Experimental Assessment of Instantaneous Heat Transfer in the Combustion Chamber and Exhaust Manifold Walls of Air-Cooled Direct Injection Diesel Engine

Mavropoulos, G. C.; Rakopoulos, C.D.; Hountalas, D. T.

doi:10.4271/2008-01-1326

Cited by 9 publications

(14 citation statements)

References 47 publications

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“…For the CDC mode, the location of the flame front determines the local heat transfer loss. 41 As can be seen in Figure 6(a), the heat flux is relatively small prior to the arrival of the flame, and the wall heat flux sharply increases when the diesel flame front impinges on the wall with the maximum in-cylinder temperature exceeding 2200 K. The heat flux distribution in CDC combustion is highly non-uniform. Since the combustion mostly takes place within the piston bowl with higher gas temperature and turbulence kinetic energy (see Figures 4(a) and 5(a)), the heat flux within the piston bowl is much higher than at other locations.…”

Section: Comparison Of Heat Transfer Losses For the Three Combustion mentioning

confidence: 96%

Effect of combustion regime on in-cylinder heat transfer in internal combustion engines

Jia

Gingrich

Wang

et al. 2015

International Journal of Engine Research

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A multi-dimensional model was applied to investigate the influence of combustion regimes on heat transfer losses in internal combustion engines. By utilizing improved turbulence and heat transfer sub-models, the combustion and heat transfer characteristics of the engine were satisfactorily reproduced for operation under conventional diesel combustion, homogeneous charge compression ignition, and reactivity controlled compression ignition regimes. The results indicated that the total heat transfer losses of conventional diesel combustion are the largest among the three combustion regimes due to the direct interaction of the high-temperature flame with the piston wall, while the heat transfer losses of reactivity controlled compression ignition are the lowest and nearly are independent of combustion phasing because of the avoidance of high-temperature regions adjacent to the cylinder walls. Compared to conventional diesel combustion, homogeneous charge compression ignition shows more potential for the reduction of exhaust energy and improvement of fuel efficiency. In reactivity controlled compression ignition combustion, the reduction of heat transfer and exhaust losses outweigh its increase in combustion losses and offer the opportunity for further improvement of fuel efficiency. Furthermore, by evaluating the widely used Woschni and Chang et al.'s empirical heat transfer correlations, it was found that both correlations considerably overestimate the heat transfer rate for the reactivity controlled compression ignition regime. It is necessary to improve empirical heat transfer models to take account of the flow and combustion characteristics under various combustion modes.

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Section: Comparison Of Heat Transfer Losses For the Three Combustion mentioning

confidence: 96%

Effect of combustion regime on in-cylinder heat transfer in internal combustion engines

Jia

Gingrich

Wang

et al. 2015

International Journal of Engine Research

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show abstract

“…The reasons for this failure are described in detail in reference [49]. Therefore, in this work the results for the cylinder head will be presented only from sensor HT#1 together with results for the exhaust manifold from sensor HT#4.…”

Section: Results and Discussion On The Effects Of Thermal Shockmentioning

confidence: 99%

Analysis and evaluation of the thermal shock phenomena in the in-cylinder surfaces of a DI diesel engine during its transient operation

Mavropoulos

Rakopoulos

Hountalas

2011

Proceedings of the Institution of Mechanical Engineers, Part D:

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This paper presents the results from the analysis of an experimental investigation with the aim of providing an insight into the cyclic thermal shock phenomena occurring in the internal cylinder wall surfaces of a direct injection (DI), air-cooled diesel engine during the initial stage of a transient operation. The mechanism of cyclic heat transfer is investigated during engine transient events, viz. after a sudden change in engine speed and/or load. The experimental installation allowed both long-and short-term signal types to be recorded on a common time reference base during the transient event. Processing of experimental data was accomplished using a modified version of one-dimensional heat conduction theory with Fourier analysis, capable of catering for the special characteristics of transient engine operation. Based on this model, the evolution of local surface heat flux during a transient event was calculated. Two engine transient events are examined, which present a key difference in the way the load and speed changes are imposed on each one. During the analysis of experimental results the most important parameters characterizing thermal shock, such as the heat wave velocity and length of penetration, are quantified for each event, providing a comprehensive insight into the causes and consequences of this dangerous phenomenon. The results, in addition, confirm the theoretical predictions for the development of the thermal field during an engine transient event, as presented by the authors in previous work. Each thermal transient event is characterized by two distinct phases, that is the 'thermodynamic' and the 'structural' one, which are appropriately configured and analysed. From the results it is revealed that in the case of a severe variation, in the first 20 cycles after the beginning of the transient event, the wall surface temperature and heat flux amplitude on the cylinder head was almost three times higher than that observed in the 'normal' temperature oscillations occurring during steady-state operation.

