ABSTRACT
The Diesel engine is expected to be available for operation at high altitude. However, power loss and emission deterioration have been plaguing highland Diesel engines. Therefore, this study aimed to investigate the impact of altitude on the performance and combustion characteristics of Diesel engines that is limited discussed in existing studies. The research was conducted by varying the altitude from 0-4500 m using a research Diesel engine and analyzing the combustion characteristics at different combustion phases with the help of triple Wiebe function. The results indicated a noticeable drop in power output with increasing altitude, and the deterioration of performance and emissions became significant when the altitude exceeded 3000 m. Specifically, the indicated specific CO, unburned hydrocarbon, and soot emissions increased while nitrogen NOx showed a reverse trend. Additionally, it was found that the lower cylinder pressure at high altitude extended the ignition delay and caused a higher heat release rate in the premixed combustion stage. Moreover, the high altitude condition shortened the duration of combustion and reduced the energy release fraction in the diffusion phase. Furthermore, the late combustion phase occurred earlier and lasted longer at high altitude, which consequently reduced the combustion and thermal efficiency. The most important finding is that the engine performance, especially the combustion efficiency, shows an abrupt degradation with altitudes above 3000 m. As a result, engines operating at extremely high altitudes require multi-stage turbocharging to compensate for combustion deterioration.
KEYWORDS
PAPER SUBMITTED: 2023-02-27
PAPER REVISED: 2023-05-03
PAPER ACCEPTED: 2023-06-29
PUBLISHED ONLINE: 2023-10-08
THERMAL SCIENCE YEAR
2024, VOLUME
28, ISSUE
Issue 2, PAGES [1621 - 1634]
- Eckerle, W., et al., Future Challenges for Engine Manufacturers in View of Future Emissions Legislation, SAE Technical Paper, 2017-01-1923, 2017
- Khalife, E., et al., Impacts of Additives on Performance and Emission Characteristics of Diesel Engines During Steady-State Operation, Progress in energy and Combustion Science, 59 (2017), Mar., pp. 32-78
- Zhu, Z., et al., Genetic Algorithm Optimization Applied to the Fuel Supply Parameters of Diesel Engines Working at Plateau, Applied Energy, 157 (2015), Nov., pp. 789-797
- Liu, J., et al., An Examination of Performance Deterioration Indicators of Diesel Engines on the Plateau. Energy, 262 (2023), 125587
- Zhang, H., et al., Study of the control strategy of the plateau self-adapted turbocharging system for diesel engine, SAE Technical Paper, 2008-01-1636, 2008
- Szedlmayer, M., et al., Effect of Altitude Conditions on Combustion and Performance of a Multi-Cylinder Turbocharged Direct-Injection Diesel Engine, SAE Technical Paper, 2016-01-0742, 2016
- Li, H.Y., et al., Experimental Study on Knocking Combustion in Compressionignition Engines under High-Altitude Conditions, Journal of Physics: Conference Series, 1507 (2020), 3, 032024
- Gan, Q., et al., Effects of Altitude Variation on Cylinder Pressure Signal of Diesel Engine, Vehicle Engine, 2018 (2018), 2, pp. 74-78+86
- Benjumea, P., et al., Effect of Altitude and Palm Oil Biodiesel Fuelling on the Performance and Combustion Characteristics of a HSDI Diesel Engine, Fuel, 88 (2009), 4, pp.725-731
- Liu, Z., Liu, J., Investigation of the Effect of Altitude on in-Cylinder Heat Transfer in Heavy-Duty Diesel Engines Based on an Empirical Model, Journal of Energy Resources Technology, 144 (2022), 11, 112303
- Wang, X., et al., Effects of Altitude on the Thermal Efficiency of a Heavy-Duty Diesel Engine, Energy, 59 (2013), Sept., pp. 543-548
- Meng, Z., et al., Investigation of in-Cylinder Combustion Deterioration of Diesel Engines in Plateau Regions, Fuel, 324 (2022), 124824
- Yang, M., et al., Analysis on Altitude Adaptability of Turbocharging Sytems for a Heavy-Duty Diesel Engine, Applied Thermal Engineering, 128 (2018), Jan., pp. 1196-1207
- Liu, J., Dumitrescu, C. E., Analysis of Two-Stage Natural-Gas Lean Combustion Inside a Diesel Geometry, Applied Thermal Engineering, 160 (2019), 114116
- Heywood, J. B., Internal Combustion Engine Fundamentals, McGraw-Hill Education, 2018 New York, USA
- Liu, J., Dumitrescu, C. E., Improved Thermodynamic Model for Lean Natural Gas Spark Ignition in a Diesel Engine Using a Triple Wiebe Function, Journal of Energy Resources Technology, 142 (2020), 6
- ***, GT-SUITE, Gamma Technologies,Westmont, Il., USA, 2014
- Han, K., et al., Research on Composite Adjustable Supercharged Program of Diesel Engine for Power Recovery at Plateau, Acta Armamentarii, 34 (2013), 2, 129
- Liu, Z., Liu, J., Effect of Altitude Conditions on Combustion and Performance of a Turbocharged Direct-Injection Diesel Engine, Proceedings of the Institution of Mechanical Engineers - Part D: Journal of Automobile Engineering, 236 (2022), 4, pp. 582-593
- Yang, M., et al., Influence of Altitude on Two-Stage Turbocharging System in a Heavy-Duty Diesel Engine Based on Analysis of Available Flow Energy, Applied Thermal Engineering, 129 (2018), Jan., pp. 12-21
- Jia, G., et al., Effects of Plateau Environment on Combustion and Emission Characteristics of a Plateau High-Pressure Common-Rail Diesel Engine with Different Blending Ratios of Biodiesel, Energies, 15 (2022), 2, 550
- Yasar, H., et al., Double-Wiebe Function: An Approach for Single-Zone HCCI Engine Modelling, Applied Thermal Engineering, 28 (2008), 11-12, pp.1284-1290
- Serrano, J. R., et al., Methodological Analysis of Variable Geometry Turbine Technology Impact on the Performance of Highly Downsized Spark-Ignition Engines, Energy, 215 (2021), 119122
