Critical Reynolds Number in an Oscillating Pipe Flow
スポンサーリンク
概要
- 論文の詳細を見る
A previous investigation revealed that, when turbulent bursts occur, the instantaneous velocity distribution and friction factor in an oscillating pipe flow are represented by the well-known 1/7 power law and by the turbulent quasi-steady values, respectively. Theses facts suggest that the mechanism of generating turbulence in an oscillating pipe flow is similar to that in a steady flow. Here an evaluation method of the critical Reynolds number is proposed by assuming that the generation region of turbulence is the same as that in a steady flow and by defining that the critical Reynolds number Reos, c is the value when the generation region is built up in a flow field. The estimated results agreed well with the experimental values. In addition, the relation between mean burst period T^^-_B in a steady turbulent pipe flow and critical frequency in an oscillating pipe flow at which turbulent bursts occur was obtained.
- 一般社団法人日本機械学会の論文
著者
-
IGUCHI Manabu
Faculty of Engineering, Osaka University
-
OHMI Munekazu
Faculty of Engineering, Osaka University
-
Iguchi Manabu
Faculty Engineering Osaka University
-
Ohmi Munekazu
Faculty Of Engineering Osaka University
-
Ohmi Munekazu
Faculty Engineering Osaka University
関連論文
- X-ray Fluoroscopic Observation of Bubble Characteristics in a Molten Iron Bath
- デローニー三角分割に基づく新しいPIV相関アルゴリズムの提案
- Transient Powder-Laden Liquid Jet in a Pipe Flow
- The Structure of Turbulence in Pulsatile Pipe Flow Accompanied by Relaminarization
- Velocity Distributions in Laminar Phases for Oscillatory Rectangular Duct Flows with Occurrence of Turbulent Transition
- Time-Dependent Wall Shear Stress in a Duct with Arbitrary Cross-Section
- Laminar-Turbulent Transition and Velocity Profiles of Oscillatory Rectangular Duct Flows
- Flow Pattern and Frictional Losses in Pulsating Pipe Flow : Part 5, Wall Shear Stress and Flow Pattern in a Laminar Flow
- Flow Pattern and Frictional Losses in Pulsating Pipe Flow : Part l, Effect of Pulsating Frequency on the Turbulent Flow Pattern
- A Experimental Study of Velocity Distribution and Inlet Length in the Inlet Region of Laminar Oscillatory Pipe Flow : Series B : Fluid Engineering, Heat Transfer, Combustion, Power, Thermophysical, Properties
- Turbulent Slug and Velocity Field in the Inlet Region for Pulsatile Pipe Flow : Fluids Engineering
- Flow Patterns and Frictional Losses in an Oscillating Pipe Flow
- Transition to Turbulence in a Pulsatile Pipe Flow Part 1,Wave Forms and Distribution of Pulsatile Velocities near Transition Region
- Velocity Distribution and Reattachment Length in an Oscillatory Pipe Flow through a Plate Orifice
- Radial Propagation of Turbulence in Pulsatile Pipe Flow
- Cold Model Experiment on Fluid Flow Phenomena in Hot Dip Plating Bath
- Behavior of Turbulent Slugs in a Transient Pipe Flow
- Mean Flow Characteristics of a Pulsating Round Jet
- A Study on Velocity Profiles of Developing Laminar Oscillatory Flows in a Square Duct
- Flow Pattern and Frictional Losses in Pulsating Pipe Flow : Part 7 Wall Shear Stress in a Turbulent Flow
- Flow Pattern and Frictional Losses in Pulsating Pipe Flow : Part 2, Effect of Pulsating Frequency on the Turbulent Frictional Losses
- Transition to Turbulence in a Pulsatile Pipe Flow : Part 2,Characteristics of Reversing Flow Accompanied by Relaminarization
- Critical Reynolds Number in an Oscillating Pipe Flow
- Free Oscillatory Flow Across a Plate Orifice in U-Shaped Tube and the Resistance Law
- Transition to Turbulence in a Pulsatile Pipe Flow : 3rd Report, Flow Regimes and the Conditions Describing the Generation and Decay of Turbulence
- Flow Pattern and Frictional Losses in Pulsating Pipe Flow : Part 3, General Representation of Turbulent Flow Pattern
