Description AC3-10: Difference between revisions
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=='''Flow Physics and Fluid Dynamics Data'''== | =='''Flow Physics and Fluid Dynamics Data'''== | ||
The flow is turbulent, weakly compressible, and isothermal. The Reynolds number in the major pipe branch ranges from < | The flow is turbulent, weakly compressible, and isothermal. The Reynolds number in the major pipe branch ranges from 5x10<sup>5</sup> to 1.2x10<sup>6</sup>. | ||
The fluid dynamics data (except boundary conditions) which are necessary in order to set up a CFD simulation are specified below: | |||
The water density is calculated from the equation: | |||
<math>\rho_{w} = 1.0012 | <center><math> | ||
\rho_{w} = 1.0012 \times {(1000.25 - 0.008{t} - 0.004{t}^{2} + 0.46\times 10^{-6}P)} | |||
\quad(1) | |||
</math></center> | |||
The water viscosity is calculated from the equation: | The water viscosity is calculated from the equation: | ||
<math> | |||
<center><math> | |||
\ln \mu_{w} = {(484.1 / {(120.57 + t)})} - 10.35\qquad\qquad\qquad\qquad\qquad\quad(2) | |||
</math></center> | |||
Reynolds numbers are based on the diameter of branch 1 (with the combined flow rates) and are defined as: | Reynolds numbers are based on the diameter of branch 1 (with the combined flow rates) and are defined as: | ||
<math>Re_{D} = \rho_{w} v_{1} D_{1} / \mu_{w}</math> | |||
<center><math> | |||
Re_{D} = \rho_{w} v_{1} D_{1} / \mu_{w} | |||
\qquad\qquad\qquad\qquad\qquad\qquad\qquad\qquad\qquad\quad(3) | |||
</math></center> | |||
Latest revision as of 16:11, 11 February 2017
Combining/dividing flow in Y junction
Application Challenge 3-10 © copyright ERCOFTAC 2004
Introduction
This application challenge focuses on the prediction of pressure losses and head loss coefficients for water flowing in a ‘Y’ junction. A series of tests has been carried out under both convergent and divergent flow conditions, and at various splits of flow in the two minor branches. The flow rates used in the major branch covered an approximate Reynolds number range of to .
The ‘Y’ junction has an included angle of 50 degrees between the two minor branches, and the internal geometry has been optimised.
Relevance to Industrial Sector
Flow behaviour in pipe junctions is relevant to many industrial applications. At certain flow rate ratios the pressures in the ‘Y’ junction give rise to ‘negative’ differential pressures. CFD can provide an insight into the reasons behind this.
Design or Assessment Parameters
In this application challenge the design or assessment parameters DOAPs, are the differential pressures between the legs of the ‘Y’ junction.
Flow Domain Geometry
The flow geometry is shown in Figures 1 to 5.
Flow Physics and Fluid Dynamics Data
The flow is turbulent, weakly compressible, and isothermal. The Reynolds number in the major pipe branch ranges from 5x105 to 1.2x106. The fluid dynamics data (except boundary conditions) which are necessary in order to set up a CFD simulation are specified below:
The water density is calculated from the equation:
The water viscosity is calculated from the equation:
Reynolds numbers are based on the diameter of branch 1 (with the combined flow rates) and are defined as:
© copyright ERCOFTAC 2004
Contributors: Alan Stevens - Rolls-Royce Marine Power, Engineering & Technology Division
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