Christopher Hill December 6, 2006 CE 679

1. Christopher HillDecember 6, 2006CE 679 Application of Ballast Flocculation for Sanitary Sewer Overflow Management North Dakota State University

2. Outline • Problem Overview • Introduction • Application • Design • Conclusion

3. Problem Overview • What are SSOs? • What is the cause of SSOs? • Why are SSOs a problem? • What is the frequency of SSOs? • How are SSOs managed?

4. Ballasted Flocculation • What is ballasted flocculation? • Why ballasted flocculation? • Actiflo®, DensaDeg®, Sirofloc®

5. Actiflo® System

6. Application – Satellite Basin • Located in the collection system • Does not meet EPA secondary treatment standards • Cost effective Interceptor Sewer Screen Sludge Actiflo® Actiflo WWTP Disinfection River

7. Application – WWTP Bypass Headworks • Located at WWTP • Mixing with the WWTP effluent to comply with permitting limits • Cost effective Secondary Treatment Actiflo® Disinfection River

8. Design – Flow Monitoring • Base on flow monitoring, develop model for sewer system. • Typically designed for 5 year return period storm • Design peak wet weather flow = 15 MGD

9. Design - Pretreatment • Design Flow • Ramp-up 150% Q • Ramp-down 50% Q • Hydraulically 200% Q • Pretreatment • Screening (3 – 6 mm) • 2 x 10 MGD Q = 10 MGD 2 x 5 MGD

10. Design – Coagulation Jar Test/Pilot Study • Coagulation • Chemical Coagulant • HRT 1 – 2 minutes • Rapid Mixing (G = 500-1500 s-1) Sizing Tank V = (HRT) x Q = 1 min x 3472.5 gal/min = 3472.5 gal or 464.2 ft3 Mixing Theoretical Power Requirement P = G2 m V = 12002(1.307x10-3 N*s/m2)13.2m3 = 24,844 W or 25 kW

11. Design – Flocculation Jar Test/Pilot Study • Flocculation • Polymer • Sand (2 – 4 g/L) • HRT 1 – 2 minutes • Rapid Mixing (G = 500-1500 s-1) Sizing Tank V = (HRT) x Q = 1 min x 3472.5 gal/min = 3472.5 gal or 464.2 ft3 Mixing Theoretical Power Requirement P = G2 m V = 12002(1.307x10-3 N*s/m2)13.2m3 = 24,844 W or 25 kW

12. Design – Maturation • Maturation • HRT 3 – 5 minutes • Slow Mixing (G = 160 – 200 s-1) Sizing Tank V = (HRT) x Q = 3 min x 3472.5 gal/min = 10,417 gal or 1,393 ft3 Mixing Theoretical Power Requirement P = G2 m V = 2002(1.307x10-3 N*s/m2)52.6m3 = 2,750 W or 2.8 kW

13. Design - Settler • Settler • Overflow Rate 20 to 80 gal/ft2*min • Typically 30 gal/ft2*min • Length: Width = 1:1 • Lamellar Tubes Tank Area A = Q / Vo = 3472.5 gal/min / 30 gal/ft2*min = 115.75 ft2 Tank Dimensions L = W = A1/2 = 115.751/2 = 10.75 ft Use 11 ft Design Criteria Between 45o and 60o Incline Nominal Spacing 2 in Incline Length 3 to 6 ft

14. Design – Actiflo® System • Assume Depth of 12 ft

15. Influent Q 1.2% of Q Recycled Sand Actiflo® Hydrocyclone 4.8% of Q Sludge Clarified Water 6% of Q Sludge Handling River WWTP Design - Microsand • 2 – 4 g/L of Microsand • Total Volume – Coagulation = 3,375 ft3 or 95,600 L • The system requires 191.2 - 382.4 kg (421.5 - 843 lb) • Sludge = 10 MGD x 0.048 = 480,000 gal/day

16. Actiflo® Design

17. Actiflo® Design

18. Conclusions • Evaluation of Alternatives • Design • Pilot Study • Disadvantages

19. Questions?