Qualitative features of flame development in case of fuel injection into medium with counterpressure up to 10 atm

Introduction. The most promising direction toward increasing the economical efficiency and ecological safety of diesel engines is the improvement of the process of fuel combustion [1]. The character of this process is determined to a large extent by the quality of mixing and pre-burning treatment of the fuel-air mixture. Incomplete combustion manifested in the presence of soot and coke particles, underoxidized hydrocarbons, etc., is caused first of all by the formation of inhomogeneities in the jet [2], which contain different-scale time and space fluctuations of the fuel distribution density, and also by the violation of homogeneity of the mixture [3]. Therefore, many papers are devoted to the study of one of the key processes in the diesel combustor: the development of a high-speed pulse jet of a fuel-air mixture. Nevertheless, although the main results were obtained many years ago [4][5][6], numerical, theoretical, and experimental studies are continuing [3,[7][8][9], since the requirements on economical efficiency and ecological characteristics of existing and newly created engines are becoming more and more stringent, and the solution of these problems is intimately connected with more profound knowledge of the mechanisms of heat and mass transfer in the engine combustor.Based on the results of complex experimental investigations, a new physical model of the development of a high-speed pulse jet of a fuel-air mixture in a gaseous medium is proposed in the paper. The interaction of the head part of this jet with a gas is considered as cumulative [10]. The jet is represented as a comparatively dense high-speed axial flux of the mixture surrounded by the gas-liquid mass with a small content of the fuel component, which hangs in space. The specific feature of the flow in the head part of the jet is its similarity to the flow observed in a vortex ring [11].1. State-of-the-Art of the Problem. A jet formed by high-speed pulse injection of fuel into a gaseous medium is usually characterized by the dependence of the jet length L and root angle ~ on the time t (Fig. la). The third important quantity, the jet diameter D, is referred to much more seldom, since it is believed to be possible to express this parameter in terms of L and ~. But if we assume this parameter to be the jet diameter in the maximum cross section, it turns out that the position of the cross section Im relative to the nozzle has a different dependence on the time and test conditions than the total length of the jet L. Therefore, the shapes of jet structures at different stages of their evolution are not, strictly speaking,

show abstract

Development of a liquid-fuel jet at high-speed pulse injection into a gaseous medium. II. Calculation and experiment

Buzukov¹

1999

J Appl Mech Tech Phys

View full text Add to dashboard Cite

A three-stage calculation scheme developed previously on the basis of a complez ezperimental study is used to calculate the parameters of a #as-liquid jet formed at pulse hieh-speed injection of a liquid fuel into a gaseous medium. The results obtained using this model are in good qualitative and quantitative agreement with ezperimental data, and a physically grounded ezplanation is offered for the discrepancies observed in some ranges of parameters.Formulation of the Problem. An analysis of the results of a complex experimental study of evolution of a pulse high-speed jet of a dispersed liquid fuel in a gaseous medium [1] allowed us to propose a simplified hydrodynamic model of this process. Based on this model, it is possible to calculate the main characteristics of the resultant gas-liquid flow in all stages of its development. In accordance with this model, it is reasonable to consider this process in three stages. First, the parameters (distributions of density and velocity over the jet length) are determined for a comparatively dense axial part of the jet of a gas-liquid mixture, which is formed directly by high-speed injection of a liquid from the nozzle. This high-speed flow is characterized by the fact that it has a low tangential friction drag in the developed cocurrent gas flow. However, because of its intense ejection, the flow gradually loses its velocity. It is shown [1] that the angle/~ of the axial jet varies weakly over the jet length and in time and the flow described can be considered as quasistationary and independent of the phenomena that occur in the head part of the jet. Under the conditions of high-speed injection, the angle /~ is mainly determined by thd physicochemical properties of the liquid and by the intensity of its injection.The second stage of solving the problem is the analysis of the flow in the head part of the jet. The main mechanism of interaction of the jet with the ambient medium is a quasicumulative mechanism. The use of dependences that exactly describe this mechanism allows us to obtain the main characteristic of the jet: the dependence of its length L on the time t. It is important that the formation of such a hydrodynamic structure in the head part of the jet is responsible for the appearance of one more parameter: the "root" angle of the jet ~(t). This parameter is used to describe the conical shape of the outer shell of the gas-liquid jet surrounding the high-speed axial flow. The shell is formed by radial spreading of the mixture in the region of its interaction with the medium (the effect of cumulative penetration through a target) and hanging of the mixture in the space surrounding the jet.In the first two stages of cMculation, .the flow is considered in the one-dimensional approximation, and it is impossible to obtain here any quantitative information about its radial components and, hence, to determine the jet diameter D(t) and the external angle o~(t). However, in the third stage, identifying the complex spatial flow in the head part of the jet with that obser...

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

Qualitative features of flame development in case of fuel injection into medium with counterpressure up to 10 atm

Cited by 5 publications

References 3 publications

Ignition in conditions where a jet of fuel-air mixture interacts with the wall of a diesel combustion chamber

Ignition in conditions where a jet of fuel-air mixture interacts with the wall of a diesel combustion chamber

Development of a liquid-fuel jet at high-speed pulse injection into a gaseous medium. I. Physical model

Development of a liquid-fuel jet at high-speed pulse injection into a gaseous medium. II. Calculation and experiment

Contact Info

Product

Resources

About