Analytical Investigation into Effects of Capillary Force on Condensate Film Flowing over Horizontal Semicircular Tube in Porous Medium

Abstract: A theoretical investigation is performed into the problem of laminar filmwise condensation flow over a horizontal semicircular tube embedded in a porous medium and subject to capillary forces. The effects of the capillary force and gravity force on the condensation heat transfer performance are analyzed using an energy balance approach method. For analytical convenience, several dimensionless parameters are introduced, including the Jakob number Ja, Rayleigh number Ra, and capillary force parameter Boc. The re… Show more

“… Investigators Type of study Geometry Fluids Working conditions Activities performed Main results Azzolin et al 64 Experimental and analytical Circular 3.38 mm ID channel R134a Horizontal and vertical downflow T sat = 40 °C Δ T sat-wall = 3.1–17.1 K G = 50–200 kg m −2 s −1 HTC measurements Flow visualizations The HTC in vertical downflow can be as low as half the value in horizontal flow at the same operating conditions. Chang et al 91 Analytical Semi-circular tube with 0.2 m diameter Saturated steam Horizontal Δ T sat-wall = 5–25 K Analytical study on laminar FWC over a horizontal semi-circular tube If the capillary force is greater than the gravity force, the condensate is sucked into the two-phase zone leading to lower liquid film thickness and higher HTC. Da Riva and Del Col 31 Numerical Circular 1 mm ID minichannel R134a Horizontal and vertical downflow T sat = 40 °C T wall = 30 °C G = 100, 800 kg m −2 s −1 x = 0.4–1 Numerical simulations of FWC inside a circular channel by means of VOF method At G = 100 kg m −2 s −1 , HTCs obtained in the horizontal configuration nearly doubles the one in vertical downflow due to stratification effects.…”

Condensation heat transfer in microgravity conditions

“… Investigators Type of study Geometry Fluids Working conditions Activities performed Main results Azzolin et al 64 Experimental and analytical Circular 3.38 mm ID channel R134a Horizontal and vertical downflow T sat = 40 °C Δ T sat-wall = 3.1–17.1 K G = 50–200 kg m −2 s −1 HTC measurements Flow visualizations The HTC in vertical downflow can be as low as half the value in horizontal flow at the same operating conditions. Chang et al 91 Analytical Semi-circular tube with 0.2 m diameter Saturated steam Horizontal Δ T sat-wall = 5–25 K Analytical study on laminar FWC over a horizontal semi-circular tube If the capillary force is greater than the gravity force, the condensate is sucked into the two-phase zone leading to lower liquid film thickness and higher HTC. Da Riva and Del Col 31 Numerical Circular 1 mm ID minichannel R134a Horizontal and vertical downflow T sat = 40 °C T wall = 30 °C G = 100, 800 kg m −2 s −1 x = 0.4–1 Numerical simulations of FWC inside a circular channel by means of VOF method At G = 100 kg m −2 s −1 , HTCs obtained in the horizontal configuration nearly doubles the one in vertical downflow due to stratification effects.…”

Condensation heat transfer in microgravity conditions

Heat Transfer at Condensation of Immobile Vapor on Horizontal Tube Placed in Granular Layer