HEC-RASAN INTRODUCTION

Patrick Ndolo Goy & Dr. Pierre Y. Julien

PRESENTATION

US Army Corps of Engineers (USACE)

Hydrologic Engineering Center

River Analysis System

http://www.hec.usace.army.mil/software/hec-ras/

OVERVIEW OF CAPABILITIES

Four one-dimensional river analysis components:

o Steady flow water surface profile computations o Unsteady flow simulationo Movable boundary sediment transport computationso Water quality analysis+o Several hydraulic design features

Computational Procedure - basic equations One-dimensional Energy Equation

Continuity EquationZ: elevation of the bottom

of the channelY: elevation of the water

surfaceV: flow velocity: coefficientg: gravityhe: head lossesA: area of cross section

Computational Procedure - basic equations

Equation of Resistance to flow Manning Equation

Q: flown: Manning’s coefficientA: area of cross sectionRH: hydraulic radiusSf: friction slopeP: Wetted perimeterK: Conveyance

/ / / /

Computational Procedure - basic equations

energy losses friction - Manning Equation contraction/expansion - loss coefficient

L: Reach length

Sf: Friction slope

V: flow velocity

: coefficient

g: gravity

he: head losses

A: area of cross section

C: Contraction/expansion coefficient

Computational Procedure - basic equations

Direct Step Method

Y: elevation of the water surface

V: flow velocity: coefficientg: gravitySf: friction slopeS0: bottom slope

∆

Main Assumptions for 1-D Steady Flow Computations Constant velocity and horizontal water surface across a channel section All flow are gradually varied with hydrostatic pressure prevailing Channel boundaries are fixed

Computational Procedure

Water surface at a given cross section computed by iteratively solving 1-D energy equation and he = hL + h0

Step 1: Assume initial value for WS elevation Assume a water surface elevation at the upstream cross section if a

supercritical profile is being calculated Assume a water surface elevation at the downstream cross section if a

subcritical profile is being calculated Step 2: Determine the corresponding total conveyance and velocity

head Step 3: Compute S and solve for he

Step 4: Solve 1-D energy equation for WS elevation Step 5: Compare WS elevation from Step 1 and 4. Iterate until values

within 0.01 feet or user-defined tolerance.

Basic data requirements –Steady Flow Simulation

Geometric Data River system Schematic Cross Section Geometry Levees, Obstructions Reach Lengths

Energy Loss coefficients Manning’s n Contraction and Expansion Coefficients

Steady Flow Data Flow Regime Boundary Conditions Discharge information

Organizational Structure

Run File (Simulation)

Output File (Results from Simulation)

Example - Application

Starting a New Project

Example - Application Entering Geometric Data

Drawing the Schematic of the River System

Tributary

0.2

0.1

0.0

Upper Reach

10

9.9

9.8

Lower Reach9.7

9.6

9.5

Sutter

River StationsRiver StationsNumeric labels increase upstream

Example - Application Drawing the Schematic of the River System

Example - Application

Cross Section Data

Example - Application

Cross Section Data

- Cross section coordinates

- Downstream Reach Lengths

- Manning’s n Values

- Main channel Bank stations

-Contraction/Expansion Coefficients

- Click on Apply Data to save data

Example - Application

Cross Section Data (Visualization) Visually inspect the section

Example - Application Entering Junction Data

Junction

- Select the computation Mode (Energy equation or Momentum Equation)

Saving the Geometry Data (File Menu of the Geometric Data window)

Example - Application Entering Steady Flow Data

Tributary

0.2

0.1

0.0

Upper Reach

10

9.9

9.8

Lower Reach9.7

9.6

9.5

Sutter

River StationsRiver StationsNumeric labels increase upstream

Example - Application Entering Steady Flow Data

Tributary

0.2

0.1

0.0

Upper Reach

10

9.9

9.8

Lower Reach9.7

9.6

9.5

Sutter

River StationsRiver StationsNumeric labels increase upstream

- Enter the number of profiles (3 profiles in this example: 10-year, 50-year and 100-year flow discharge obtained from a frequency analysis of recorded flow data from gage stations)

- Enter the flow data from upstream to downstream for each reach

- It is assumed that flow doesn’t change between X-sections (flow remains constant until another flow value is encountered within the reach)

Example - Application

Entering Boundary Conditions Necessary to establish the starting water surface at the ends of the river system

Subcritical flow regime boundary conditions only required at the downstream ends of the river system (downstream control)

Supercritical flow regime boundary conditions only required at the upstream ends of the river system (upstream control)

Mixed flow regime boundary conditions required at all open ends of the river system

Example - Application Entering Boundary Conditions

In this example, it is assumed that the flow is subcritical throughout the river system

Only boundary condition are enteredTributary

0.2

0.1

0.0

Upper Reach

10

9.9

9.8

Lower Reach9.7

9.6

9.5

Sutter

River StationsRiver StationsNumeric labels increase upstream

- “Normal Depth” button is used to define the boundary condition for the downstream end of Fall River, Lower reach (Value of 0.0004 ft/ft is entered as average energy slope)

Example - Application Performing the Hydraulic Calculations

- A plan is unique combination of:

- Geometry File (reach network, X-Sections and Junctions), and

- Steady Flow File (flows and boundary conditions)

Example - Application Viewing Graphical and Tabular Results

Cross sections

- Water surface profile (Hydraulic Grade Line) in blue

- Energy Grade Line in green

Example - Application Viewing Graphical and Tabular Results

Water Surface Profiles (“Profile Plot” button)

Example - Application Viewing Graphical and Tabular Results

Rating curve (Water Surface Elevation vs Discharge curve) at a given section

Example - Application Viewing Graphical and Tabular Results

X-Y-Z Perspective Plots

Example - Application Viewing Graphical and Tabular Results

Tabular Results

Cross Section Output

Energy grade line elevation (ft)

Velocity head (ft)

Water surface elevation (ft)

Critical Water surface elevation (ft)

Slope of the energy grade line (ft/ft)

Total discharge (cfs)

Top width (ft)

Total velocity (ft/s)

Maximum channel depth (ft)

Total conveyance (cfs)

….

Example - Application Viewing Graphical and Tabular Results

Tabular Results

Profile Output Table

Energy grade line elevation (ft)

Velocity head (ft)

Water surface elevation (ft)

Critical Water surface elevation (ft)

Slope of the energy grade line (ft/ft)

Total discharge (cfs)

Top width (ft)

Total velocity (ft/s)

Maximum channel depth (ft)

Total conveyance (cfs)

Flow area

Other Applications Bridge/culvert Modeling

Other Applications Bridge/culvert Modeling

Other Applications Inline Structures (Dams, Weirs and Gated Spillways)

Breached dam Gated Spillways

Other Applications Lateral Structures(Weirs, Gated Spillways, Culverts, and Diversion Rating Curves)

Other ApplicationsFlood management and flood insurance studies to evaluate floodway encroachments

THANK YOU!QUESTION?