1. MAE 5350: Gas Turbine Engines
Velocity Triangles Example
Mechanical and Aerospace Engineering Department
Florida Institute of Technology
D. R. Kirk

2. Example: Stator – Rotor Stageb c
Draw velocity triangles assuming that wr = 2 times the axial velocity w (w = constant)

3. QUESTIONS Is this a compressor or a turbine? How can you tell?
On which blade row(s) is there a torque applied? Why?
Describe in words the energy exchange process in each of the two blade rows

4. VELOCITY TRIANGLES AT bw
Start by drawing the axial velocity to some scale (10 units here)

5. VELOCITY TRIANGLES AT bVb w
bb=75º
Draw the absolute velocity vector

6. VELOCITY TRIANGLES AT bVb w
bb=75º
vqb
Draw vq in direction of rotation from the axis to absolute velocity vector

7. VELOCITY TRIANGLES AT bVb w
bb=75º wr
vqb
Add the rotational velocity (wr) and remember Vabs=Vrel+Vcs

8. VELOCITY TRIANGLES AT bVb w
bb=75º wr
vqb
Draw in the velocity to the rotor as seen from the rotating frame

9. VELOCITY TRIANGLES AT b
relative frame inlet
velocity to rotor
Stationary frame inlet
velocity to rotor Vb w
bb=75º wr
vqb

10. VELOCITY TRIANGLES AT cwr
Either start with the fixed axial velocity or fixed rotational speed

11. VELOCITY TRIANGLES AT c
bc’=55º w wr
Add the velocity from the rotor blades in the relative frame

12. VELOCITY TRIANGLES AT c
bc’=55º w wr
vqc
Add the velocity exiting the rotor in the absolute frame

13. VELOCITY TRIANGLES AT c
stationary frame exit
velocity of rotor
bc’=55º
relative frame exit
velocity of rotor w wr
vqc
Again, draw vq in the direction of rotation to the absolute velocity vector

14. bc’=55º w bb=75º w wr vqb vqc COMPOSITE TRIANGLE
Fixed or ‘metal’ blade angles
bc’=55º w
bb=75º w wr
vqb
vqc
To draw the composite velocity triangle, overlay the rotational velocity

15. QUESTIONS Is this a compressor or a turbine? How can you tell?
On which blade row(s) is there a torque applied? Why?
Describe in words the energy exchange process in each of the two blade rows

16. QUESTIONS Is this a compressor or a turbine?
This is a turbine. The stationary frame tangential velocity (vq) in the direction of rotor motion is reduced across the moving blade row
On which blade row(s) is there a torque applied? Why?
Torque is applied to both blade rows since there is a change in angular momentum across each of them. However, power is extracted only from the moving blades.
Describe in words the energy exchange process in each of the two blade rows
In the first blade row, fluid internal energy is converted to swirling kinetic energy by accelerating the flow through a nozzle. No additional energy is added or removed from the flow.
In the second blade row, swirling kinetic energy is extracted from the flow reducing the overall level of energy in the flow and transferring it to the spinning rotor blades.

17. Vb w bb=75º wr vqb ADDITIONAL QUESTION relative frame inlet
So far, we have looked at trailing edge angles of the blades (bb and bc’)
Why do we care about exit velocities from stator in the relative frame? Why do we even draw this on velocity triangles?
relative frame inlet
velocity to rotor
Stationary frame inlet
velocity to rotor Vb w
bb=75º
Why draw this? wr
vqb

18. ADDITIONAL QUESTION
Information about
how to shape
leading edge of
rotor blade
Doesn’t come into
ideal Euler equation
but obviously
important for
aerodynamic
Purposes
(rotor relative inflow
angle)