Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering PDF Download

Applications-

  • Equation (26.8) is commonly used in the measurement of viscosity with the help of capillary tube viscometers . Such a viscometer consists of a constant head tank to supply liquid to a capillary tube (Fig. 26.4).

 

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering  

  • Pressure drop readings across a specified length in the developed region of the flow are taken with the help of a manometer. The developed flow region is ensured by providing the necessary and sufficient entry length.
  • From Eq. (26.8), the expression for viscosity can be written as

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering

  • The volumetric flow rates (Q) are measured by collecting the liquid in a measuring cylinder. The diameter (D) of the capillary tube is known beforehand. Now the viscosity of a flowing fluid can easily be evaluated.
  • Shear stress profile across the cross-section can also be determined from this information. Shear stress at any point of the pipe flow is given by

 

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering

 

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering                                          (26.9a)

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering                             (26.9b)

This also indicates that τ varies linearly with the radial distance from the axis.

  • At the wall, τ  assumes the maximum value.

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering

 

as it should be. Negative sign indicates that the force is acting in opposite to the flow direction. 

  • However, from Eq. (26.6b), we can write

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering                                                                                           (26.9c)

 

 

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering                                                                                             (26.10)

 

Losses and Friction Factors

  • Over a finite length l , the head loss  Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering                            (26.11) 
    Combining Eqs (26.10) and (26.11), we get

 

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering                                                                           (26.12) 

 

  • On the other hand, the head loss in a pipe flow is given by Darcy-Weisbach formula as

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering                                                                                                     (26.13)

 

where "f" is Darcy friction factor . Equations (26.12) and (26.13) yield

  Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering

which finally gives Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering, where Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering is the Reynolds number.

 

  • So, for a fully developed laminar flow, the Darcy (or Moody) friction factor is given by

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering                                                                                                                        (26.14a)                                                                                                              

 

Alternatively, the skin friction coefficient for Hagen-Poiseuille flow can be expressed by

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering

With the help of Eqs (26.9b) and (26.9c), it can be written

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering

The skin friction coefficient Cf is called as Fanning's friction factor . From comparison of Eqs (26.14a) and (26.14b), it appears

 

 

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering                                                                                                           (26.14b)

 

  • For fully developed turbulent flow, the analysis is much more complicated, and we generally depend on experimental results. Friction factor for a wide range of Reynolds number (104 to 108) can be obtained from a look-up chart . Friction factor, for high Reynolds number flows, is also a function of tube surface condition. However, in circular tube, flow is laminar for Re ≤ 2300 and turbulent regime starts with Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering.
  • The surface condition of the tube is another responsible parameter in determination of friction factor.
  • Friction factor in the turbulent regime is determined for different degree of surface-roughness Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering of the pipe, where ∈ is the dimensional roughness and Dh is usually the hydraulic diameter of the pipe .
  • Friction factors for different Reynolds number and surface-roughness have been determined experimentally by various investigators and the comprehensive
  • results are expressed through a graphical presentation which is known as Moody Chart after L.F. Moody who compiled it.
  • The hydraulic diameter which is used as the characteristic length in determination of friction factor, instead of ordinary geometrical diameter, is defined as

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering

where Aw is the flow area and Pw is the wetted perimeter .

  • Kinetic energy correction factor , α The kinetic energy associated with the fluid flowing with its profile through elemental area  Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering  and the total kinetic energy passing through per unit time

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering

This can be related to the kinetic energy due to average velocity Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering  through a correction factor, α

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering

 

  • Here, for Hagen-Poiseuille flow,

Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering                                                          (26.16)

 

The document Couette Flow - 2 | Fluid Mechanics for Mechanical Engineering is a part of the Mechanical Engineering Course Fluid Mechanics for Mechanical Engineering.
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FAQs on Couette Flow - 2 - Fluid Mechanics for Mechanical Engineering

1. What is Couette flow?
Ans. Couette flow is a type of fluid flow where the fluid is confined between two parallel plates, with one plate moving and the other stationary. This flow is characterized by a linear velocity profile, where the velocity of the fluid increases linearly from the stationary plate to the moving plate.
2. How is Couette flow different from Poiseuille flow?
Ans. Couette flow and Poiseuille flow are both types of fluid flow, but they have some key differences. In Couette flow, the fluid is confined between two parallel plates, with one plate moving and the other stationary, resulting in a linear velocity profile. In Poiseuille flow, the fluid flows through a cylindrical pipe, and the velocity profile is parabolic. Additionally, Couette flow is driven by the movement of the plates, while Poiseuille flow is driven by a pressure difference along the pipe.
3. What are the applications of Couette flow?
Ans. Couette flow has several applications in various fields. It is commonly used in rheology studies to understand the flow behavior of different fluids. It is also used in engineering applications such as lubrication systems, where the motion of one plate provides a shearing force to reduce friction between two surfaces. Couette flow is also utilized in the manufacturing of certain materials, such as the controlled deposition of thin films.
4. How is Couette flow affected by the gap between the plates?
Ans. The gap between the plates in Couette flow has a significant impact on the flow behavior. As the gap decreases, the velocity gradient between the plates increases, resulting in a higher shear rate and shear stress. This leads to a higher resistance to flow and a thicker boundary layer near the plates. Conversely, as the gap increases, the velocity gradient decreases, resulting in a lower shear rate and shear stress, and a thinner boundary layer.
5. What is the significance of studying Couette flow in mechanical engineering?
Ans. Studying Couette flow is crucial in mechanical engineering as it helps in understanding fluid behavior and developing efficient lubrication systems. By analyzing the flow characteristics, engineers can design optimal systems that minimize friction and wear between moving parts. Additionally, Couette flow serves as a fundamental building block for more complex fluid flow problems, making it essential for engineers working in fields such as fluid dynamics, heat transfer, and materials processing.
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