2. Similarity Laws for Turbo-machinery P M V Subbarao Professor Mechanical Engineering Department From Inception to Utilization….

3. Buckingham, E. The principle of similitude. Nature 96, 396-397 (1915).

4. The purpose of Dimensional Analysis Want to determine which variables to study. Want to determine the parameters that significantly affect the system. Reduce the cost/effort of experimental analysis by studying the most important groups of variables. The ideas can be used for any physical system. This will help in the design of scale test models

5. Similitude & Dimensional Analysis Scale model to prototype design and analysis. Used to select proper turbo-machine (axial, radial or mixed flow,…) Used to define performance parameters

6. Similarity Laws GEOMETRIC –Linear dimension ratios are the same everywhere. –Photographic enlargement KINEMATIC ( ϕ m = ϕ p ) –Same flow coefficients –Same fluid velocity ratios (triangles) are the same DYNAMIC (ψ m = ψ p ) –Same loading coefficient –Same force ratios (and force triangles) Energetic (  m =  p ) –Same power coefficient –Same energy ratios.

7. Euler’s GENERIC TURBOMACHINE (turbine, compressor, pump, ….) List the n physical quantities (Q n ) with dimensions and the k fundamental dimensions. There will be (n-k) π-terms. Select k of these quantities, none dimensionless and no two having the same dimensions. All fundamental dimensions must be included collectively in the quantities selected.

8. Fundamental Quantities for Turbo-machines

9. The First Non-dimensional Parameter Flow Coefficient or Capacity Coefficient (  ) “the dimensionless ‘swallowing’ capacity of the machine”

10. Flow Velocity Vs Blade Speed Volumetric flow rate (Q) can be related to the fluid velocity : A particular value of  implies a specific relationship between fluid velocity and blade/impeller speed.

11. Efficiency (η) vs Flow coefficient ( ϕ )

12. Design Innovations for Better Performance

13. Strategies to Capture More Power from Wind

14. Pitch-Controlled Variable-Speed Wind Turbine Generation

15. Grid Acceptable Power

16. The second Non-dimensional Parameter  p corresponds to the energy per unit volume of the fluid.  N 2 D 2 relates to the rotor or impeller dynamic pressure (K.E. per unit volume). Loading Coefficient

17. Load Coefficient or Head Coefficient For compressible fluid machines : For incompressible fluid machines :

18. Selection of Load Coefficient for an Axial Flow Compressor

19. Accepted Technology for Hydro Power generation

20. Universal Design Chart for Power Consuming Turbo-machines

21. The Third non-dimensional Parameter

22. Role of Power Coefficient : Wind Turbines

23. Size Vs Capacity of A Wind TUrbine

25. Design Upgradation

27. Similarity of Model & Prototype

28. Design for Best Efficiency for Pumps & Fans

29. Dimensions for Performance