Flow effects due to valve and piston motion in an internal combustion engine exhaust port

Semlitsch, Bernhard; Mihăescu, Mihai

doi:10.1016/j.enconman.2015.02.058

Cited by 29 publications

(14 citation statements)

References 20 publications

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“…The instantaneous spray fields at 4 different conditions at 3°a SOI from 3 individual injection cycles are decomposed into four parts and presented in Figs. [6][7][8][9]. Each spray field is reconstructed by using the modes listed in Table 2.…”

Section: 5°asoimentioning

confidence: 99%

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Investigation of the temporal evolution and spatial variation of in-cylinder engine fuel spray characteristics

Qin

Hung

2015

Energy Conversion and Management

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Section: 5°asoimentioning

confidence: 99%

“…In addition, the advanced numerical simulation tools can also help the researchers to understand the in-cylinder phenomena [5][6][7][8][9][10][11]. Extensive research studies have been performed to study in-cylinder turbulent flow field CCV [12][13][14][15][16][17][18][19][20].…”

Section: Introductionmentioning

confidence: 99%

Investigation of the temporal evolution and spatial variation of in-cylinder engine fuel spray characteristics

Qin

Hung

2015

Energy Conversion and Management

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“…The expansion of the air in the cylinder during the exhaustion can, however, be viewed as an isentropic process Semlitsch et al 2015;Povey and Beard 2008). Thus, the temperature is related to the pressure as follows:…”

Section: Time-resolved Mass-flow Measurementsmentioning

confidence: 99%

“…In another study Semlitsch et al (2015) investigated how valve and piston motion affects the exhaust process, again using LES. In this study, they performed simulations on a double exhaust-valve cylinder top.…”

mentioning

confidence: 99%

On discharge from poppet valves: effects of pressure and system dynamics

2018

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Simplified flow models are commonly used to design and optimize internal combustion engine systems. The exhaust valves and ports are modelled as straight pipe flows with a corresponding discharge coefficient. The discharge coefficient is usually determined from steady-flow experiments at low pressure ratios and at fixed valve lifts. The inherent assumptions are that the flow through the valve is insensitive to the pressure ratio and may be considered as quasi-steady. The present study challenges these two assumptions through experiments at varying pressure ratios and by comparing measurements of the discharge coefficient obtained under steady and dynamic conditions. Steady flow experiments were performed in a flow bench, whereas the dynamic measurements were performed on a pressurized, 2 l, fixed volume cylinder with one or two moving valves. In the latter experiments an initial pressure (in the range 300-500 kPa) was established whereafter the valve(s) was opened with a lift profile corresponding to different equivalent engine speeds (in the range 800-1350 rpm). The experiments were only concerned with the blowdown phase, i.e. the initial part of the exhaustion process since no piston was simulated. The results show that the process is neither pressure-ratio independent nor quasi-steady. A measure of the "steadiness" has been defined, relating the relative change in the open flow area of the valve to the relative change of flow conditions in the cylinder, a measure that indicates if the process can be regarded as quasi-steady or not.

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“…The traditional method to obtain the flow coefficient of the valve is experiment blowing through the valve. Nowadays, with the development of CFD and FEA technology, the flow coefficient can be obtained with a numerical method [15].…”

Section: Flow Coefficient βmentioning

confidence: 99%

Investigation of the Thermodynamic Process of the Refrigerator Compressor Based on the m-θ Diagram

Wang

Guo³

et al. 2017

Energies

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Abstract:The variation of refrigerant mass in the cylinder of refrigerator compressor has a great influence on the compressor's thermodynamic process. In this paper, the m-θ diagram, which represents the variation of refrigerant mass in compressor cylinder (m) and the crank angle (θ), is proposed to investigate the thermodynamic process of the refrigerator compressor. Comparing with the traditional pressure-Volume (p-V) indicator diagram, the refrigerant's backflow trigged by the delayed closure of valve can be clearly expressed in the m-θ diagram together with the mass flow rate. A typical m-θ diagram was obtained by experimental and theoretical investigations. To improve the thermodynamic model of the compressor, a 3D fluid-structure interaction (FSI) FEA model has been introduced to find out the effective flow area of the valves. Based on the m-θ diagram, the effect of rotating speed on the backflow through the valve, which depends on the movement of the valve, has been investigated. Specific to the compressor used in this study, the maximum backflow through the suction valve and discharge valve occur at 3500 r·min −1 and 5500 r·min −1 , respectively.

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Flow effects due to valve and piston motion in an internal combustion engine exhaust port

Cited by 29 publications

References 20 publications

Investigation of the temporal evolution and spatial variation of in-cylinder engine fuel spray characteristics

Investigation of the temporal evolution and spatial variation of in-cylinder engine fuel spray characteristics

On discharge from poppet valves: effects of pressure and system dynamics

Investigation of the Thermodynamic Process of the Refrigerator Compressor Based on the m-θ Diagram

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