Sage Journals: Discover world-class research

Abstract

Understanding heat delivery in a multifaceted and vital engine component, such as the turbocharger, is important for improving engine performance and efficiency, but it is challenging to determine. In this paper, the temperature distribution in a turbocharger body was measured experimentally using a thermal camera, and a one-dimensional simulation of a turbocharger was developed for the temperature distribution. As part of the work, an innovative method is used to determine the thermal radiation constant of the turbocharger housing. In this method, the complete turbocharger system was first installed in a laboratory furnace and, at each stage, the temperature of the furnace was carefully adjusted. After temperature stabilization, a thermal image was taken with a thermal camera, and the radiation coefficient was obtained. Finally, a measurement of the temperature distribution was performed on the engine's test cell for the turbochargers of two three-cylinder gasoline engines (i.e. engines 1200 cc and 999 cc). The experiments include steady-state and transient tests. The transient tests include hot and cold tests at various operating conditions. The results showed that the maximum temperature of the turbine housing varies linearly with inlet gas temperature. Also, the axial distribution of the temperature in the compressor volute shows that temperature increases from the inlet side to the bearing housing side. Based on the numerical results, the maximum turbine housing temperature for engine 1200 cc is 679 °C and for engine 999 cc is 523 °C.

Keywords

Temperature distribution turbocharger thermal camera numerical simulation emissivity

Get full access to this article

View all access options for this article.

References

Hung

T-C

Shai

Wang

. A review of organic Rankine cycles (ORCs) for the recovery of low-grade waste heat. Energy. 1997; 22: 661–667.

Wang

Bao

Kunc

, et al. Coal power plant flue gas waste heat and water recovery. Appl Energy. 2012; 91: 341–348.

Liu

Shi

Fang

. A new operation strategy for CCHP systems with hybrid chillers. Appl Energy. 2012; 95: 164–173.

Jang

Choi

. Comparison of fuel consumption and emission characteristics of various marine heavy fuel additives. Appl Energy. 2016; 179: 36–44.

Morganti

Al-Abdullah

Alzubail

, et al. Synergistic engine-fuel technologies for light-duty vehicles: fuel economy and greenhouse gas emissions. Appl Energy. 2017; 208: 1538–1561.

Pesiridis

Martinez-Botas

. Experimental testing of an active control turbocharger turbine inlet equipped with a sliding sleeve nozzle. Proc Inst Mech Eng, Part D: J Automob Eng, 227, 800–811, 2013.

Rajoo

Pesiridis

Martinez-Botas

. Novel method to improve engine exhaust energy extraction with active control turbocharger. Int J Engine Res, 15: 236–249, 2014.

Baines

. Fundamentals of turbocharging. White River Junction, Vermont: Concepts NREC, London; 2005. I. ISBN 0-933283-14-8.

Nasiri

Jamalabadi

MYA

Sadeghi

, et al. A smoothed particle hydrodynamics approach for numerical simulation of nano-fluid flows. J Therm Anal Calorim. 2019; 135: 1733–1741.

10.

Jiaqiang

Zhao

Qiu

, et al. Experimental investigation on performance and economy characteristics of a diesel engine with variable nozzle turbocharger and its application in urban bus. Energy Convers Manage. 2019; 193: 149–161.

11.

Lin

Akasyah

, et al. Comparison of sintering condition and radio frequency plasma discharge on the conversion of coal/biomass fly ash into high-temperature thermal energy storage material. Energy Convers Manage. 2019; 192: 180–187.

12.

Pishgooie

. A study on the effect of radiation heat transfer on the performance of an internal combustion Engines, Doctoral Thesis, Shahidbahonar University, Kerman, Iran; 2017.

13.

Nunak

Rakrueangdet

Nunak

, et al. Thermal image resolution on angular emissivity measurements using infrared thermography. Proceedings of the International MultiConference of Engineers and Computer Scientists 2015 Vol I, IMECS 2015, March 18–20, 2015, Hong Kong, 2015. pp. 18–20.

14.

