Drainage System Design and Layout. Design Process Flowchart Background Information (Soils, Topo, Crops) Confirm Outlet Drainage Needed Select DC, Spacing.

Slides:

Advertisements

Similar presentations

Drainage Management to Improve Water Quality and Enhanced Agricultural Production Don Pitts Agricultural Engineer NRCS USDA Champaign, IL by.

Advertisements

1 CTC 261 Hydraulics Storm Drainage Systems. 2 Objectives Know the factors associated with storm drainage systems.

EA204 Environmental Technology Pavement Drainage Stormwater Sewer Design.

CE 3372 Storm Sewer Conduit, Junctions, Inlets. Storm Sewers 0 Inlets capture stormwater 0 Junctions connect laterals to trunk lines. 0 Conduits (pipes)

Permeable Heavy Use Area for Livestock Farms Presentation for Kitsap County DCD, September 28 th, 2006, Lab Test Findings and Calculated Storm Water Performance.

Interpreting a contour map

Practice – CP-39 Farmable Wetland Program Constructed Wetland.

Detention / Infiltration Structure. Figure 21–1 Point Discharge and Downstream Stability Analysis Procedure.

Urban Storm Drain Design: Curb inlets, on grade & sag

Review of Flood Routing

CHARACTERISTICS OF RUNOFF

Soil Conservation Service Runoff Equation

CE 515 Railroad Engineering

OKLAHOMA STATE UNIVERSITY Biosystems and Agricultural Engineering Department Hydrology 101 OKLAHOMA STATE UNIVERSITY Biosystems and Agricultural Engineering.

Culvert Hydraulics using the Culvert Design Form

Design of Open Channels and Culverts CE453 Lecture 26

Design of Culverts. Culvert Design - Basics Top of culvert not used as pavement surface (unlike bridge), usually less than 7 m.

Trash Capture Device Installations

Design of Open Channels and Culverts

EXAM 2 REVIEW. 1. Drainage problem (25 pts) Below you see a cross-section of a ditch. It runs parallel to a 200-acre field consisting of permanent pasture.

1 Time of Concentration. 2 Objectives Know how to calculate time of concentration Know how to calculate time of concentration Know why it’s important.

CE 3372 Water Systems Design

SCOPE & EFFECT EQUATIONS Chapter 7

Understanding Soil Drainage Systems

The Objectives of storm water drainage To prevent erosion in hillside areas (paved roads and terracing are needed) To prevent land-slides To improve the.

Hydraulics Engineering

Surface Drainage CE 453 Lecture 25.

Part 2 Some Basic Aspects of CHANNEL HYDRAULICS. The volume of water that passes by any given point along a watercourse is called “Q”, for quantity of.

Design of Grass Swales Norman W. Garrick

 An adequate drainage system for the removal of surface and subsurface water is vital for the safety of aircraft and for the long service life of the.

Estimating Qmax Using the Rational Method

DIMITRI LAZARIDIS AND PHILIP APPLETON SUCCESSFUL GOLF COURSE DRAINAGE.

UNIFORM FLOW AND DESIGN OF CHANNELS

WinTR-20 Project Formulation Hydrology Computer Program Basic Input and Output Presented by: WinTR-20 Development Team.

WinTR-20 Project Formulation Hydrology Computer Program Basic Input and Output Presented by: WinTR-20 Development Team.

Overlap of multiple irrigations. 3-D Uniformity Simulation.

CTC 450 Review 1  WW Characteristics. Objectives 2  Understand the basics of storm drainage systems  Understand the basics of sewer systems.

WinTR-20 SensitivityMarch WinTR-20 Sensitivity to Input Parameters.

Pavement Analysis and Design

CTC 440 Review Determining peak flows Rational method Q=CIA

Subsurface drainage – Investigations

Definition: Soil and water conservation engineering is the application of engineering principles to the solution of soil and water management problems.

__________________________ SITES INTEGRATED DEVELOPMENT ENVIRONMENT for WATER RESOURCE SITE ANALYSIS COMPLEX WATERSHEDS SITES IN SERIES.

Surface hydrology The primary purpose of the WEPP surface hydrology component is to provide the erosion component with the duration of rainfall excess,

Drainage Management for Water Quality and Crop Production Benefits Don Pitts Agricultural Engineer NRCS USDA Champaign, IL.

ERT 349 SOIL AND WATER ENGINEERING

Basic Hydraulics: Channels Analysis and design – I

CE 3372 Water Systems Design Lecture 17: Storm sewers, inlets, conduits and related hydrology and hydraulics.

CE 3372 Water Systems Design Lecture 18: Storm sewers, inlets, conduits and related hydrology and hydraulics.

Basic Hydraulics: Open Channel Flow – I

Section 3: Stream Deposition

Transient Drainage Department of Agricultural and Biological Engineering University of Illinois at Urbana-Champaign.

Lesson Understanding Soil Drainage Systems. Interest Approach Ask students the question, “What determines how fast water will flow through a funnel?”