- Analysis of Free Oscillating Flow in a U-Shaped Tube
- Turbulence Structure in a Relatively Low Frequency Pulsatile Pipe Flow : Series B : Fluid Engineering, Heat Transfer, Combustion, Power, Thermophysical Properties
- Flow Pattern and Frictional Losses in Pulsating Pipe Flow : Part 6 Frictional Losses In a Laminar Flow
- Loss Coefficients for Flows Through a Sudden Expansion and a Sudden Contraction Closely Placed : Series B : Fluid Engineering, Heat Transfer, Combustion, Power, Thermophysical Properties
- Experimental Study of Turbulence in a Pulsatile Pipe Flow
- Transition to Turbulence and Velocity Distribution in an Oscillating Pipe Flow
- Flow Pattern and Frictional Losses in Pulsating Pipe Flow : Part 4, General Representation of Turbulent Frictional Losses
- Mean Velocity and Turbulence of Water Flow in a Cylindrical Vessel Agitated by Bottom Air Injection
- Pressure and Velocity Distributions in Pulsating Turbulent Pipe Flow Part 2 Experimental Investigations
- Numerical Analysis of Transient Turbulent Flow in a Liquid Line
- Numerical Analysis of a Periodically Varying Flow in a Circular Tube Containing a Slightly Compressible Fluid
- Numerical Analysis of Pressure and Velocity Distributions for a Pulsating Turbulent Flow in a Circular Tube Containing a Slightly Compressible Fluid
- Pressure and Velocity Distributions in Pulsating Turbulent Pipe Flow Part 1 Theoretical Treatments
- Dealloying of Cu-Zn Alloy Microchannel Lining Layers for Producing Microporous Catalyst
- Mixing Time in a Cylindrical Bath Agitated by Gas Injection through a Multi-hole Nozzle
- Fabrication of Alumina Coating on Ni-Al Alloy Microchannel Wall for Catalyst Supporting
- Fabrication of Microchannels in Metallic Wire Bundles by a Sacrificial-Core Method
- Anodization of the Inner Wall of the Microchannel Formed in Sintered Aluminum Body
- Alkali Leaching of Ni-Al Alloy Microchannel Lining Layers
- Gas-Liquid Two-Phase Flow through at Orifice in Millimeter-Scale Rectangular Channel
- Fabrication of Ni-Al Alloy Transpiration-Cooling Device by Powder-Metallurgical Microchanneling Process
- Re-examination of method of kinetic analysis on the rate of stepwise reduction of a single sinter particle with CO-CO2-N2 gas mixture.
- Structure Control of Cu-Zn Microchannel Lining Layers with Electrochemical Dissolution
- Characteristics of Poorly-Wetted Two Spheres Penetrating into a Water Bath
- Fabrication of Free-Form Channels by a combined process of Metal Injection Molding and Sacrificial-Core Method
- Anodic Oxidation Behavior of Al-Zn Alloy Lining Layer Produced by a Sacrificial-Core Method
- Composition and Structure Changes in Al_3Ni_2 Microchannel Lining Layers by Alkali Leaching
- Filtration of Ni-Al Alloy Containing By-Product Alumina in Centrifugal Combustion Synthesis
- Cold Model Study of Spout Eye Area in the Presence of the Slag Layer Simulated by Low-Density Particles
- Bubble Behavior in Hg-Air Vertical Bubbling Jets in a Cylindrical Vessel.
- Evaluation of Critical Gas Flow Rate for the Entrapment of Slag Using a Water Model.
- Flow phenomena and heat transfer around a sphere submerged in water jet and bubbling jet.
- The characteristics of water and bubbling jets in a cylindrical vessel with bottom blowing.
- Heat Transfer between Bubbles and Liquid during Cold Gas Injection.
- The Effective Viscosity and Effective Diffusivity of Bubbles in an Air-Water Vertical Bubbling Jet.
- Heat Transfer between Bubbles and Molten Wood's Metal.
- Cold Model Experiments for Developing a New Velocimeter Applicable to Molten Metal.
- The flow field in air-water vertical bubbling jets in a cylindrical vessel.
- Bubble Characteristics in the Buoyancy Region of a Vertical Bubbling Jet.