Helical Double-tube HX P M V Subbarao Professor Mechanical Engineering Department I I T Delhi Ideas for Creation of Compact HX!!!

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Helical Double-tube HX P M V Subbarao Professor Mechanical Engineering Department I I T Delhi Ideas for Creation of Compact HX!!!

Helical Double-tube HX

Secondary Flow in Helical Coils The form of the secondary flow would depend on the ratio of the tube diameters and other factors. A representative secondary flow pattern is shown below: Thirdly, this configuration should lead to a more standard approach for characterizing the heat transfer in the exchanger. The ratio of the two tube diameters may be one of the ways to characterize the heat transfer.

Heat Transfer in Helical Tubes Acharya et al. (1992, 2001) developed the following two correlations of the Nusselt number, for Prandtl numbers less than and greater than one, respectively.

Heat Transfer in Helical Annulus  Nusselt numbers for the annulus have been calculated and correlated to a modified Dean number.  The modified dean number for the annulus is calculated as it would be for a normal Dean number, except that the curvature ratio used is based on the ratio of the radius of the outer tube to the radius of curvature of the outer tube, and the Reynolds number based on the hydraulic radius of the annulus.  Thus the modified Dean number is:

Helical Coils: Laminar flow De is Dean Number. De=Re (a/R) 1/2. Srinivasan et al. (7 < R/a < 104): Manlapaz and Churchill: Correction for vp:

Helical coils: turbulent flow

Annular flow in series & Tubular Flow in Parallel

Two level Annular flow in series & Tubular Flow in Parallel