately one-third of total fuel input energy is converted to useful work. Since the working gas in a practical engine cycle is not exhausted at ambient temperature, a major part of the energy is lost with the exhaust gases. In addition, another major part of energy input is rejected in the form of heat via the cooling system. If the energy normally rejected to the coolant could be recovered instead on the crankshaft as useful work, then a substantial improvement in fuel economy would result. In this study, the effect of insulated heat transfer surfaces on diesel engine energy balance system was investigated. The research engine was a four-stroke, direct injected, six cylinder, turbocharged and inter-cooled diesel engine. This engine was tested at different speeds and load conditions without coating. Then, combustion chamber surfaces, cylinder head, valves and piston crown faces were coated with ceramic materials. Ceramic layers were made of CaZrO3 and MgZrO3 and plasma coated onto base of the NiCrAl bond coat. The ceramic-coated research engine was tested at the same operation conditions as the standard (without coating) engine. The results indicate a reduction in fuel consumption and heat losses to engine cooling system of the ceramic-coated engine.

Suggested Citation

  • Taymaz, Imdat, 2006. "An experimental study of energy balance in low heat rejection diesel engine," Energy, Elsevier, vol. 31(2), pages 364-371.
    • Handle: RePEc:eee:energy:v:31:y:2006:i:2:p:364-371
    DOI: 10.1016/j.energy.2005.02.004
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    1. Aghaali, Habib & Ångström, Hans-Erik, 2015. "A review of turbocompounding as a waste heat recovery system for internal combustion engines," Renewable and Sustainable Energy Reviews, Elsevier, vol. 49(C), pages 813-824.
    2. Jagtap, Sharad P. & Pawar, Anand N. & Lahane, Subhash, 2020. "Improving the usability of biodiesel blend in low heat rejection diesel engine through combustion, performance and emission analysis," Renewable Energy, Elsevier, vol. 155(C), pages 628-644.
    3. Yao, Zhi-Min & Qian, Zuo-Qin & Li, Rong & Hu, Eric, 2019. "Energy efficiency analysis of marine high-powered medium-speed diesel engine base on energy balance and exergy," Energy, Elsevier, vol. 176(C), pages 991-1006.
    4. Abedin, M.J. & Masjuki, H.H. & Kalam, M.A. & Sanjid, A. & Rahman, S.M. Ashrafur & Masum, B.M., 2013. "Energy balance of internal combustion engines using alternative fuels," Renewable and Sustainable Energy Reviews, Elsevier, vol. 26(C), pages 20-33.
    5. Payri, Francisco & López, José Javier & Martín, Jaime & Carreño, Ricardo, 2018. "Improvement and application of a methodology to perform the Global Energy Balance in internal combustion engines. Part 1: Global Energy Balance tool development and calibration," Energy, Elsevier, vol. 152(C), pages 666-681.
    6. Chintala, Venkateswarlu & Subramanian, K.A., 2014. "Assessment of maximum available work of a hydrogen fueled compression ignition engine using exergy analysis," Energy, Elsevier, vol. 67(C), pages 162-175.
    7. Magno, Agnese & Mancaruso, Ezio & Vaglieco, Bianca Maria, 2015. "Effects of both blended and pure biodiesel on waste heat recovery potentiality and exhaust emissions of a small CI (compression ignition) engine," Energy, Elsevier, vol. 86(C), pages 661-671.
    8. Karthikeyan, B. & Srithar, K., 2011. "Performance characteristics of a glowplug assisted low heat rejection diesel engine using ethanol," Applied Energy, Elsevier, vol. 88(1), pages 323-329, January.
    9. Yao, Mingfa & Ma, Tianyu & Wang, Hu & Zheng, Zunqing & Liu, Haifeng & Zhang, Yan, 2018. "A theoretical study on the effects of thermal barrier coating on diesel engine combustion and emission characteristics," Energy, Elsevier, vol. 162(C), pages 744-752.
