Particle Control Technologies

1. Particle Control Technologies Lecture notes adapted from Prof. Dr. Benoit Cushman-Roisin Thayer School of Engineering at Dartmouth

2. Design Criteria • Partikül Giderim Yöntemlerinde bir gaz medyum için yer alan katı veya sıvı partiküllerin giderimine yönelik sistem tasarlanması söz konusudur. Partikül maddeye ve onu taşıyan gaz medyumuna ait tasarımda göz önünde bulundurulması gereken karekteristikler: • Boyut T,P,Q, • Kimyasal içerik Kimyasal İçerik • Direnç Basınç kaybı Partikül Kontrol Ünitesi

3. Collection Efficiency • Considering the wide range of size of particulates, efficiency will be different for each size. • The overall efficiency (h) can be calculated on a basis of total number (or mass) of particles • Generally regulations are written based on mass, and efficiencies are calculated on mass basis.

4. Collection Efficiency • Efficiencies calculated on mass basis: h: overall collection efficiency (fraction) Mi: total mass input rate (g/s or equivalent) Me: total mass emission rate (g/s or equivalent) Li: particulate loading in the inlet gas to the device (g/m3) Le:particulate loading in the exit gas stream, (g/m3)

5. Collection Efficiency • When the particulate size distribution is known, and the efficiency of the device is known as a function of particle size, the overall collection efficiency can be calculate: where hj: collection efficiency for the jth size mj: mass percent of particles in the jth size

6. Example • Example 3.1 from the book

7. Gravity Settler • Cyclones • ESP • Filters and Baghouses • Wet Scrubbers

8. Settling Chamber • Efficient for particles with diameter of 10-50 mm (depending on its density) • Velocity through chamber < 0.3-3 m/s (to prevent reentrainment) V H L

9. v H L Settling Chamber • Settling time < transit time through chamber • t = H/vt = L/v  Settling chambers are cheap to build and operate but not preferred due to their large space requirement

10. Settling Chamber • Assuming unit density sphere at STP, vt and chamber Lw are tabulated below: Assumed flow rate Q = 150 m3/min

11. Settling Chamber • Baffled Settling Chamber • Large particles can not make sudden direction change and settle into dead space of chamber • Baffle chambers are used as precleaners

12. Cyclones • :

13. Cyclones • :

14. Cyclone Geometry

15. Cyclone Geometry

16. Cyclone Theory

17. Cyclone Theory

18. Cyclone Theory

19. Cyclone Theory

20. Collection Efficiency

21. Collection Efficiency (i) increase Vt (expensive, since DPa Vt2, as we will see in the next slides

22. Collection Efficiency

23. Collection Efficiency

24. Pressure Drop K: a constant depends on cyclone configuration and operating conditions. Theoretically K can vary considerably but for air pollution work with standard tangential-entry cyclones values of K are in the range of 12 to 18 Cyclone pressure drops range from about 0.5 to 10 velocity heads (250 to 4000 Pa)

25. Cyclone Analysis

26. Example

27. Example

28. Example 4.5

29. Example 4.5

30. Example 4.5

31. ESP

32. ESP

34. ESP Geometry

35. ESP Theory

36. Corona Power vrs Efficiency

37. ESP Theory

38. ESP THEORY

39. ESP Theory

40. ESP Theory

41. ESP Theory

42. ESP Theory

43. ESP Theory

44. ESP Theory

45. ESP Theory

46. ESP Theory

47. ESP Theory

48. Efficiency

49. Efficiency

50. Effect of Resistivity