Saha

Ranjan

Emani

, et al. Heat Transfer Fundamentals for Design of Heat Transfer Enhancement Devices. In Introduction to Enhanced Heat Transfer. Springer, Cham; 2020. https://www.springer.com/series/8884.

15.

Tadesse

Rakut

Diefenthal

, et al. Experimental investigation of steady state and transient heat transfer in a radial turbine wheel of a turbocharger. ASME Turbo Expo 2015: Turbine Technical Conference and Exposition: American Society of Mechanical Engineers; 2015. pp. V008T23A15–VT23A15.

16.

Romagnoli

Martinez-Botas

. Heat transfer on a turbocharger under constant load points. ASME Turbo Expo 2009: Power for Land, Sea, and Air: American Society of Mechanical Engineers; 2009. pp. 163–74.

17.

Romagnoli

Martinez-Botas

. Heat transfer analysis in a turbocharger turbine: an experimental and computational evaluation. Appl Therm Eng. 2012; 38: 58–77.

18.

Westin

Rosenqvist

Ångström

H-E

. Heat losses from the turbine of a turbocharged SI-engine-measurements and simulation. SAE Word Congress Detroit, Michigan, March 8–11; No. 2004-01-0996.

19.

Lam

Roberts

McDonnell

. Flow modelling of a turbocharger turbine under pulsating flow. IMechE Conference Transactions from 7th International Conference on Turbochargers and Turbocharging, 2002. p. 14–5.

20.

Hellström

Fuchs

. Numerical computations of the pulsatile flow in a turbocharger with realistic inflow conditions from an exhaust manifold. ASME Turbo Expo 2009, Power for Land, Sea and Air, 2009.

21.

Aghaali

Ångström

Serrano

. Evaluation of different heat transfer conditions on an automotive turbocharger. Int J Engine Res 2015; 16: 137–151.

22.

Aghaali

Ångström

H-E

. Turbocharged SI-engine simulation with cold and hot-measured turbocharger performance maps. ASME Turbo Expo 2012: Turbine Technical Conference and Exposition: American Society of Mechanical Engineers; 2012. p. 671–9.

23.

Burke

. Analysis and modeling of the transient thermal behavior of automotive turbochargers. J Eng Gas Turbines Power. 2014; 136: 101511.

24.

Jiaqiang

Zhang

, et al. Effect analysis on flow and boiling heat transfer performance of cooling water-jacket of bearing in the gasoline engine turbocharger. Appl Therm Eng. 2018; 130: 754–766.

25.

Zhao

Zhuge

, et al. Numerical study on steam injection in a turbo compound diesel engine for waste heat recovery. Appl Energy. 2017; 185: 506–518.

26.

Guo

Ahdad

Guo

, et al. Heat Transfer Investigation on Center Housing Using Genetic Algorithms and Finite Element Method. ASME Turbo Expo 2017: Turbomachinery Technical Conference and Exposition: American Society of Mechanical Engineers; 2017. pp. V05AT20A001–V05AT20A.

27.

Serrano

Olmeda

Paez

, et al. An experimental procedure to determine heat transfer properties of turbochargers. Meas Sci Technol. 2010; 21: 035109.

28.

Olmeda

Dolz

Arnau

, et al. Determination of heat flows inside turbochargers by means of a one-dimensional lumped model. Math Comput Model. 2013; 57: 1847–1852.

29.

Jianqin

Liu

Wang

, et al. A comparative study on various turbocharging approaches based on IC engine exhaust gas energy recovery. Appl Energy. 2014; 113: 248–257.

30.

Romagnoli

Manivannan

Rajoo

, et al. A review of heat transfer in turbochargers. Renew Sustain Energy Rev. 2017; 79: 1442–1460.

31.

Gamma Technologies

. GT-Power User's manual and Tutorial, GT-SUITE Version 7.4, Gamma Technologies Inc., USA, 2013.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

5.09 MB

Comparison of simulation and experimental test results of the turbocharger temperature for two gasoline direct injection engines

Abstract

Keywords

Get full access to this article

References

Supplementary Material