Shaft Work in Thermodynamic Systems

Shaft Work in Thermodynamic Systems
In thermodynamics, shaft work refers to the mechanical energy transferred by a rotating shaft, such as
in turbines, compressors, or pumps. It’s a critical concept in analyzing energy systems, especially in
power plants, engines, and refrigeration cycles. Let’s break it down step by step, with examples and
insights to make it engaging and clear.



What is Shaft Work?

Shaft work is the energy transferred due to the rotation of a shaft. It’s often represented as Wₛ in
equations. Think of it as the work done by a turbine to generate electricity or the work required by a
compressor to increase the pressure of a gas.



For example, in a steam turbine, high-pressure steam flows through the turbine blades, causing the
shaft to rotate. This rotation generates electricity. Here, the shaft work is the energy extracted from the
steam and converted into electrical energy.



The Math Behind Shaft Work

The shaft work can be calculated using the First Law of Thermodynamics for open systems (control
volumes). The equation is:



[ \dot{W}s = \dot{m} \cdot (h{in} - h_{out})

]



Where:



(\dot{W}_s) = shaft work rate (kW or hp)

(\dot{m}) = mass flow rate (kg/s or lb/s)

(h_{in}) and (h_{out}) = specific enthalpies at the inlet and outlet (kJ/kg or Btu/lb)

Example Calculation:

Imagine a turbine where steam enters at 500°C and exits at 200°C. The mass flow rate is 10 kg/s, and the
enthalpy values are:



(h_{in} = 3500 , \text{kJ/kg})