Gas Dynamics ESA 341 Chapter 3

1. Gas DynamicsESA 341Chapter 3 Dr Kamarul Arifin B. Ahmad PPK Aeroangkasa

2. Normal shock waves • Definition of shock wave • Formation of normal shock wave • Governing equations • Shock in the nozzle

3. Shock wave V P T Definition of shock wave Shock wave is a very thin region in a flow where a supersonic flow is decelerated to subsonic flow. The process is adiabatic but non-isentropic.

4. Formation of Shock Wave A piston in a tube is given a small constant velocity increment to the right magnitude dV, a sound wave travel ahead of the piston. A second increment of velocity dV causing a second wave to move into the compressed gas behind the first wave. As the second wave move into a gas that is already moving (into a compressed gas having a slightly elevated temperature), the second waves travels with a greater velocity. The wave next to the piston tend to overtake those father down the tube. As time passes, the compression wave steepens.

5. b Types of Shock Waves: Normal shock wave - easiest to analyze Oblique shock wave - will be analyzed based on normal shock relations Curved shock wave - difficult & will not be analyzed in this class • The flow across a shock wave is adiabatic but • not isentropic (because it is irreversible). So:

6. Governing Equations Conservation of mass: Conservation of momentum: Rearranging: Combining: Conservation of energy: Change of variable: combine

7. Governing Equationscont. Continued: Multiplied by r2/p1: Rearranging: or

8. Governing Equationscont. From conservation of mass: From equation of state:

9. Governing Equations cont. Conservation of mass C O M BINE Conservation of momentum Conservation of energy Expanding the equations

10. Governing Equationscont. Solution: Mach number cannot be negative. So, only the positive value is realistic.

11. Governing Equations cont. Temp. ratio Dens. ratio 1 Pres. ratio Simplifying: 3 2

12. Governing Equations cont. Stagnation pressures: Other relations:

13. Shock wave 1 2 Governing Equations cont. Entropy change: But, S02=S2 and S01=S1 because the flow is all isentropic before and after shockwave. So, when applied to stagnation points: But, flow across the shock wave is adiabatic & non-isentropic: And the stagnation entropy is equal to the static entropy: So:  Total pressure decreases across shock wave !

14. Group Exercises 3 • Consider a normal shock wave in air where the upstream flow properties are u1=680m/s, T1=288K, and p1=1 atm. Calculate the velocity, temperature, and pressure downstream of the shock. • A stream of air travelling at 500 m/s with a static pressure of 75 kPa and a static temperature of 150C undergoes a normal shock wave. Determine the static temperature, pressure and the stagnation pressure, temperature and the air velocity after the shock wave. • Air has a temperature and pressure of 3000K and 2 bars absolute respectively. It is flowing with a velocity of 868m/s and enters a normal shock. Determine the density before and after the shock.

15. Stationary Normal Shock Wave Table – Appendix C: