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Recap: Conservation Equations & Analysis of Finite Control Volume | Fluid Mechanics for Mechanical Engineering PDF Download

Recap
In this course you have learnt the following

  • A control mass or closed system is characterized by a fixed quantity of mass of a given identity, while in an open system or control volume mass may change continuously due to the flow of mass across the system boundary.
  • Continuity equation is the equation of conservation of mass in a fluid flow. The general form of the continuity equation for an unsteady compressible flow is given by
    Recap: Conservation Equations & Analysis of Finite Control Volume | Fluid Mechanics for Mechanical Engineering
     
  • The concept of stream function is a consequence of continuity. In a two dimensional incompressible flow, the difference in stream functions between two points gives the volume flow rate (per unit width in a direction perpendicular to the plane of flow) across any line joining the points. The value of stream function is constant along a streamline.
  • The equation of motion (conservation of momentum) of an inviscid flow is known as Euler’s equation. The general form of Euler’s equation is given by  Recap: Conservation Equations & Analysis of Finite Control Volume | Fluid Mechanics for Mechanical Engineering   where Recap: Conservation Equations & Analysis of Finite Control Volume | Fluid Mechanics for Mechanical Engineering is the body force vector per unit mass and Recap: Conservation Equations & Analysis of Finite Control Volume | Fluid Mechanics for Mechanical Engineering the velocity vector. Euler’s equation along a streamline, with gravity as the only body force, can be written as
    Recap: Conservation Equations & Analysis of Finite Control Volume | Fluid Mechanics for Mechanical Engineering      ( where s represents the coordinate along the streamline.)
     
  • Reynolds transport theorem states the relation between equations applied to a system and those applied to a control volume. The statement of the law of conservation of momentum as applied to a control volume is known as momentum theorem. This theorem states that the resultant force (or torque) acting on a control volume is equal to the time rate of increase in linear momentum (or angular momentum) within the control volume plus the rate of net efflux of linear momentum (or angular momentum) from the control volume.
     
  • A fluid element in motion possesses intermolecular energy, kinetic energy and potential energy. The work required by a fluid element to move against pressure is known as flow work. It is loosely termed as pressure energy. The shaft work is the work interaction between the control volume and the surrounding that takes place by the action of
    shear force such as the torque exerted on a rotating shaft. The equation for conservation of energy of a steady, in viscid and incompressible flow in a conservative body force field is known as Bernoulli’s equation.
    Bernoulli’s equation in the case of gravity as the only body force field is given by

    Recap: Conservation Equations & Analysis of Finite Control Volume | Fluid Mechanics for Mechanical Engineering    (The value of C remains constant along a streamline.)
     
  • The loss of mechanical energy due to friction in a real fluid is considered in Bernoulli’s equation as

             Recap: Conservation Equations & Analysis of Finite Control Volume | Fluid Mechanics for Mechanical Engineering

where, hf = frictional work done or loss of mechanical energy due to friction per unit weight of a fluid element while movingfrom station 1 to 2 along a streamline. The term hf is usually referred to as head loss.

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FAQs on Recap: Conservation Equations & Analysis of Finite Control Volume - Fluid Mechanics for Mechanical Engineering

1. What are conservation equations in civil engineering?
Ans. Conservation equations in civil engineering refer to a set of mathematical equations used to describe the conservation of mass, momentum, and energy within a given control volume. These equations are fundamental in analyzing fluid flow and heat transfer problems in various civil engineering applications.
2. How are conservation equations applied in the analysis of finite control volumes?
Ans. Conservation equations are applied in the analysis of finite control volumes by considering the inflow and outflow of mass, momentum, and energy across the control volume boundaries. By applying the conservation equations to the control volume, engineers can analyze and predict the behavior of fluid flow and heat transfer within the system.
3. What is the significance of analyzing finite control volumes in civil engineering?
Ans. Analyzing finite control volumes is significant in civil engineering as it allows engineers to evaluate the behavior of fluids and heat transfer in specific regions of interest within a larger system. This analysis provides insights into the performance and efficiency of various civil engineering processes, such as fluid flow in pipes or heat transfer in building systems.
4. How can conservation equations be used to solve civil engineering problems?
Ans. Conservation equations can be used to solve civil engineering problems by formulating them into mathematical models and applying appropriate numerical methods. These models can then be solved using computational tools or software to obtain quantitative results. By solving conservation equations, engineers can make informed decisions and optimize the design and operation of civil engineering systems.
5. What are some common civil engineering applications where conservation equations are used?
Ans. Conservation equations are commonly used in civil engineering applications such as fluid flow analysis in pipes, channels, and rivers; heat transfer analysis in buildings, bridges, and tunnels; and pollutant transport analysis in environmental engineering. These equations provide a systematic approach to understanding and predicting the behavior of fluids and energy in various civil engineering systems.
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