Sage Journals: Discover world-class research

Abstract

A semi-analytical model for the interaction of twin circular jets is developed, requiring the solution of a second-order differential equation for the momentum balance. This model (‘Bending Model’) can predict the trajectory and the attachment of two jets. Using Reichardt’s hypothesis, the three-dimensional velocity field of dual-hole circular jets can be predicted. The model is used to predict the interaction of converging, diverging, parallel and non-equal jets. The results show encouraging agreement with k–ε numerical simulations and experimental results from the literature. The position of the maximum velocity is predicted to within 5%, and the model can predict the velocity field as well as the k–ε model. The current model can be useful in phenomenological engine simulation of multi-hole injectors.

Keywords

Turbulent circular jet dual-hole nozzle interaction Bending Model phenomenological modeling

Get full access to this article

View all access options for this article.

References

Boushaki

Sautet

J-C.

Characteristics of flow from an oxy-fuel burner with separated jets: influence of jet injection angle. Exp Fluids 2010; 48: 1095–1108.

Nishida

Tian

Sumoto

. An experimental and numerical study on sprays injected from two-hole nozzles for DISI engines. Fuel 2009; 88: 1634–1642.

Park

Reitz

RD.

Optimization of fuel/air mixture formation for stoichiometric diesel combustion using a 2-spray-angle group-hole nozzle. Fuel 2009; 88: 843–852.

Grandmaison

Yimer

Becker

. The strong-jet/weak-jet problem and aerodynamic modeling of the CGRI burner. Combust Flame 1998; 114: 381–396.

Miller

Comings

EW.

Force-momentum fields in a dual-jet flow. J Fluid Mech 1960; 7: 237–256.

Okamoto

Yagita

Watanabe

. Interaction of twin turbulent circular jet. Bull JSME 1985; 28: 617–622.

Harima

Fujita

Osaka

Turbulent properties of twin circular free jets with various nozzle spacing. Eng Turb Modelling Exp 2005; 6: 501–510.

Moustafa

GH.

Experimental investigation of high-speed twin jets. AIAAJ 1994; 32(11): 2320–2322.

Elangovan

Solaiappan

Rathakrishnan

Studies on twin non-parallel unventilated high-speed jets. Proc IMechE, Part G: J Aerospace Engineering 1997; 211: 337–353.

10.

Rajaratnam

Khan

AA.

Intersecting circular turbulent jets. J Hydraulic Res 1992; 30(3): 373–387.

11.

Yimer

Becker

Grandmaison

EW.

The strong-jet/weak-jet problem: new experiments and CFD. Combust Flame 2001; 124: 481–502.

12.

Schlichting

Boundary layer theory. 6th ed. New York: McGraw-Hill, 1968.

13.

Rajaratnam

Turbulent jets. New York: Elsevier Co, 1976.

14.

Reichardt

On a new theory of free turbulence. J R Aeronaut Soc 1943; 47: 167–176.

15.

Pani

Dash

. Application of Reichardt’s inductive theory to three-dimensional jets. Report No. HYD 2/80, Department of Civil Engineering, Indian Institute of Technology, Bombay, India, 1980.

16.

Pani

Dash

RN.

Three-dimensional single and multiple free jets. J Hydraulic Eng 1983; 109(2): 254–269.

17.

Rajaratnam

Intersecting circular jets of unequal momentum flux. J Hydraulic Res 1992; 30(6): 755–768.

18.

Ricou

Spalding

DB.

Measurements of entrainment by axisymmetrical turbulent jets. J Fluid Mech 1961; 11: 21–32.

19.

Maxwell

WHC

Snorrason

. Measurements in merging flow. UILU-WRC-81-0155, The University of Illinois at Urbana-Champaign, USA, 1981.

20.

Anderson

Spall

RE.

Experimental and numerical investigation of two-dimensional parallel jets. J Fluids Eng 2001; 123: 401–406.

A phenomenological model of two circular turbulent jets

Abstract

Keywords

Get full access to this article

References