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Thermodynamic optimisation of diesel engine turbocharging system. Part II

Krzysztof Nakonieczny Tadeusz R. Fodemski
Archive of Mechanical Engineering | 2002 | vol. 49 | No 3 | 201-213
Keywords turbocharging
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Abstract

The authors present the optimisation procedure and results, applied to the system discussed in part I. This procedure utilises a "fixed variables" method from the group of "search methods". The optimisation is related to the specific turbocharged engine STAR T3 70 for which necessary construction data and experimental measurements were available. Calculation results, however, are based mainly on the computer simulation of time dependant flows in the inlet and exhaust systems of this engine. They show that the presented method, after necessary improvements and the use of more advanced optimisation procedures, could represent an additional and attractive tool, which might be used by designers of such systems.
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Authors and Affiliations

Krzysztof Nakonieczny
Tadeusz R. Fodemski

Thermodynamic optimisation of diesel-engine turbocharging system. Part I

Krzysztof Nakonieczny Tadeusz R. Fodemski
Archive of Mechanical Engineering | 2002 | vol. 49 | No 2 | 127-140
Keywords turbocharging minimum entropy generation exergy optimisation
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Abstract

The authors present an optirrusanon method, based on the thermodynamic consideration and applied to the inlet and exhaust systems of turbocharged engine. The goal function in this method is defined as a sum of exergy irreversible losses - occurring in the whole flow path. The decision variables, optimisation parameters and, also, the constraint conditions in the discussed method are defined and determined. The validation results of specially written and unique programmes, used for flow simulations in the analysed systems, are also presented. The optimisation results, based on the discussed method and related to a specific turbocharged engine are discussed in part II.
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Authors and Affiliations

Krzysztof Nakonieczny
Tadeusz R. Fodemski

The Use of Plastic Working Alloys Feal to Perform Controls Elements of Turbocharger in Diesel Engine

J. Cebulski D. Pasek
Archives of Metallurgy and Materials | 2018 | vol. 63 | No 3 | 1423-1427 | DOI: 10.24425/123821
Keywords FeAl turbocharger intermetallic alloys heat resistance material structure
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Abstract

Operating conditions turbocharger (high temperature and corrosive environment) mean that the device is classified into one of the most elements of the emergency drive unit of the car. The failure rate can be reduced through the use of modern heat-resistant materials, which include based alloys FeAl intermetallic phase. Intermetallic alloys belong to the group of materials known as prospective due to their advantageous properties, in particular their high specific strength, high melting point and good resistance to corrosion and oxidation at high temperatures. In the article presented results of the research axis roll control system variable geometry blades made of intermetallic alloy Fe40Al5Cr0,2TiB as a substitute so far made of austenitic steel. A verification service conditions, comparing the degradation of the material previously used by manufacturers of turbochargers for elements of the control system degradation axes made of intermetallic alloy Fe40Al5Cr0,2TiB. The study consisted of determining microstructure and corrosion products after use. Observations of the structure and the surface of the corrosion tests were performed using light microscopy, scanning electron microscopy and X-ray microanalysis EDS chemical composition.

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Authors and Affiliations

J. Cebulski
D. Pasek

Effect of heat transfer correlation on wet cylinder liner temperature distribution when converting an old engine into a turbocharged engine

Kien Nguyen Trung
Archives of Thermodynamics | 2021 | vol. 42 | No 3 | 159-172 | DOI: 10.24425/ather.2021.138114
Keywords Heat transfer correlation Turbocharged engine Cylinder liner distribution Supercharging
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Abstract

For conventional diesel engines, two of the most widely used global correlations are due to Woschni and Hohenberg. Besides, the modern diesel engines used a new heat transfer coefficient correlation was proposed by Finol and Robinson. In Vietnam, improving engine power density is a trend of improving non-turbocharged base engines by using a supercharging system with exhaust gas energy recovery. Increasing engine power by the turbocharger is limited for two reasons: mechanical stress and thermal stress of the components surrounding the combustion chamber. In general, the heat transfer coefficient has a major effect on heat transfer rate, especially during the combustion process. So, the purpose of this study is to compare the cylinder distribution results from the simulation using the equations of Woschni and Hohenberg and compare to the experiment results when converting an old heavy-duty engine into a turbocharged engine. Results show that the cylinder distribution using Hohenberg’s correlation has a good agreement with the experiment results, especially in the case of a turbocharged engine.
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Bibliography

[1] Caton J.A.: An Introduction to Thermodynamic Cycle Simulations for Internal Combustion Engines. Wiley, 2016.
[2] Kurowski M.: Heat transfer coefficient measurements on curved surfaces. Arch. Thermodyn. 42(2021), 2, 155–170.
[3] Nusselt W.: Der Warmeubergang in der Verbrennungskrafmaschine. V.D.I. Forschungsheft 264(1923).
[4] Annand W.J.D.: Heat transfer in the cylinders of reciprocating internal combustion engines. P.I. Mech. Eng. 177(1963), 36, 973–996.
[5] Eichelberg G.: Some new investigations on old combustion engine problems. Engineering 148(1939), 463–466, 547–550.
[6] Woschni G.: A universally applicable equation for the instantaneous heat transfer coefficient in the internal combustion engine. SAE Transactions 76(1967), 670931, 3065–3083.
[7] Hohenberg G.F.: Advanced approaches for heat transfer calculations. SAE Tech. Pap. 790825(1979).
[8] Finol C.A., Robinson K.: Thermal modelling of modern engines: A review of empirical correlations to estimate the in-cylinder heat transfer coefficient. P.I. Mech. Eng. D-J. Aut. 220(2006), 12, 1765–1781.
[9] Finol C.A., Robinson K.: Thermal modelling of modern diesel engines: proposal of a new heat transfer coefficient correlation. P.I. Mech. Eng. D-J. Aut. 225(2011), 11, 1544–1560.
[10] Parra C.A.F.: Heat transfer investigations in a modern diesel engine. PhD thesis, Univ. Bath, Bath 2008.
[11] Hiereth H., Prenninger P.: Charging the Internal Combustion Engine. Springer, Wien New York 2007.
[12] Pan M., Qian W., Wei H., Feng D., Pan J.: Effects on performance and emissions of gasoline compression ignition engine over a wide range of internal exhaust gas recirculation rates under lean conditions. Fuel 265(2020), 116881.
[13] Trung K.N.: A Study for determination of the pressure ratio of the V12 diesel engine based on the heat flow density to cooling water. In: Advances in Engineering Research and Application. (K.U. Sattler., D.C. Nguyen, N.P. Vu, B.T. Long., H. Puta, Eds.), Proc. ICERA 2020, Lecture Notes in Networks and Systems, Vol. 178, Springer, 2021, 64–74.
[14] Thompson M.K., Thompson J.M.: ANSYS Mechanical APDL for Finite Element Analysis. Butterworth-Heinemann, 2017.
[15] Trung K.N.: The temperature distribution of the wet cylinder liner of V-12 engine according to calculation and experiment. J. Therm. Eng. 7(2021), 2 (Spec. iss.),
[16] Heywood J.B.: Internal Combustion Engine Fundamentals (2nd Edn.). McGraw- Hill Education, 2018.
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Authors and Affiliations

Kien Nguyen Trung
1 2
  1. Phenikaa University, Faculty of Vehicle and Energy Engineering, Yen Nghia Ward, Ha-Dong District, Hanoi 12116, Vietnam
  2. Phenikaa Research and Technology Institute, A&A Green Phoenix Group JSC, 167 Hoang Ngan, Trung Hoa, Cau Giay, Hanoi 11313, Vietnam

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