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Concept of Flow Potential and Flow Resistance

  • Consider the flow of water from one reservoir to another as shown in Fig. 35.3. The two reservoirs A and B are maintained with constant levels of water. The difference between these two levels is Introduction: Applications of Viscous Flows Through Pipes - 2 | Fluid Mechanics for Mechanical Engineering as shown in the figure. Therefore water flows from reservoir to reservoir .

Introduction: Applications of Viscous Flows Through Pipes - 2 | Fluid Mechanics for Mechanical Engineering

 

  • Application of Bernoulli's equation between two points and at the free surfaces in the two reservoirs gives

Introduction: Applications of Viscous Flows Through Pipes - 2 | Fluid Mechanics for Mechanical Engineering

where hf is the loss of head in the course of flow from to .

  • Therefore, Eq. (35.10) states that under steady state, the head causing flow Δ H becomes equal to the total loss of head due to the flow. 
  • Considering the possible hydrodynamic losses, the total loss of head hf can be written in terms of its different components as 

Introduction: Applications of Viscous Flows Through Pipes - 2 | Fluid Mechanics for Mechanical Engineering                             35.11

 

Loss of heat at                 Friction loss in                           Exit loss to the 
 entry to the pipe                pipe over its                              reservoir B                             
  from reservoir A                length L  
                                      

 where, is the average velocity of flow in the pipe.


(contd from previous...) Concept of Flow Potential and Flow Resistance

The velocity in the above equation is usually substituted in terms of flow rate , since, under steady state, the flow rate remains constant throughout the pipe even if its diameter changes. Therefore, replacing V in Eq. (35.11) as  Introduction: Applications of Viscous Flows Through Pipes - 2 | Fluid Mechanics for Mechanical Engineering  we finally get 

 

Introduction: Applications of Viscous Flows Through Pipes - 2 | Fluid Mechanics for Mechanical Engineering                     (35.12)     


 Introduction: Applications of Viscous Flows Through Pipes - 2 | Fluid Mechanics for Mechanical Engineering

 

Introduction: Applications of Viscous Flows Through Pipes - 2 | Fluid Mechanics for Mechanical Engineering                       (35.13)     

 

The term is defined as the flow resistance .

In a situation where f becomes independent of Re, the flow resistance expressed by Eg. (35.13) becomes simply a function of the pipe geometry. With the help of Eq. (35.10), Eq. (35.12) can be written as                 

Introduction: Applications of Viscous Flows Through Pipes - 2 | Fluid Mechanics for Mechanical Engineering                                                            ( 35.14)

 

 ΔH in Eq. (35.14) is the head causing the flow and is defined as the difference in flow potentials between A and B. 

This equation is comparable to the voltage-current relationship in a purely resistive electrical circuit. In a purely resistive electrical circuit,  ΔV = Rl, where  ΔVis the voltage or electrical potential difference across a resistor whose resistance is R and the electrical current flowing through it is I

  • The difference however is that while the voltage drop in an electrical circuit is linearly proportional to current, the difference in the flow potential in a fluid circuit is proportional to the square of the flow rate. 
  • Therefore, the fluid flow system as shown in Fig. 35.3 and described by Eq. (35.14) can be expressed by an equivalent electrical network system as shown in Fig. 35.4.

Introduction: Applications of Viscous Flows Through Pipes - 2 | Fluid Mechanics for Mechanical Engineering

Fig 35.4 Equivalent electrical network system for a simple pipe flow problem shown in Fig.35.3

The document Introduction: Applications of Viscous Flows Through Pipes - 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 Introduction: Applications of Viscous Flows Through Pipes - 2 - Fluid Mechanics for Mechanical Engineering

1. What are some common applications of viscous flows through pipes?
Ans. Some common applications of viscous flows through pipes include oil and gas transportation, water distribution, chemical processing, and sewage systems. Viscous flows are also present in various industrial processes such as cooling systems, lubrication, and hydraulic systems.
2. How is the flow rate affected by the viscosity of the fluid?
Ans. The viscosity of the fluid affects the flow rate through a pipe. Higher viscosity results in slower flow rates, as the resistance to flow increases. Conversely, lower viscosity leads to faster flow rates, as there is less resistance to the movement of the fluid.
3. What is the Reynolds number and how does it relate to viscous flows through pipes?
Ans. The Reynolds number is a dimensionless quantity used to predict the flow regime in a pipe. It is calculated by multiplying the fluid velocity, pipe diameter, and fluid density, and dividing it by the fluid viscosity. In viscous flows through pipes, the Reynolds number helps determine whether the flow is laminar (smooth and orderly) or turbulent (chaotic and irregular).
4. How does pipe diameter affect viscous flows?
Ans. The diameter of the pipe has a significant impact on viscous flows. A larger pipe diameter allows for higher flow rates with lower pressure drop, as there is more space for the fluid to flow. Conversely, a smaller pipe diameter increases the resistance to flow, resulting in lower flow rates and higher pressure drop.
5. What factors can cause an increase in the pressure drop in viscous flows through pipes?
Ans. Several factors can cause an increase in pressure drop in viscous flows through pipes. These include higher fluid viscosity, smaller pipe diameter, longer pipe length, and higher flow rates. Additionally, the presence of obstacles or rough surfaces inside the pipe can also contribute to an increase in pressure drop.
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