Effects of split and single injection strategies on particle number emission and combustion of a GDI engine

Xie, Fei; Zheng, Wentian; Chen, Hong; Liu, Yu; Su, Yan; Wei, Hong

doi:10.1177/0954407018759739

Cited by 7 publications

(2 citation statements)

References 32 publications

(41 reference statements)

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“…Moreover, Zhuang et al 27 found that a significant oil-rich zone would appear in the center of the cylinder at delayed injection timing, which made nitrogen oxides (NO x ) emissions increase. Xie et al 28 found experimentally that the presence of optimal injection timing resulted in the best emissions performance. Further, Firat 29 indicated that compared to single-injection strategy, multistage injection strategies reduce the direct injection spark ignition (DISI) engine emissions such as NO x , carbon monoxide (CO), and unburned hydrocarbon (UHC).…”

Section: Introductionmentioning

confidence: 99%

Numerical investigation of the effect of injection timing on the in-cylinder activity of a gasoline direct injection engine

Zhang

Wang

Yang

et al. 2022

Advances in Mechanical Engineering

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GDI (Gasoline direct injection) technology is used in downsized engines for its economy and low emissions. However, if the injection strategy is not set properly, GDI will produce more emissions than conventional gasoline engines. In this paper, the effect of injection timing on GDI engine emissions under optimal phasing conditions was analyzed by using a three-dimensional (3D) computational fluid dynamics (CFD) GDI engine numerical model. The results showed that at medium engine speed and medium load advancing the injection timing from −300 to −290 CAD ATDC resulted in a more efficient and cleaner combustion process, as evidenced by the higher power output, the increased thermal and combustion efficiencies, and the reduced CO, UHC, soot emissions. The raised NOx emissions at advanced injection timing operation corresponded to the high combustion quality. There was a trade-off relation for advancing injection timing strategy. Specifically, an advanced injection timing operation would increase the amount of liquid film formed on the piston and liner, which is not favorable to clean combustion. However, advancing injection timing also provides more time for fuel-air mixing, which is beneficial for the formation of a more homogeneous mixture. The numerical simulations suggested that the advantages of earlier injection timing outweighed the disadvantages and improved engine efficiency, at least for the conditions and the engine investigated here. Moreover, the comparison indicated that changing injection timing also altered the chemical reaction pathways for pollutant species formation. Overall, all of these findings demonstrated that more fundamental work is still needed to understand the effect of injection timing on engine performance.

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Section: Introductionmentioning

confidence: 99%

Numerical investigation of the effect of injection timing on the in-cylinder activity of a gasoline direct injection engine

Zhang

Wang

Yang

et al. 2022

Advances in Mechanical Engineering

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“…6,7 Particulate emissions are highly sensitive to the start of combustion timing as well as the properties of the engine, its speed, and the spark advance. 8,9 For example, Xie et al 10 showed that delaying the spark advance from 25 CAD to 5 CAD can reduce particulate emissions from GDI engines by 50%. In a typical GDI engine drive cycle, particulate emissions peak during cold starts and transients, when there is an abrupt change in engine load or both load and speed together.…”

Section: Introductionmentioning

confidence: 99%

Visualization of soot formation in load transients during GDI engine warm-up

Etikyala

Koopmans

Dahlander

2022

International Journal of Engine Research

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Reducing the emissions of pollutants, and particularly soot particles, from internal combustion engines is one of the greatest challenges faced by car manufacturers. Although modern gasoline direct injection (GDI) engines produce relatively low particulate emissions during steady state operation under near-stoichiometric conditions, they can produce much higher particulate emissions during transients that cause abrupt changes in load, fuel consumption, and the air-to-fuel ratio. Emissions during transients are particularly high when the engine coolant temperature is low, as occurs during engine start-up. Consequently, there is a need to find ways of reducing particulate emissions during load transients. This paper therefore investigates particulate formation during load transients in a single-cylinder GDI engine equipped with an endoscope in the cylinder head. A transient sequence was designed in which the engine load was increased from 4 bar NMEP to a maximum of 12 bar NMEP in 2 s at an engine speed of 2000 rpm. During the transients, the engine’s particulate emissions were measured in terms of particulate number (PN) and images of the combustion process inside the cylinder were captured via the endoscope using a high-speed camera to identify locations where soot formation occurred. Experiments were conducted at a range of coolant temperatures and using different injection strategies to determine how these parameters affect PN emissions. The coolant temperature was found to be the dominant factor governing PN emissions during transients. Luminescence data obtained by analyzing the flame images agreed well with the measured PN emissions during transients. Under all varied parameters in the transients except delayed injection, soot was mainly formed from wall films. For transients with delayed fuel injection, much of the piston film could be avoided but soot formation instead became mixing-dominated. Variation of the air-fuel ratio had little effect on PN emissions during transients. At all coolant temperatures, PN emissions were lowest when using a split injection strategy but delaying the injection timing increased PN emissions even though the endoscope images suggested a lower frequency of diffusion flame formation. No conditions were found under which the PN emissions during transients with low coolant temperatures could be reduced to levels comparable to those seen with warm coolant.

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Improving the partial-load performance and emission of GDI engine by combining injection strategy and exhaust variable valve timing technology

Wang,

Xie,

Duan

et al. 2023

J Braz. Soc. Mech. Sci. Eng.

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Effects of split and single injection strategies on particle number emission and combustion of a GDI engine

Cited by 7 publications

References 32 publications

Numerical investigation of the effect of injection timing on the in-cylinder activity of a gasoline direct injection engine

Numerical investigation of the effect of injection timing on the in-cylinder activity of a gasoline direct injection engine

Visualization of soot formation in load transients during GDI engine warm-up

Improving the partial-load performance and emission of GDI engine by combining injection strategy and exhaust variable valve timing technology

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