Consider the Hilsch-Ranque vortex tube discussed in Illustration 4.5-6. Starting with air at 4 bar and 25

Question:

Consider the Hilsch-Ranque vortex tube discussed in Illustration 4.5-6. Starting with air at 4 bar and 25^◦C, and exhaust pressure of 1.013 bar, and that half the air that enters the tube will be withdrawn at the higher temperature, what is the maximum temperature difference that can be obtained? Treat J mol. K air as an ideal gas with Cp = 29.3-

Illustration 4.5-6.

Showing That the Energy and Entropy Balances Can Be Used to Determine Whether a Process Is Possible

An engineer claims to have invented a steady-flow device that will take air at 4 bar and 20°C and separate it into two streams of equal mass, one at 1 bar and −20°C and the second at 1 bar and 60°C. Furthermore, the inventor states that his device operates adiabatically and does not require (or produce) work. Is such a device possible? [Air can be assumed to be an ideal gas with a constant heat capacity of C^∗_P = 29.3 J/(mol K)].

P = 4 bar T = 20C N Black box P = 1 bar T = -20C P = 1 bar T = 60C