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“…The model for the processing and analysis of experimental data has been developed by the authors. It is an adaptation for the case of transient engine operation of a similar model presented already in previous publications [32,46,49,50]. The procedure consists of the following submodels:…”

Section: The Simulation Modelmentioning

confidence: 99%

“…The last of the above submodels concerning the estimation of heat transfer coefficient will not be used in the present paper due to space limitations: it will be the subject of a future communication. Details on this submodel concerning analysis and calculation of heat transfer coefficient (HTC) variation both for the combustion chamber and exhaust manifold surfaces during steady state can be found in reference [50].…”

Section: The Simulation Modelmentioning

confidence: 99%

“…Within this framework, they have already reported detailed structural and thermodynamic analysis models [31,45,46], which are also capable of taking into account the heat transfer behaviour of the insulated engine [47]. They also reported in detail the short-term variations of instantaneous diesel engine heat flux and temperature during an engine cycle [32,[48][49][50]. Recently, they have also published the first results of their research work [51] aiming to explore the changes occurring in the mechanism of instantaneous cyclic heat transfer during transient engine operation.…”

Section: Introductionmentioning

confidence: 99%

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Effects of transient diesel engine operation on its cyclic heat transfer: an experimental assessment

Rakopoulos

Mavropoulos

2009

Proceedings of the Institution of Mechanical Engineers, Part D:

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This paper presents results from the analysis of experimental data with the aim of investigating the cyclic, instantaneous heat transfer phenomena occurring in both the cylinder head and exhaust manifold wall surfaces of a direct injection, air-cooled diesel engine, operating under transient events (long-term), viz. during a sudden change in engine speed and/or load, rather than the usual steady state. The experimental installation allowed both for long- and short-term signal types to be recorded on a common time reference base during the transient event. Processing of experimental data was accomplished using a modified version of one-dimensional heat conduction theory with Fourier analysis, capable of catering for the special characteristics of transient engine operation. Based on this model, the evolution of local surface heat flux during a transient event was calculated. Two engine transient events are examined, which present a key difference in the way the load and speed changes are imposed on each one of them. It is revealed that in the case of a ‘ramp’ transient the amplitude of wall surface temperature and heat flux variation in the combustion chamber during the first 20 engine cycles was increased by almost three times more than the corresponding ones during steady state operation. At the same time, temporal gradients of cylinder pressure and wall surface temperature are also sharply increased in the combustion chamber and exhaust manifold surfaces. The variation of cylinder pressure, surface temperature, and heat flux is altered significantly during the transient event, with their peak values either advanced or retarded compared with those for the corresponding steady state operation. The previous observations are moderated or even vanished in the case of a ‘slow pace’ transient variation, revealing the significant influence of engine speed and load triggered by the external command, on the response of heat transfer variables. During a ramp transient, the amplitude of wall temperature swing is increased significantly even at a depth of a few millimetres below the surface of the combustion chamber, thereby influencing the dissipation of heat towards its external layers. Under these circumstances, the depth of penetration for temperature oscillations inside the metal volume is also significantly increased.

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Experimental Assessment of Instantaneous Heat Transfer in the Combustion Chamber and Exhaust Manifold Walls of Air-Cooled Direct Injection Diesel Engine

Cited by 9 publications

References 47 publications

Effect of combustion regime on in-cylinder heat transfer in internal combustion engines

Effect of combustion regime on in-cylinder heat transfer in internal combustion engines

Analysis and evaluation of the thermal shock phenomena in the in-cylinder surfaces of a DI diesel engine during its transient operation

Effects of transient diesel engine operation on its cyclic heat transfer: an experimental assessment

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