Subsurface Drainage (Tile) Design Thomas F. Scherer NDSU Extension Agricultural Engineer (701)

Sanitary Engineering Lecture 4

Sanitary Engineering Lecture 7

Definition: Soil and water conservation engineering is the application of engineering principles to the solution of soil and water management problems.

Norman W. Garrick Design of Grass Swales.

Drainage and Grading Creating stable ground surfaces

Designing Swales Norman W. Garrick CE 4410 Spring 2017 Lecture 15.

CE 3372 Water Systems Design

Site plan The plat map A plat map is the first step in development of a site plan. It delineates property lines with bearings, dimensions, streets, and.

Uniform Open Channel Flow

Drainage System Design and Layout

Time of Concentration.

Transient Drainage Department of Agricultural and Biological Engineering University of Illinois at Urbana-Champaign.

Culvert Hydraulics using the Culvert Design Form

Love Field Modernization Program

Humidity Absolute Humidity

Scour Analysis on the west fork of the Duchesne River

Presentation transcript:

Drainage System Design and Layout

Design Process Flowchart Background Information (Soils, Topo, Crops) Confirm Outlet Drainage Needed Select DC, Spacing & Depth Determine Grades & Depth Develop System Layout Determine Drain Sizes Installation NO

Design Process Flowchart Background Information (Soils, Topo, Crops) Confirm Outlet Drainage Needed Select DC, Spacing & Depth Determine Grades & Depth Develop System Layout Determine Drain Sizes Installation NO

Drainage Outlets

Outlet channels designed according to Curve B will provide excellent agricultural drainage in Illinois. Use this curve for drainage of truck crops, nursery crops, and other specialty crops. Designs based on curve B will provide the best drainage that can normally be justified in agricultural areas. Design Curves

Channels that are designed according to curve C will provide good agricultural drainage in Illinois. This curve is the one most often recommended for drainage of Illinois cropland Design Curves

Drainage Outlets Designs based on curve D provide satisfactory agricultural drainage as long as frequent overflow does not cause excessive damage. This curve is generally recommended for pasture or woodland. It may also be adequate for drainage of general cropland in northern Illinois, provided that the landowner carries out an excellent maintenance program. Designs based on curve D provide the minimum amount of drainage recommended in Illinois.

Drainage CFS/ Acre In/Day Curve 100 Acres (Drainage Coefficient) B C D For comparison: For a 100 acre watershed, RCN = 75, Avg. Slope = 1% in Central Illinois A 2 Yr., 24 Hr. Rainfall yields 1” of Runoff and would result in a Peak Flow of 30 CFS. A 10 Yr., 24 Hr. Rainfall yields 2” of Runoff and would result in a Peak Flow of 70 CFS. Design Curves

Ditch Configuration Once you know what the capacity of the outlet channel must be, you need to determine the size that will enable it to convey the desired amount of flow without letting the water surface rise above a predetermined elevation. The following sections describe some basic hydraulic concepts that will help you design a channel of the proper size.

Outlet Ditches Velocity The velocity of water flow must be high enough to prevent siltation in the channel but low enough to avoid erosion. Listed on the next page are the maximum velocities for drainage areas of 640 acres or less. The velocity should be no lower than 1.5 feet per second. A lower velocity will cause siltation, which encourages moss and weed growth and reduces the cross section of the channel.

Hydraulic Gradeline

Channel Velocity The most widely used equation for designing outlet channels was developed by Robert Manning in 1890 and is known as Manning's equation: where V = average velocity of flow (ft/sec), n = coefficient of roughness, R = hydraulic radius (ft), s = slope of hydraulic gradient (ft/ft).

Manning Routine

Design Process Flowchart Background Information (Soils, Topo, Crops) Confirm Outlet Drainage Needed Determine Grades & Depth Develop System Layout Determine Drain Sizes Installation NO Select DC, Spacing & Depth

Drainage Coefficient

Impermeable or Restricted-Flow Layer h  d S K K

Design for uniform depth throughout system (depends on layout) Depth will of course vary on flat and rolling topography Drain Spacing & Depth

Depth-Spacing Relationships

Drain Layout Comparison

Drainage Costs

 100 Tile Density Profitability Cost/AcreCrop YieldRate of Return Cost or Yield Ratio (%)‏ Spacing

Design Process Flowchart Background Information (Soils, Topo, Crops) Confirm Outlet Drainage Needed Select DC, Spacing & Depth Determine Grades & Depth Determine Drain Sizes Installation NO Develop System Layout

System Layout

ContourMap

Cost Differential: $50/acre

Design Process Flowchart Background Information (Soils, Topo, Crops) Confirm Outlet Drainage Needed Select DC, Spacing & Depth Develop System Layout Determine Drain Sizes Installation NO Determine Grades & Depth

Drain Sizing Tool

Result Display

Materials

Drainage Materials

Drainage Coeff.

Drainage Coefficient

Design Criteria

10 = 3 x 6 Tile Mathematics 12/2 = 8

Sedimentation Options

Design Chart

Can be Saved

Lateral Specification

Inlets

Questions?