The effect of intake port shape on in-cylinder flow field and turbulence distribution in a high-tumble production engine with endoscope accesses

Kim, Dongchan; Rao, Lingzhe; Kook, Sanghoon; Lee, Seung Woo; Baek, Hong-kil

doi:10.1177/14680874231181960

Cited by 3 publications

(1 citation statement)

References 47 publications

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“…In reality, it is known that the heat flux significantly varies depending on the location within the engine. 8,9,27 Nevertheless, insights from previous studies on in-cylinder flows 22,28 indicate that the turbulence intensity does not exhibit strong variation during the early expansion stroke. This likely accounts for the observed constancy in the heat flux ratio.…”

Section: Resultsmentioning

confidence: 92%

Conduction-strain model for heat transfer characterization in internal combustion engines

Dejima,

Nakabeppu

2024

International Journal of Engine Research

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Heat transfer between combustion gases and walls is one of the most important phenomena for internal combustion engines; however, its mechanisms have not yet been elucidated. This study proposed a new model based on one-dimensional heat conduction to characterize and predict engine heat transfer. This model assumes a conduction thickness of a thermal boundary layer determined by heat conduction and strain. Through comparison with numerical simulation, it was found that the heat flux from the conduction-strain model was comparable to that in laminar heat transfer. The heat flux calculated with the conduction-strain model is considered to be the minimum heat flux under each operating condition and engine specification. Therefore, the ratio of the measured heat flux to modeled heat flux indicates the intensity of convection and radiation, particularly turbulent mixing. It was also found that the conduction-strain model reproduced the measured heat flux well with a single coefficient, exhibiting a small error of 10.2%; meanwhile, the errors of Woschni and Annand models were greater than 20%, suggesting that the proposed model has good potential in predicting the instantaneous heat flux more accurately than conventional models.

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Section: Resultsmentioning

confidence: 92%

Conduction-strain model for heat transfer characterization in internal combustion engines

Dejima,

Nakabeppu

2024

International Journal of Engine Research

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Design trends and challenges in hydrogen direct injection (H2DI) internal combustion engines – A review

Goyal,

Jones,

Bajwa

et al. 2024

International Journal of Hydrogen Energy

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Influence of Inlet and Outlet Area Ratio on Intake Port Flow Capacity

Rui,

Li,

Feng

et al. 2024

International Journal of Rotating Machinery

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The flow capacity of the intake port has a great influence on the charging efficiency of the internal combustion engine, affecting the engine’s performance, so it is critical to improve the intake port flow capacity. In this paper, the intake port numerical model was established, and the influence of the inlet and outlet area ratio on intake port flow capacity was studied. The results show that, under the same condition of relative pressure difference, the intake port discharge coefficient increases sharply and then slowly with an increase in area ratio. Under the same condition of area ratio, the discharge coefficient is only determined by relative pressure difference and decreases with an increase of relative pressure difference when the inlet and outlet area ratio>1. The optimal area ratio decreases and then converges with an increase in relative pressure difference. When the intake port is designed, the optimal area ratio under the working condition of a smaller relative pressure difference should be applied in order to ensure the discharge coefficient is optimal under all working conditions.

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The effect of intake port shape on in-cylinder flow field and turbulence distribution in a high-tumble production engine with endoscope accesses

Cited by 3 publications

References 47 publications

Conduction-strain model for heat transfer characterization in internal combustion engines

Conduction-strain model for heat transfer characterization in internal combustion engines

Design trends and challenges in hydrogen direct injection (H2DI) internal combustion engines – A review

Influence of Inlet and Outlet Area Ratio on Intake Port Flow Capacity

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