Understanding Thermodynamics and Fluid Mechanics Fundamentals for Efficiency
Explore key concepts in thermodynamics and fluid mechanics such as the equation of continuity, the first law of thermodynamics, the momentum equation, Euler's equation, and more. Learn about efficiency, internal energy, and the laws governing energy transfer in various systems. Delve into topics like moment of momentum, Euler's pump and turbine equations, and the significance of rothalpy in compressors and pumps. Gain insights into entropy and the second law of thermodynamics to enhance your understanding of energy principles in engineering applications.
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2ndlecture Basic Thermodynamics, Fluid Mechanics: Definitions of Efficiency
The equation of continuity (cnis the normal velocity component to the flow surface) If A1 and A2 are the flow areas at stations 1 and 2 along a passage respectively, then The first law of thermodynamics - internal energy During a change of state from 1 to 2, there is a change in the property internal energy, For an infinitesimal change of state
The momentum equation- Newtons second law of motion This equation is the one-dimensional form of the steady flow momentum equation. Euler s equation of motion Bernoulli s equation
Moment of momentum For a system of mass m, the vector sum of the moments of all external forces acting on the system about some arbitrary axis A A fixed in space is equal to the time rate of change of angular momentum of the system about that axis, i.e. where r is distance of the mass centre from the axis of rotation measured along the normal to the axis and c the velocity component mutually perpendicular to both the axis and radius vector r. For a control volume the law of moment of momentum can be obtained. The figure shows the control volume enclosing the rotor of a generalized turbomachine. Swirling fluid enters the control volume at radius r1 with tangential velocity c 1and leaves at radius r2with tangential velocity c 2. For one-dimensional steady flow
Eulers pump and turbine equations For a pump or compressor rotor running at angular velocity , the rate at which the rotor does work on the fluid is The work done on the fluid per unit mass or specific work, is This equation is referred to as Euler s pump equation. For a turbine the fluid does work on the rotor and the sign for work is then reversed. Thus, the specific work is This equation is the Euler s turbine equation.
Defining rothalpy In a compressor or pump the specific work done on the fluid equals the rise in stagnation enthalpy. Thus, combining the angular momentum equation with the energy equation we get After some rearranging of this equation and rewriting , we get The function I has the name rothalpy, rotational stagnation enthalpy. As the value of rothalpy is apparently unchanged between entry and exit of the impeller it is deduced that it must be constant along the flow lines between these two stations. Thus, the rothalpy can be written generally as The second law of thermodynamics- entropy The property called entropy, for a finite change of state, is then defined as
Gibbs equation For a system of mass m undergoing a reversible process dQ = dQR = mTds and dW =dWR = mpdv. In the absence of motion, gravity and other effects the first law of thermodynamics becomes With h = u+ pv then dh = du + pdv + vdp and then
Definitions of efficiency Efficiency of turbines the overall efficiency 0 The isentropic efficiency tor hydraulic efficiency hfor a turbine is, the mechanical efficiency m, which is simply the ratio of shaft power to rotor power, is
For an incremental change of state through a turbomachine the steady flow energy equation can be written as From the second law of thermodynamics rearranging For a reversible adiabatic process
Steam and gas turbines From Figure (a), neglecting the potential energy effect, the actual turbine rotor specific work is: Similarly, the ideal turbine rotor specific work between the same two pressures is
Total-to-total efficiency The turbine and stage adiabatic efficiency , is the total-to-total efficiency and is defined as Total-to-static efficiency ts. When the exhaust kinetic energy is not usefully employed and entirely wasted, the relevant adiabatic efficiency is the total-to-static efficiency ts. If the difference between inlet and outlet kinetic energies is small Hydraulic turbines The turbine hydraulic efficiency h, is defined as the work supplied by the rotor in unit time divided by the hydrodynamic energy difference of the fluid per unit time,