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Abstract

The effects of turbocharger (T/C) rotational inertia on engine and turbine performance under transient and steady engine conditions were analyzed in a 2.0 L 4-cylinder turbocharged-gasoline direct injection (T-GDI) engine. The test T/Cs consisted of heavy and light compressor wheels (C/W) and turbine wheels (T/W). The study was conducted in two research stages. First, transient engine load tests were conducted to evaluate the effect of T/C rotational inertia on transient response of the T/C, combustion performance, and fuel consumption. Seconds, steady engine load tests were conducted to find out if a light inertia T/C can run at higher efficiency under the same exhaust pulsating flow conditions within one engine cycle. In order to evaluate the engine on-board turbine instantaneous performances in the units of crank angle degree (CAD), T/C rotation speed and pressure data were measured in the experiment. The instantaneous exhaust gas mass flow rate and the temperature of upstream and downstream of the turbine were extracted by 1-D simulation. Turbine efficiency and mass flow rate parameters were calculated by combining these data. In the results, there existed positive effects of light inertia T/C on response and specific fuel consumption under transient conditions. It was also found that the light inertia T/C could show higher T/C speed fluctuation under the same exhaust pulsating flow conditions. Consequently, blade speed ratio (BSR) and turbine efficiency of light inertia T/C were partially higher than that of conventional one. However, it was not led to higher engine efficiency.

Keywords

Light inertia turbocharger transient response transient fuel consumption unsteady turbine efficiency Unsteady turbine mass flow rate parameters

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References

Spicher

. Fuel economy improvement for eco-friendly powertrains – research and development trends. In: 14th Hyundai-Kia international powertrain conference, Gyeonggi-do, Korea, 28 October 2014.

Peter

. European vehicle market statistics. The International Council on Clean Transportation (ICCT). https://theicct.org/publications/european-vehicle-market-statistics-2014 (2014, accessed 01 December 2019)

Takashima

Katayama

Sako

Furutani

Activities for high-efficiency small gas engines. Appl Therm Eng 2017; 114: 1372–1377.

Wirth

Mayerhofer

Piock

Fraidl

GK.

Turbocharging the DI gasoline engine. SAE Trans 2000; 109: 146–155. DOI: 10.4271/2000-01-0251.

Han

Kim

WT.

Development of 2.0 L Turbocharged DISI engine for downsizing application. SAE paper 2007-01-0259, 16 April 2007.

Gheorghiu

. Ultra-downsizing of internal combustion engines. In: Sustainable automotive technologies 2012, 2012, pp.145–155. Berlin, Heidelberg: Springer.

Petitjean

Bernardini

Middlemass

Shahed

SM.

Advanced gasoline engine turbocharging technology for fuel economy improvements. SAE paper 2004-01-0988, 8 March 2004.

Zhao

Wang

Improving the partial-load fuel economy of 4-cylinder SI engines by combining variable valve timing and cylinder-deactivation through double intake manifolds. Appl Therm Eng 2018; 141: 245–256.

Ismail

Costall

Martinez-Botas

Rajoo

Turbocharger matching method for reducing residual concentration in a turbocharged gasoline engine. SAE paper 2015-01-1278, 14 April 2015.

10.

Agarwal

Jung

Byrd

, et al. Blowdown interference on a V8 twin-turbocharged engine. SAE Int J Engines 2011; 4(1): 202–218.

11.

Czapka

Hagelstein

Theobald

Demmelbauer-Ebner

Seume

. Turbocharger compressor map enhancement for highly efficient combustion engines. In: 12th international conference on turbochargers and turbocharging 2016, London, UK, 17–18 May 2016.

12.

Ebisu

Shiraishi

Tomita

Furukawa

. Development of advanced centrifugal compressor for turbocharger, applying control of internal unsteady flow structure. In: 10th international conference on turbochargers and turbocharging, London, May 2012, pp.135–144. Sawston: Woodhead Publishing. DOI: 10.1533/9780857 096135.3a.135.

13.

Chen

Cai

. The transient response of turbocharger turbines. In: 10th international conference on turbochargers and turbocharging, 11 May 2012, pp.295–304. Sawston: Woodhead Publishing. DOI: 10.1533/9780857 096135.5.295.

