ENGR251: Steady flow work

Lyes Kadem

23 Nov 202011:34

Summary

TLDRThis video discusses steady flow work in thermodynamics, specifically for open systems such as turbines, compressors, and pumps. The script begins by comparing the work done in closed systems (like piston-cylinder assemblies) to work done in open systems. It explores concepts such as conservation of mass, the first and second laws of thermodynamics, and isentropic processes. The formula for steady flow work is derived, emphasizing assumptions like steady-state, adiabatic, and isentropic conditions. The video concludes by comparing work calculations for closed and open systems, offering a deeper understanding of energy transfer in fluid-based devices.

Takeaways

😀 Steady flow work is introduced as an extension of work calculations for closed systems to include devices like turbines, pumps, and compressors in open systems.
😀 In closed systems, work is calculated using the integral of pressure times volume change (p dv), but for steady flow work, the equation becomes more complex and adapted for open systems.
😀 The conservation of mass in open systems states that the mass flow rate in equals the mass flow rate out, implying steady-state conditions (no mass accumulation).
😀 The first law of thermodynamics is applied to steady flow systems, where the work is related to the change in enthalpy at the inlet and outlet of devices like turbines, pumps, and compressors.
😀 The term ‘steady flow’ means that the flow rate and the properties of the fluid (like mass flow) do not change with time within the system.
😀 Kinetic and potential energy changes are neglected in the analysis, as turbines, pumps, and compressors focus on work creation or work consumption rather than changes in kinetic or potential energy.
😀 For steady flow work, the formula for shaft work in a system like a turbine or pump is simplified to the enthalpy difference: W = ṁ(h_in - h_out).
😀 An important assumption for these devices is that the process is adiabatic (no heat transfer), which simplifies the first law equation by removing the heat term.
😀 The second law of thermodynamics is applied by considering an isentropic process, which is both adiabatic and reversible. This leads to the assumption that entropy changes are zero.
😀 The equation for work in an isentropic process becomes W = ∫ v dp, where v is specific volume, and dp represents the pressure change across the system.
😀 The work equation for steady flow systems in an isentropic process is derived as W = - ∫(p_out - p_in) v dp, which is the general formula for work in turbines, pumps, and compressors under these assumptions.

Q & A

What is the primary focus of the script?
-The primary focus of the script is the concept of steady flow work in thermodynamics, comparing closed systems like piston-cylinder assemblies with open systems such as turbines, pumps, and compressors. It aims to derive a general formula for work in open systems under specific assumptions.
What are the key assumptions made in the analysis of steady flow work?
-The key assumptions are: the system is in steady state (no mass accumulation), the process is adiabatic (no heat transfer), and the process is isentropic (reversible and adiabatic). Additionally, changes in kinetic and potential energy are neglected.
How is work calculated in a closed system, like a piston-cylinder assembly?
-In a closed system, work is calculated using the integral of pressure with respect to volume: W = ∫p dv, where pressure and volume change during compression or expansion.
How does steady flow work differ in open systems like turbines and pumps?
-In open systems, steady flow work is calculated using the integral of volume times the change in pressure: W = -∫v dp. This formulation accounts for the work done through a shaft in devices like turbines (work out) or pumps and compressors (work in).
What does it mean for the process to be steady in this context?
-A steady process means that there is no accumulation of mass within the control volume, implying that the mass flow rate in equals the mass flow rate out, and that the system operates under constant conditions.
Why are changes in kinetic and potential energy neglected in the steady flow work analysis?
-Changes in kinetic and potential energy are considered negligible in the analysis because the primary focus is on the work done by the system, which is related to the changes in enthalpy rather than the motion or position of the fluid.
What does isentropic mean in the context of this analysis?
-Isentropic refers to a process where the entropy of the system remains constant, meaning the process is both reversible and adiabatic. In this case, it implies that there is no heat transfer and that the system operates in an ideal, lossless manner.
What is the role of the specific volume (v) in the steady flow work formula for open systems?
-In the steady flow work formula, specific volume (v) is used to calculate the work done by the system as it changes pressure. The work is proportional to the specific volume and the change in pressure, which reflects the system's energy exchange through the shaft.
What does the integral form of the steady flow work formula represent?
-The integral form, W = -∫1^2 v dp, represents the work done by or on the system as the pressure changes from state 1 to state 2. The negative sign indicates the direction of work flow, depending on whether the system is producing or receiving work.
Why is it important to assume the process is isentropic for this analysis?
-Assuming the process is isentropic simplifies the analysis by allowing us to neglect heat transfer and frictional losses, providing an idealized framework where the work calculation only depends on changes in enthalpy and pressure.