Presentation is loading. Please wait.

Presentation is loading. Please wait.

Pressure drop prediction models

Published byAudrey Hodges Modified over 6 years ago

Similar presentations

Presentation on theme: "Pressure drop prediction models"— Presentation transcript:

1 Pressure drop prediction models
Wilson et al. (2003) Considered parameters Single-phase pressure gradients (liquid-only) Martinelli parameter Horizontal condensing in flattened round smooth, axial, and helical microfin tubes. Heat and Mass Transfer Laboratory

2 Pressure drop prediction models
Wilson et al. (2003) Model uses liquid-only two-phase multiplier of Jung and Radermacher (1989): Xtt is the Martinelli dimensionless parameter for turbulent flow in the gas and liquid phases. The liquid only formulation treats all refrigerant mass flow as if it is in the liquid phase. Heat and Mass Transfer Laboratory

3 Pressure drop prediction models
Wilson et al. (2003) Knowing the single-phase pressure gradient, the two-phase pressure grandient is: with Single-phase friction factors are calculated using the Churchill correlation (1977): Heat and Mass Transfer Laboratory 3

4 Pressure drop prediction models
Wilson et al. (2003) Sensitivity of the parameters: Heat and Mass Transfer Laboratory 4

5 Heat transfer prediction models
Shah (1979) Considered parameters Vapor Velocity Liquid-only Reynolds number Liquid Prandtl number Reduced pressure Fluid and geometric properties Heat and Mass Transfer Laboratory

6 Heat transfer prediction models
Shah (1979) Applicability range: If range is respected, compute liquid-only transfer coefficient: Heat and Mass Transfer Laboratory 6

7 Heat transfer prediction models
Shah (1979) For heat transfer coefficient, apply multiplier: Widely used for design. Improvement needed for results near critical pressure and vapor quality from 0.85 to 1. Heat and Mass Transfer Laboratory 7

8 Heat transfer prediction models
Dobson and Chato (1998) Considered parameters Liquid, vapor-only Reynolds number Martinelli parameter Zivi’s (1964) void fraction Galileo number Modified Soliman Froude number Liquid Prandtl number Heat and Mass Transfer Laboratory 8

9 Heat transfer prediction models
Dobson and Chato (1998) Calculate the modified Soliman Froude number: Heat and Mass Transfer Laboratory 9

10 Heat transfer prediction models
Dobson and Chato (1998) With: Heat and Mass Transfer Laboratory 10

11 Heat transfer prediction models
Dobson and Chato (1998) For Frso > 20, the annular flow correlation proposed is And the resulting heat transfer coefficient is: Heat and Mass Transfer Laboratory 11

Download ppt "Pressure drop prediction models"

Similar presentations

Chapter 10 Sections 10.6 through 10.11

Chapter 10 Sections 10.6 through 10.11
Conduction & Convection Quiz 9 – 2014.01.27 TIME IS UP!!! A flat furnace wall is constructed with a 4.5-inch layer of refractory brick (k = 0.080 Btu/ft·h·

Conduction & Convection Quiz 9 – TIME IS UP!!! A flat furnace wall is constructed with a 4.5-inch layer of refractory brick (k = Btu/ft·h·
Convection in Flat Plate Turbulent Boundary Layers P M V Subbarao Associate Professor Mechanical Engineering Department IIT Delhi An Extra Effect For.

Convection in Flat Plate Turbulent Boundary Layers P M V Subbarao Associate Professor Mechanical Engineering Department IIT Delhi An Extra Effect For.
Estimation of Convective Heat Transfer Coefficient

Estimation of Convective Heat Transfer Coefficient
Two-Phase Flow Boiling Heat Transfer P M V Subbarao Professor Mechanical Engineering Department Selection of Optimal Parameters for Healthy and Safe Furnace.

Two-Phase Flow Boiling Heat Transfer P M V Subbarao Professor Mechanical Engineering Department Selection of Optimal Parameters for Healthy and Safe Furnace.
Chapter 4.2: Flow Across a Tube Bundle Heat Exchanger (Tube Bank)

Chapter 4.2: Flow Across a Tube Bundle Heat Exchanger (Tube Bank)
Two-Phase: Overview Two-Phase Boiling Condensation

Two-Phase: Overview Two-Phase Boiling Condensation
Nucleate Boiling Heat Transfer P M V Subbarao Professor Mechanical Engineering Department Recognition and Adaptation of Efficient Mode of Heat Transfer.

Nucleate Boiling Heat Transfer P M V Subbarao Professor Mechanical Engineering Department Recognition and Adaptation of Efficient Mode of Heat Transfer.
Heat transfer to fluids without phase change

Heat transfer to fluids without phase change
1 Dept. of Energy Technology, Div. of Applied Thermodynamics and Refrigeration Tube diameter influence on heat exchanger performance and design. Single.

1 Dept. of Energy Technology, Div. of Applied Thermodynamics and Refrigeration Tube diameter influence on heat exchanger performance and design. Single.
Environmentally Conscious Design & Manufacturing (ME592) Date: March 20, 2000 Slide:1 Environmentally Conscious Design & Manufacturing Class 7: Cutting.

Environmentally Conscious Design & Manufacturing (ME592) Date: March 20, 2000 Slide:1 Environmentally Conscious Design & Manufacturing Class 7: Cutting.
CE 1501 CE 150 Fluid Mechanics G.A. Kallio Dept. of Mechanical Engineering, Mechatronic Engineering & Manufacturing Technology California State University,

CE 1501 CE 150 Fluid Mechanics G.A. Kallio Dept. of Mechanical Engineering, Mechatronic Engineering & Manufacturing Technology California State University,
Nusselt Number Calculator Travis Kenworthy and and Matthew Christensen.

Nusselt Number Calculator Travis Kenworthy and and Matthew Christensen.
CHE/ME 109 Heat Transfer in Electronics

CHE/ME 109 Heat Transfer in Electronics
Introduction to Convection: Flow and Thermal Considerations

Introduction to Convection: Flow and Thermal Considerations
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 P M V Subbarao Professor Mechanical Engineering Department I I T Delhi Ideas for Creation of Compact HX!!!
Design of Condensers/Condensing Zones

Design of Condensers/Condensing Zones
G. Monni, M. De Salve, B. Panella Politecnico di Torino, C.so Duca degli Abruzzi 24, 10129 Torino HEFAT2014 10 th International.

G. Monni, M. De Salve, B. Panella Politecnico di Torino, C.so Duca degli Abruzzi 24, Torino HEFAT th International.
Fluid Dynamics: Boundary Layers

Fluid Dynamics: Boundary Layers
Two Phase Flow Modeling Prepared by: Tan Nguyen Two Phase Flow Modeling – PE 571 Chapter 3: Stratified Flow Modeling For Horizontal and Slightly Inclined.

Two Phase Flow Modeling Prepared by: Tan Nguyen Two Phase Flow Modeling – PE 571 Chapter 3: Stratified Flow Modeling For Horizontal and Slightly Inclined.

Similar presentations

Ads by Google