Effect of spark ignition location on the turbulent jet ignition characteristics in a lean burning natural gas engine

Xue, Yiguo; Yong, Cheng; Zhao, Qingwu; Wang, Pengcheng; Chen, Jinbing

doi:10.1177/14680874211064677

Cited by 7 publications

(17 citation statements)

References 47 publications

(77 reference statements)

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“…Figure 9 shows the methane mass fraction, flow velocity, and turbulent kinetic energy (TKE) contours on plane A at spark timing for the cases of ST1 and ST9. It can be seen from Figure 9 that a swirl flow around the horizontal axis is formed in the pre-chamber under the action of the compression flow from the main chamber (as demonstrated in the authors’ previous work 24 ). Due to the inflow of the main chamber lean mixture and the short mixing time, the distribution of the mixture concentration, flow velocity, and TKE in the pre-chamber is not homogeneous.…”

Section: Resultssupporting

confidence: 63%

“…One is composed of low-temperature unburned gas, which is defined as a cold jet, and the other is composed of high-temperature flame and combustion product, which is defined as a hot jet. 24 As shown in Figure 16, the first zero-crossing point of the velocity curve from negative to positive indicates that the gas in the pre-chamber starts to flow into the main chamber, which is the low-temperature cold jet. When the temperature at the outlet of the orifice rises rapidly, the hot jet begins to spray into the main chamber.…”

Section: Resultsmentioning

confidence: 96%

“…Table 2 shows the specifications of the adopted sub-models in the simulation. 24 The Renormalization Group (RNG) k-e turbulence model is selected to calculate in-cylinder turbulent flow in our work considering sufficient computational accuracy and low cost. 32 RNG k-e turbulence model is a Reynolds-Averaged Navier-Stokes turbulence model, which is suitable for simulating flows with high strain rate behavior and a large degree of streamline bending.…”

Section: Simulation Model Setup and Validationmentioning

confidence: 99%

“…Therefore, the above factors should be taken into account in the optimization of the spark location. 24–26…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, the above factors should be taken into account in the optimization of the spark location. [24][25][26] From the above literature review, it can be known that the combustion heat release rate of the prechamber is the most critical factor for turbulent jet characteristics. The mixture concentration, temperature, as well as turbulence quantities in the pre-chamber at spark timing would affect the pre-chamber combustion and later govern the main chamber combustion.…”

Section: Introductionmentioning

confidence: 99%

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Effect of spark timing on the pre-chamber jet ignition in a lean-burn natural gas engine

Xue

Wang

Zhao

et al. 2023

International Journal of Engine Research

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An enhanced combustion concept, pre-chamber jet ignition can provide high ignition energy and a wide dispersion of ignition sources, thus improving combustion performance and realizing stable lean combustion. However, the ignition performance of the pre-chamber jets depends strongly on the pre-chamber combustion process and is sensitive to many factors. Therefore, this paper will explore the impact of spark timing on the pre-chamber combustion, turbulent jet characteristics, and main chamber combustion performance by CFD simulation based on an active pre-chamber natural gas engine. The in-cylinder flow and combustion processes of the engine are calculated with the fuel-air equivalence ratio of the main chamber maintained at 0.5, and the spark timing varied from 684°CA to 708°CA with a step of 3°CA (compression top dead center is 720°CA). The results show that, in the present engine operating point, the pre-chamber combustion heat release rate is improved when the spark timing is retarded from 696°CA to 705°CA, and the injection velocity of the pre-chamber jet accordingly increases. As the spark timing continues to be delayed until 708°CA, the pre-chamber combustion deteriorates, and the injection velocity of the pre-chamber jet decreases. Under the combustion phase CA50 no more than 725°CA and the combustion duration CA5-90 fixed around 30°CA, the IMEP will maintain a relatively stable value when the spark timing is delayed from 693°CA to 705°CA, in the meantime, the NOx emission decreases with the delay of spark timing. Therefore, on the premise of ensuring engine power performance, it is a feasible scheme to delay spark timing to reduce NOx emission for the natural gas engine with an active pre-chamber.

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Section: Resultssupporting

confidence: 63%

Section: Resultsmentioning

confidence: 96%

Section: Simulation Model Setup and Validationmentioning

confidence: 99%

“…Therefore, the above factors should be taken into account in the optimization of the spark location. 24–26…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Effect of spark timing on the pre-chamber jet ignition in a lean-burn natural gas engine

Xue

Wang

Zhao

et al. 2023

International Journal of Engine Research

Self Cite

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Influence of structure parameters of pre-chamber on lean combustion of active pre-chamber jet ignition engine

Yang,

Xie,

Jiang

et al. 2024

Energy

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Numerical Investigation of the Operating Characteristics of the Passive and Active Prechamber Jet Ignition in a Natural Gas Engine

Yang,

Li,

Wang

et al. 2024

ACS Omega

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Prechamber jet ignition is a promising technology that enables stable ignition and fast combustion by combining thermal effects, chemical kinetics, and turbulent disturbance. The development and application of the prechamber ignition require a comprehensive and in-depth understanding of the operating characteristics of the prechamber ignition in the real engine working cycle. Therefore, numerical simulations are conducted to explore the operating performance of the prechamber ignition applied to a large-bore natural gas engine in this study. The differences between the passive prechamber (PPRE) and active prechamber (APRE) near the lean burn limit are compared. The results show that the jet ignition performance of the PPRE is hampered by the high residual gas coefficient and lean mixture in the prechamber under lean burn conditions. The ignition mode of the PPRE is similar to torch ignition, and the combustion process in the main chamber is mainly turbulent flame propagation. The ignition mechanism of the APRE is flame jet ignition. The main chamber combustion process presents a two-stage heat release characteristic, which can be subdivided into three phases: the initial flame development phase, the rapid combustion phase, and the late combustion phase. The heat release rate during the initial flame development phase depends on the physical and chemical properties of the prechamber jet and the mixture conditions in the main chamber. During the rapid combustion phase, the flame propagation along the radial direction of the jet largely depends on the time scale of the chemical reaction. The heat release rate depends on the coverage area of the jet, the jet residual momentum, and the turbulent flame speed. During the late combustion phase, the flame propagation is mainly affected by the turbulent flame speed. These results provide theoretical guidance for the subsequent application of prechamber ignition systems in various powertrains.

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Effect of spark ignition location on the turbulent jet ignition characteristics in a lean burning natural gas engine

Cited by 7 publications

References 47 publications

Effect of spark timing on the pre-chamber jet ignition in a lean-burn natural gas engine

Effect of spark timing on the pre-chamber jet ignition in a lean-burn natural gas engine

Influence of structure parameters of pre-chamber on lean combustion of active pre-chamber jet ignition engine

Numerical Investigation of the Operating Characteristics of the Passive and Active Prechamber Jet Ignition in a Natural Gas Engine

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