    10. Dong, Guangyu & Morgan, Robert E. & Heikal, Morgan R., 2016. "Thermodynamic analysis and system design of a novel split cycle engine concept," Energy, Elsevier, vol. 102(C), pages 576-585.
    11. Haifeng Liu & Junsheng Ma & Laihui Tong & Guixiang Ma & Zunqing Zheng & Mingfa Yao, 2018. "Investigation on the Potential of High Efficiency for Internal Combustion Engines," Energies, MDPI, vol. 11(3), pages 1-20, February.
    12. Li, Yongliang & Sciacovelli, Adriano & Peng, Xiaodong & Radcliffe, Jonathan & Ding, Yulong, 2016. "Integrating compressed air energy storage with a diesel engine for electricity generation in isolated areas," Applied Energy, Elsevier, vol. 171(C), pages 26-36.
    13. Shin, Yoon Hyuk & Kim, Sung Chul & Kim, Min Soo, 2013. "Use of electromagnetic clutch water pumps in vehicle engine cooling systems to reduce fuel consumption," Energy, Elsevier, vol. 57(C), pages 624-631.
    14. Calise, Francesco & de Notaristefani di Vastogirardi, Giulio & Dentice d'Accadia, Massimo & Vicidomini, Maria, 2018. "Simulation of polygeneration systems," Energy, Elsevier, vol. 163(C), pages 290-337.
    15. Junhong Zhang & Zhexuan Xu & Jiewei Lin & Zefeng Lin & Jingchao Wang & Tianshu Xu, 2018. "Thermal Characteristics Investigation of the Internal Combustion Engine Cooling-Combustion System Using Thermal Boundary Dynamic Coupling Method and Experimental Verification," Energies, MDPI, vol. 11(8), pages 1-20, August.
    16. Fu, Jianqin & Liu, Jingping & Feng, Renhua & Yang, Yanping & Wang, Linjun & Wang, Yong, 2013. "Energy and exergy analysis on gasoline engine based on mapping characteristics experiment," Applied Energy, Elsevier, vol. 102(C), pages 622-630.
    17. Fu, Jianqin & Liu, Jingping & Xu, Zhengxin & Ren, Chengqin & Deng, Banglin, 2013. "A combined thermodynamic cycle based on methanol dissociation for IC (internal combustion) engine exhaust heat recovery," Energy, Elsevier, vol. 55(C), pages 778-786.
    18. Gogoi, T.K. & Baruah, D.C., 2011. "The use of Koroch seed oil methyl ester blends as fuel in a diesel engine," Applied Energy, Elsevier, vol. 88(8), pages 2713-2725, August.
    19. Fu, Jianqin & Liu, Jingping & Ren, Chengqin & Wang, Linjun & Deng, Banglin & Xu, Zhengxin, 2012. "An open steam power cycle used for IC engine exhaust gas energy recovery," Energy, Elsevier, vol. 44(1), pages 544-554.
    20. Shabashevich, A. & Richards, N. & Hwang, J. & Erickson, P.A., 2015. "Analysis of powertrain design on effective waste heat recovery from conventional and hybrid electric vehicles," Applied Energy, Elsevier, vol. 157(C), pages 754-761.
    21. Francesco Madaro & Iman Mehdipour & Antonio Caricato & Francesco Guido & Francesco Rizzi & Antonio Paolo Carlucci & Massimo De Vittorio, 2020. "Available Energy in Cars’ Exhaust System for IoT Remote Exhaust Gas Sensor and Piezoelectric Harvesting," Energies, MDPI, vol. 13(16), pages 1-15, August.
    22. Şahin, Z. & Durgun, O. & Bayram, C., 2008. "Experimental investigation of gasoline fumigation in a single cylinder direct injection (DI) diesel engine," Energy, Elsevier, vol. 33(8), pages 1298-1310.
    23. Martín, Jaime & Novella, Ricardo & García, Antonio & Carreño, Ricardo & Heuser, Benedikt & Kremer, Florian & Pischinger, Stefan, 2016. "Thermal analysis of a light-duty CI engine operating with diesel-gasoline dual-fuel combustion mode," Energy, Elsevier, vol. 115(P1), pages 1305-1319.
    24. Serge Nyallang Nyamsi & Ivan Tolj & Mykhaylo Lototskyy, 2019. "Metal Hydride Beds-Phase Change Materials: Dual Mode Thermal Energy Storage for Medium-High Temperature Industrial Waste Heat Recovery," Energies, MDPI, vol. 12(20), pages 1-27, October.
    25. Rattner, Alexander S. & Garimella, Srinivas, 2011. "Energy harvesting, reuse and upgrade to reduce primary energy usage in the USA," Energy, Elsevier, vol. 36(10), pages 6172-6183.

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