1. Urban Water Global water aspects
Department of Hydro Sciences, Institute for Urban Water Management
Urban Water
Global water aspects
Introduction to urban water management
Basics for systems description
Water transport
Matter transport
Introduction to water supply
Water extraction
Water purification
Water distribution
Introduction to wastewater disposal
Urban drainage
Wastewater treatment
Sludge treatment
Peter Krebs Dresden, 2010

2. 4.1 Introduction to transport phenomena 4.2 Transport processes
Peter Krebs
Department of Hydro Sciences, Institute for Urban Water Management
Urban Water
4 Matter transport
4.1 Introduction to transport phenomena
4.2 Transport processes
4.3 Reactor approach
4.4 Advection-dispersion approach

3. 4.1 Introduction to transport phenomena 4.2 Transport processes
Peter Krebs
Department of Hydro Sciences, Institute for Urban Water Management
Urban Water
4 Matter transport
4.1 Introduction to transport phenomena
4.2 Transport processes
4.3 Reactor approach
4.4 Advection-dispersion approach

4. Characteristics of compounds
Passive solubles
Travel ~ with water
Often used to indicate velocity and residence-time distribution
Solids
Transport decoupled from flow
Suspended solids and gravel
Sedimentation and Erosion
Reactive matter
Can be solubles or solids
Residence time and conditions in reactor important
Reaction must be known for balancing

5. Milk and sugar in a cup of coffee
Quiescent conditions
Molecular diffusion
Stirring
Turbulent diffusion

6. Tracer in a full pipe L, t Transport with flow
Longitudinal extension of tracer cloud
Decrease of peak concentration

7. Residence-time distribution in a clarifier

8. 4.1 Introduction to transport phenomena 4.2 Transport processes
Peter Krebs
Department of Hydro Sciences, Institute for Urban Water Management
Urban Water
4 Matter transport
4.1 Introduction to transport phenomena
4.2 Transport processes
4.3 Reactor approach
4.4 Advection-dispersion approach

9. Advection Transport with water flow  no relative movement Flux
Example: Transport of compound with constant concentration C in a tube with cross section A:

10. Molecular diffusion
Transport in the direction of decreasing concentration
 1st Fick law
1D approach; it also applies in a 2D or 3D system
Dmd,M is a specific value for a certain compound M
Dmd,M is a function of temperature

11. Turbulent diffusion
Process similar to molecular diffusion, but some orders of magnitude more efficient C x
Diffusive flux
Dtd is dependant on flow and state of turbulence, not on the compound itself
Concentration gradients decrease !!

12. Dispersion
Dispersion is not transport relative to water, but inhomogeneous advection
 In 1D formulation, dispersion “collapses on diffusion”

13. Sedimentation
Suspended particles have a transport component in gravity direction
In reactors this effect is used for particle separation
In transport systems, a sink or source term - depending on the operation conditions - is needed
Sedimentation flux v vS
Examples: - 1D clarifier model - Sewer sediments

14. 4.1 Introduction to transport phenomena 4.2 Transport processes
Peter Krebs
Department of Hydro Sciences, Institute for Urban Water Management
Urban Water
4 Matter transport
4.1 Introduction to transport phenomena
4.2 Transport processes
4.3 Reactor approach CSTR
Plug-flow reactor
CSTR in series
4.4 Advection-dispersion approach

15. Continuously stirred tank reactor (CSTR)
Constant volume
Immediate mixing
Complete mixing   no concentration gradients
CReactor = COutlet Q
Cin C V r
Mass balance

16. CSTR: steady state
Mass balance
0-order reaction
1st-order reaction

17. CSTR: residence-time distribution (RTD)
Tracer pulse is introduced to the inlet  tracer concentration is measured in the outlet
Mass balance
No input, no reaction

18. 4.1 Introduction to transport phenomena 4.2 Transport processes
Peter Krebs
Department of Hydro Sciences, Institute for Urban Water Management
Urban Water
4 Matter transport
4.1 Introduction to transport phenomena
4.2 Transport processes
4.3 Reactor approach CSTR
Plug-flow reactor
CSTR in series
4.4 Advection-dispersion approach

19. Plug-flow reactor Constant volume Constant cross section
No mixing (ev. lateral)
Concentration gradients along flow axes
Mass balance x dx A

20. Plug-flow reactor: steady state
Outlet concentrations: with x = L  L/v = 
Mass balance
0-order
1st order

21. Plug-flow reactor: RTD
Tracer pulse is introduced to the inlet  tracer pulse appears in the outlet unchanged !!

22. 4.1 Introduction to transport phenomena 4.2 Transport processes
Peter Krebs
Department of Hydro Sciences, Institute for Urban Water Management
Urban Water
4 Matter transport
4.1 Introduction to transport phenomena
4.2 Transport processes
4.3 Reactor approach CSTR
Plug-flow reactor
CSTR in series
4.4 Advection-dispersion approach

23. CSTR cascade Q C2 V2 r Q Ci Vi r Ci-1 Cn Vn Cn-1 Q Q r Cin C1 V1 C1
Reactor i
1st order reaction

24. CSTR cascade: 1st order reaction (i)
n = number of reactors
Total volume
2 Reactors
n Reactors

25. CSTR cascade: 1st order reaction (ii)
n Reactors

26. CSTR cascade: RTD (i)
Initial condition in 1st reactor c0,1 as reference concentration
1st reactor
2nd reactor
i-th reactor

27. CSTR cascade: RTD (ii)
Solving the coupled equations with Laplace transformation yields
Mean value
Variance
Peak value at time

28. CSTR cascade: RTD (iii)

29. 4.1 Introduction to transport phenomena 4.2 Transport processes
Peter Krebs
Department of Hydro Sciences, Institute for Urban Water Management
Urban Water
4 Matter transport
4.1 Introduction to transport phenomena
4.2 Transport processes
4.3 Reactor approach
4.4 Advection-dispersion approach

30. Advection-dispersion approach (i)
Analytical solution for a tracer pulse
u = mean velocity
Ddisp = dispersion coefficient
m = total amount of tracer introduced
A = cross-section area
t = time from dosage

31. Advection-dispersion approach (ii)
Standard deviation
Dispersion coefficient
Shear velocity
cf = Fischer coefficient = (-)
b = width of water surface
h = water depth
Sf = friction slope

32. A-D approach: effect of dispersion/diffusion
Advection
Dispersion, estimated by diffusion approach 
Standard deviation

33. A-D approach: tracer curves

34. 1 2 3 4 5 A-D approach: dispersion in a river tracer model50
100
150
200
250
300
350
400
450
Time (minutes)
tracer
model 1 2 3 4 5
Boeije (1999)

35. A-D approach: reactor approximation (i)
Normalisation by length L of reactor
Peclet number
Pe large  Advection dominant  plug flow behaviour
Pe small  Diffusion dominant  CSTR behaviour
small < Pe < large  CSTR cascade or A-D approach

36. A-D approach: reactor approximation (ii)
Relation of turbulence/dispersion and standard deviation
Simplification for Pe > 100 (applies to conditions in sewers and rivers)
CSTR approximation, „hydrologic model“
 Turbulence can be estimated from RTD (i.e. )