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Factors Contributing to Mudflows. Watershed ConditionsDrainage and channel developmentSediment availability (channel storage, hillslope failure)Exposed slopes (fires, logging, vegetation)Debris (logs, boulders, trash)Channel roughness and constrictions Volcanic eruptions. Hyperconcentrated Sediment Flows
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1. Sediment Loading, Hyperconcentrated Sediment Flows, Mud and Debris Flows Jim O'Brien
FLO-2D Software, Inc.
2. Factors Contributing to Mudflows Watershed Conditions
Drainage and channel development
Sediment availability (channel storage, hillslope failure)
Exposed slopes (fires, logging, vegetation)
Debris (logs, boulders, trash)
Channel roughness and constrictions
Volcanic eruptions
3. Hyperconcentrated Sediment Flows not an exact science!Using volume conservation model (FLO-2D), not a Lagrangian particle dynamic model.
4. Evaluating Mud and Debris Potential Objective: Investigate sediment supply and balance sediment volume and water hydrograph volume
Mudflow Potential:
Nature of sediment transport (flood or mudflow) - channel and fan deposits (natural boulder levees, lobate deposits)
Loose debris and boulders in channel
Estimate available sediment volume (channel storage, bank failure, landslide, overland sediment yield)
Compute a sediment volume and average sediment concentration for the design flood event. For mudflows: average 30% to 35% concentration by volume
5. Five Primary Sources of Sediment Landslides
Hillslope sloughing or failure
Channel bank failure
Channel bed scour
Overland sediment yield
Objective: To balance sediment supply with the sediment volume computed in the output files
6. Hyperconcentrated Sediment Flows - Basics Concentration by volume:
Cv = Volume of Sediment
Vol. of Sed. + Vol. of Water
7. Hyperconcentrated Sediment Flows - Basics Specific Weight of the Mixture:
?m = ? + Cv (?s - ?)
8. Hyperconcentrated Sediment Flows - Basics Bulking Factor: BF = 1/(1-Cv)
9. Question: What is the sediment concentration by volume?
17. Evaluating Mud and Debris Potential In small watersheds (< 5 mi2), infrequent floods ~100 yr event generally do not create viscous mudflows.
Why?
18. Evaluating Mud and Debris Potential
In small watersheds (< 5 mi2), infrequent floods ~100 yr event generally do not create viscous mudflows. Why?
Theres too much water for the available sediment supply. Surging occurs with debris frontal waves.
19. Hyperconcentrated Sediment Flows
? = ?y + ? (?v/?y) + C (?v/?y)2
21. Select mudflow parameters Select viscosity and yield stress parameters to match the field conditions (e.g. high viscosity and low yield stress).
24. Viscosity = f (Cv)
26. Yield Stress = f (Cv)
27. To perform a mudflow analysis Switch on MUD = 1 in CONT.DAT
Add sediment concentration to inflow fileINFLOW.DAT
Add line 1 in SED.DAT, coefficients and exponents for viscosity and yields in Table 9
M 0.000602 33.1 .00172 29.5 2.74 0.0
Turn off ISED and XCONC in CONT.DAT
Flow is treated as a fluid continuum
Simulate flow cessation and remobilization
28. Construct a Sediment Concentration Hydrograph Average sediment concentration range 30-35% by volume
Bulk the frontal wave 45-53%
Hydrograph peak discharge ~ 40-45%
Result:
Maximize peak discharge moving over the fan
Slow the flow down for higher depths
Fluid motion to inundation a large area
Peak discharge catches the frontal wave
29. Select mudflow parameters Select viscosity and yield stress parameters to match the field conditions (e.g. high viscosity and low yield stress)
Compute the viscosity and yield stress for one sediment concentration by volume
Try several different sets of data for a one inflow hydrograph and sediment concentration
30. Typical Fan Apex Mudflow Hydrograph
31. Mudflow hydrograph at fan terminus
32. Whats Missing? Surging in the recessional limb
Effects of channel blockage both in the watershed and at bridges and culverts
Roll wave phenomena
34. Dispersive Stress The different fluid shear stresses with high sediment concentrations are:
Cohesion between fine particles
Viscous interaction between particles and surrounding fluid
Inertial impact between sediment particles dispersive stress
Turbulence
35. Dispersive Shear Stress For dispersive stress to occur, satisfy 3 conditions:
High sediment concentration Cv > 0.5
Large velocity gradients ~ > 0.1 s-1
Large sediment particles Ds > 0.05 h
36. Hyperconcentrated Sediment Flows
? = ?y + ? (?v/?y) + C (?v/?y)2
37. Dimensionless Form - Quadratic Model
38. Dispersive vs Turbulent Stress
Hyperconcentrated flows are:
Primarily Turbulent if Td > 1
h/ds > 70 dispersive stress is small
Primarily Dispersive if Td < 1
h/ds< 70 high resistance with particle collisions
39. Classification Dv Td
Mud floods > 400 > 1
Mudflows < 30
Granular Flows > 400 < 1
Mud floods turbulent stress is dominant
Mudflows viscous stress is dominant
Granular flows dispersive is dominant
(see handout)
40. Task: Relate the turbulent and dispersive stress in practical terms Define a relationship that would permit the C coefficient in the shear stess to be evaluated
Resistance to flow as defined by Mannings n value
41. Dispersive Stress Velocity Profiles
42. Flow resistance in turbulent flows with low sediment concentrations
43. Plot data with high concentrations of non-cohesive particles with previous curves
44. Combine all the data highlight dispersive stress data
45. Dispersive Stress Flow Resistance
46. Dispersive Stress Flow Resistance
47. Plotting nd/nt = f (Cv) ntd = nt b e mCv
where b = 0.054 and m = 6.09
At high concentrations, dispersive stress transfers more momentum flow to the boundary by particle contact ~ flow resistance
Hardwired in the model
48. The end