Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering PDF Download

Low Reynolds Number Flow

We have seen earlier that Reynolds number is the ratio of inertia force to viscous force. For flow at low Reynolds number, the inertia terms in the Navier-Stokes equations become small as compared to viscous terms. As such, when the inertia terms are omitted from the equations of motion, the analyses are valid for only Re << 1. Consequently, this approximation, linearizes the Navier-Stokes equations and for some problems, makes it amenable to analytical solutions.

In the next two slides we will discuss such flows. Motions at very low Reynolds number are sometimes referred to as creeping motion.

 

Theory of Hydrodynamic Lubrication

  • Thin film of oil, confined between the interspace of moving parts, may acquire high pressures up to 100 MPa which is capable of supporting load and reducing friction. The salient features of this type of motion can be understood from a study of slipper bearing (Fig. 27.2). The slipper moves with a constant velocity past the bearing plate. This slipper face and the bearing plate are not parallel but slightly inclined at an angle of α. A typical bearing has a gap width of 0.025 mm or less, and the convergence between the walls may be of the order of 1/5000. It is assumed that the sliding surfaces are very large in transverse direction so that the problem can be considered two-dimensional.

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering  

  • For the analysis, we may assume that the slipper is at rest and the plate is forced to move with a constant velocity .
  • The height h(x) of the wedge between the block and the guide is assumed to be very small as compared with the length l of the block.
  • The essential difference between this motion and that discussed in Lecture 26  Couette flow) is that here the two walls are inclined at an angle to each other.
  • Due to the gradual reduction of narrowing passage, the convective acceleration  Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering  is distinctly not zero.
  • For all practical purposes, inertia terms can be neglected as compared to viscous term. This can be justified in following way

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering

The inertia force can be neglected with respect to viscous force if the modified Reynolds number,

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering

  • The equation for motion in direction can be omitted since the component of velocity is very small with respect to . Besides, in the x-momentum equation, Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering can be neglected as compared withLow Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering because the former is smaller than the latter by a factor of the order of Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering With these simplifications the equations of motion reduce to

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering                                                                (27.6)

The equation of continuity can be written as :

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering                                                                 (27.7)   

 

The boundary conditions are: 
at y = 0, u = U at x = 0, p = p0
at y = h, u = 0 and at x = l, p = p0                                      (27.8)

 

  • Integrating Eq. (27.6) with respect to , we obtain

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering

  • Application of the kinematic boundary conditions (at y=0, u =U and y = h, U=0), yields

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering                          ( 27.9)  

Note thaLow Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering is constant as far as integration along is concerned, but and Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering vary along -axis.  

 

At the point of maximum pressure, Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering =0 hence

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering

  • Equation (27.10) depicts that the velocity profile along is linear at the location of maximum pressure. The gap at this location may be denoted as h*.
  • Substituting Eq. (27.9) into Eq. (27.8) and integrating, we get

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering                                          (27.11)

where  p' = dp/dx

 

  • Integrating Eq. (27.11) with respect to , we obtain

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering                   (27.12a)        

 

 

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering                 (27.12b)

 

where  Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering    is a constant

  • Since the pressure must be the same (p = p0), at the ends of the bearing, namely, p = p0 at x = 0 and p = p0 at x=l, the unknowns in the above equations can be determined by applying the pressure boundary conditions. We obtain

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering

  • With these values inserted, the equation for pressure distribution (27.12) becomes

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering                                                  (27.13)      

 

  • It may be seen from Eq. (27.13) that, if the gap is uniform, i.e. h = h1=h2, the gauge pressure will be zero. Furthermore, it can be said that very high pressure can be developed by keeping the film thickness very small.
  • Figure 27.2 shows the distribution of pressure throughout the bearing.

 

Theory of Hydrodynamic Lubrication... cont from previous slide

 

  • The total load bearing capacity per unit width is

                                       

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering

After substituting h=h- αx with α=(h1-h2)/ l in the above equation and performing the integration,

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering                                  (27.14)


 

  • The shear stress at the bearing plate is

 

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering                             (27.15)

 

Substituting the value of P' from Eq. (27.14) and then invoking the value of Q in Eq. (27.15), the final expression for shear stress becomes

 

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering

 

  • The drag force required to move the lower surface at speed is expressed by

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering                          (27.16)

 

  • Michell thrust bearing, named after A.G.M. Michell, works on the principles based on the theory of hydrodynamic lubrication . The journal bearing (Fig. 27.3) develops its force by the same action, except that the surfaces are curved.

Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering  

 

The document Low Reynolds Number Flow | Fluid Mechanics for Mechanical Engineering is a part of the Mechanical Engineering Course Fluid Mechanics for Mechanical Engineering.
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FAQs on Low Reynolds Number Flow - Fluid Mechanics for Mechanical Engineering

1. What is low Reynolds number flow?
Ans. Low Reynolds number flow refers to the flow of a fluid at a relatively low velocity, where the inertial forces are much smaller compared to the viscous forces. In this flow regime, the fluid behaves differently, exhibiting characteristics such as laminar flow, slower rates of mixing, and increased fluid resistance.
2. What are some examples of low Reynolds number flow?
Ans. Some examples of low Reynolds number flow include the flow of blood in small blood vessels, the motion of microorganisms in water, the flow of air around small insects, and the flow of fluids in microchannels or microfluidic devices.
3. How is low Reynolds number flow different from high Reynolds number flow?
Ans. Low Reynolds number flow is characterized by slow and smooth flow patterns, with the fluid moving in well-defined layers. In contrast, high Reynolds number flow is characterized by turbulence, eddies, and chaotic flow patterns. At high Reynolds numbers, the inertial forces dominate over the viscous forces, resulting in a different flow behavior.
4. What are the applications of studying low Reynolds number flow?
Ans. Understanding low Reynolds number flow is crucial in various fields, including biology, biomedical engineering, microfluidics, and aerospace engineering. It helps in designing efficient microfluidic devices, studying the motion of microorganisms, optimizing drug delivery systems, and improving the performance of small-scale aircraft and drones.
5. How can the behavior of low Reynolds number flow be described mathematically?
Ans. The behavior of low Reynolds number flow can be described mathematically using the Stokes flow equations, which are simplified versions of the Navier-Stokes equations. These equations take into account the viscous forces and neglect the inertial forces. Solving these equations allows researchers to predict the flow behavior, velocity profiles, and pressure distribution in low Reynolds number flows.
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