Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering PDF Download

Couette Flow

Couette flow is the flow between two parallel plates (Fig. 26.1). Here, one plate is at rest and the other is moving with a velocity . Let us assume the plates are infinitely large in direction, so the dependence is not there.

The governing equation is
Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

flow is independent of any variation in z-direction. 
The boundary conditions are ---(i)At y = 0, u = 0 (ii)At y = h, u = U.

 

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

 

  • We get,

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

Invoking the condition (at y = 0, u = 0), C2 becomes equal to zero.

 

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

Invoking the other condition (at y = h, u = U),

 

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

Equation (26.1) can also be expressed in the form

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

Where 

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

 

Equation (26.2a) describes the velocity distribution in non-dimensional form across the channel with P as a parameter known as the non-dimensional pressure gradient .

  • When P = 0, the velocity distribution across the channel is reduced to

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

This particular case is known as simple Couette flow.

  • When P > 0 , i.e. for a negative or favourable pressure gradient  Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering  in the direction of motion, the velocity is positive over the whole gap between the channel walls. For negative value of P ( P < 0 ), there is a positive or adverse pressure gradient in the direction of motion and the velocity over a portion of channel width can become negative and back flow may occur near the wall which is at rest. Figure 26.2ashows the effect of dragging action of the upper plate exerted on the fluid particles in the channel for different values of pressure gradient.

 

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

 

Maximum and minimum velocities

The quantitative description of non-dimensional velocity distribution across the channel, depicted by Eq. (26.2a), is shown

in Fig. 26.2b.

  • The location of maximum or minimum velocity in the channel is found out by setting du/dy =0. From Eq. (26.2a), we can write

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

Setting  Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering  gives

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering                                                                                            ( 26.2b)

 

 

  • It is interesting to note that maximum velocity for P = 1 occurs at y/h = 1 and equals to . For P > 1, the maximum velocity occurs at a location Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering .
  • This means that with P > 1, the fluid particles attain a velocity higher than that of the moving plate at a location somewhere below the moving plate.
  • For P = -1, the minimum velocity occurs,  at Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering. For P < -1,  the minimum velocity occurs at a location Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering.
  • This means that there occurs a back flow near the fixed plate. The values of maximum and minimum velocities can be determined by substituting the value of from Eq. (26.2b) into Eq. (26.2a) as 
  • This means that there occurs a back flow near the fixed plate. The values of maximum and minimum velocities can be determined by substituting the value of from Eq. (26.2b) into Eq. (26.2a) as

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering                                                                 (26.2c)

 

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

 

Hagen Poiseuille Flow

  • Consider fully developed laminar flow through a straight tube of circular cross-section as in Fig. 26.3. Rotational symmetry is considered to make the flow two-dimensional axisymmetric.
  • Let us take z-axis as the axis of the tube along which all the fluid particles travel, i.e

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

  • Now, from continuity equation, we obtain

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

  • Invoking  Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering  in the

Navier-Stokes equations, we obtain

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering                                                               (26.3)

  • For steady flow, the governing equation becomes

 

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering                                                                                 (26.4)

 

The boundary conditions are- (i) At r =0  vz is finite and (ii) r = R, vz  = 0 yields

  • Equation (26.4) can be written as

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

 

  • At r =0  vz is finite which means A should be equal to zero and at r = R, vz  = 0  yields

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering                                                              (26.5)

  • This shows that the axial velocity profile in a fully developed laminar pipe flow is having parabolic variation along r.
  • At r = 0, as such,  Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering                                            (26.6a)           

 

  • The average velocity in the channel,

 

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering

 

 

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering                                                           (26.6b)

 

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering                                                                           ( 26.6c)

 

  • Now, the discharge (Q) through a pipe is given by

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering                                      (26.7)                        

 

 

Couette Flow - 1 | Fluid Mechanics for Mechanical Engineering                                                                        (26.8)

The document Couette Flow - 1 | 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 - 1 - Fluid Mechanics for Mechanical Engineering

1. What is Couette flow in mechanical engineering?
Ans. Couette flow is a type of fluid flow in mechanical engineering where a viscous fluid is confined between two parallel plates, with one plate moving relative to the other. This flow is characterized by a linear velocity profile, with the fluid particles near the stationary plate having zero velocity and the particles near the moving plate having a maximum velocity.
2. What are the applications of Couette flow in mechanical engineering?
Ans. Couette flow has various applications in mechanical engineering, including lubrication systems, viscous fluid flow analysis, and rheology studies. It is also used in the design and analysis of fluid bearings, squeeze film dampers, and flow sensors. Couette flow is particularly useful in understanding and predicting the behavior of fluids in narrow gaps or channels.
3. How is the velocity profile determined in Couette flow?
Ans. The velocity profile in Couette flow is determined by the no-slip condition, which states that the fluid particles at the solid boundaries have zero velocity. As a result, the velocity of each fluid layer varies linearly between the two plates. The velocity profile can be mathematically expressed as a function of the distance from the stationary plate to the moving plate.
4. What factors affect the flow rate in Couette flow?
Ans. Several factors can affect the flow rate in Couette flow. The viscosity of the fluid is a significant factor, as higher viscosity leads to a slower flow rate. The distance between the two plates, known as the gap width, also affects the flow rate, with smaller gaps resulting in higher flow rates. Additionally, the velocity of the moving plate and the length of the channel can impact the flow rate.
5. How is Couette flow different from other types of fluid flow?
Ans. Couette flow differs from other types of fluid flow, such as Poiseuille flow or laminar flow, in terms of the flow geometry. While Poiseuille flow occurs in a cylindrical pipe with a pressure gradient, Couette flow occurs between two parallel plates with a relative motion. The velocity profile in Couette flow is linear, unlike the parabolic velocity profile in Poiseuille flow.
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