14.

Zhen

Wang

, et al. The engine knock analysis–An overview. Appl Energy 2012; 92: 628–636.

15.

Zhao

Research and application of over-expansion cycle (Atkinson and Miller) engines–A review. Appl Energy 2017; 185: 300–319.

16.

Korakianitis

Sadoi

Turbocharger-design effects on gasoline-engine performance. J Eng Gas Turbine Power 2005; 127(3): 525–530.

17.

Walkingshaw

Iosifidis

Scheuermann

Filsinger

Ikeya

A comparison of a mono-, twin-, and double-scroll turbine for automotive applications. J Eng Gas Turbine Power 2016; 138(5): 052301.

18.

Ricardo

Apostolos

Yang

Overview of boosting options for future downsized engines. Sci China Technol Sci 2011; 54(2): 318–331.

19.

Turner

Popplewell

Patel

, et al. Ultra boost for economy: extending the limits of extreme engine downsizing. SAE Int J Engines 2014; 7(1): 387–417.

20.

Stoffels

Quiring

Pingen

Analysis of transient operation of turbo charged engines. SAE Int J Engines 2010; 3(2): 438–447.

21.

Park

Matsumoto

Oda

Numerical analysis of turbocharger response delay mechanism. SAE paper 2010-01-1226, 12 April 2010.

22.

Jung

Park

Bae

Effects of high-response TiAl turbine wheel on engine performance under transient conditions. SAE paper 2015-01-1881, 1 September 2015.

23.

Yang

Martinez-Botas

Rajoo

Yokoyama

Ibaraki

An investigation of volute cross-sectional shape on turbocharger turbine under pulsating conditions in internal combustion engine. Energy Convers Manag 2015; 105: 167–177.

24.

Dale

AP.

Radial, vaneless, turbocharger turbine performance. Doctoral Dissertation, Imperial College, London, 1990.

25.

Karamanis

Martinez-Botas

RF.

Mixed-flow turbines for automotive turbochargers: steady and unsteady performance. Int J Engine Res 2002; 3(3): 127–138.

26.

Piscaglia

Onorati

Marelli

Capobianco

A detailed one-dimensional model to predict the unsteady behavior of turbocharger turbines for internal combustion engine applications. Int J Engine Res 2019; 20(3): 327–349.

27.

Serrano

Arnau

García-Cuevas

Soler

Cheung

Experimental validation of a one-dimensional twin-entry radial turbine model under non-linear pulse conditions. Int J Engine Res. Epub ahead of print 20 August 2019. DOI: 10.1177/1468087419869157.

28.

Rehnberg

Ångström

Olofsson

Instantaneous on-engine turbine efficiency for an SI engine in the closed waste gate region for 2 different turbochargers. SAE paper 2006-01-3389, 16 October 2006.

29.

Westin

Ångström

HE.

Calculation accuracy of pulsating flow through the turbine of SI-engine turbochargers-Part 1 measurements, simulation correlations and conclusions. SAE Trans 2005; 114: 1662–1684. DOI: 10.4271/2005-01-3812.

30.

Avola

Copeland

Romagnoli

Burke

Dimitriou

Attempt to correlate simulations and measurements of turbine performance under pulsating flows for automotive turbochargers. Proc IMechE, Part D: J Automobile Engineering 2017; 233(2): 174–187.

31.

Jääskeläinen

Turbocharger durability and materials. https://www.dieselnet.com/tech/air_turbo_durability.php (2019, accessed 22 August 2019).

32.

Hiereth

Prenninger

Charging the internal combustion engine. Vienna, Australia: Springer Science & Business Media, 2007.

33.

Möller

Johansson

Grandin

Lindström

Divided exhaust period - A gas exchange system for turbocharged SI engines. SAE paper 2005-01-1150, 2005.

34.

Baar

Boxberger

Gern

MS.

Boosting technologies and limits for small combustion engines. SAE paper 2016-32-0077, 8 November 2016.

Effects of turbocharger rotational inertia on engine and turbine performance in a turbocharged gasoline direct injection engine under transient and steady conditions

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