Applied Hydrology Infiltration

Slides:

Advertisements

Similar presentations

Hydrology Rainfall - Runoff Modeling (I)

Advertisements

Applied Hydrology Design Storm Hyetographs

Hyetograph Models Professor Ke-Sheng Cheng

Water Budget IV: Soil Water Processes P = Q + ET + G + ΔS.

Yhd Subsurface Hydrology

z = -50 cm, ψ = -100 cm, h = z + ψ = -50cm cm = -150 cm Which direction will water flow? 25 cm define z = 0 at soil surface h = z + ψ = cm.

Field Hydrologic Cycle Chapter 6. Radiant energy drives it and a lot of water is moved about annually.

Runoff Estimation, and Surface Erosion and Control Ali Fares, PhD NREM 600, Evaluation of Natural Resources Management.

Soil Conservation Service Runoff Equation

Forest Hydrology: Lect. 18

Runoff Processes Reading: Applied Hydrology Sections 5.6 to 5.8 and Chapter 6 for Tuesday of next week.

Hydrologic Abstractions

Infiltration Infiltration is the process by which water penetrates from ground surface into the soil. Infiltration rate is governed by: rainfall rate hydraulic.

Infiltration Introduction Green Ampt method Ponding time

Lecture ERS 482/682 (Fall 2002) Infiltration ERS 482/682 Small Watershed Hydrology.

HYDROLOGIC ABSTRACTIONS

WATER MOVING UNDERGROUND

Water in Soil. The basis of irrigation Soil Plant Evapotranspiration Plant requirements.

Groundwater Hydraulics Daene C. McKinney

Toby’s & Jake’s notes combined

Lecture 7 b Soil Water – Part 2

Environmental Requirements for Good Plant Growth

WATER CONSERVATION and WATER QUALITY. WATER CONSERVATION The HYDROLOGICAL CYCLE - Runs on solar energy The HYDROLOGICAL CYCLE - Runs on solar energy.

CE 394K.2 Hydrology Infiltration Reading AH Sec 5.1 to 5.5 Some of the subsequent slides were prepared by Venkatesh Merwade.

Lecture Notes Applied Hydrogeology

CE 394K.2 Hydrology Infiltration Reading AH Sec 5.1 to 5.5 Some slides were prepared by Venkatesh Merwade Slides 2-6 come from

Surface Water Hydrology: Infiltration – Green and Ampt Method

Subsurface Water unit volume of subsurface consists of soil/rock, and pores which may be filled with water and/or air total porosity= volume voids/total.

CE 394K.2 Hydrology Infiltration Reading for Today: AH Sec 4.3 and 4.4 Reading for Thurs: AH Sec 5.1 to 5.5 Subsequent slides prepared by Venkatesh Merwade.

Soil Water Processes:Chapter 3 Learn how soil properties influence runoff, infiltration and plant growth. Learn how soil properties influence runoff, infiltration.

AOM 4643 Principles and Issues in Environmental Hydrology.

Moisture-Holding Capacity of Soil

Infiltration Reading AH Sec 4.3 to 4.4.

Surface Water Surface runoff - Precipitation or snowmelt which moves across the land surface ultimately channelizing into streams or rivers or discharging.

Surface Water Applied Hydrology. Surface Water Source of Streamflow Streamflow Characteristics Travel Time and Stream Networks.

6. Drainage basins and runoff mechanisms Drainage basins Drainage basins The vegetation factor The vegetation factor Sources of runoff Sources of runoff.

Lecture 7 b Soil Water – Part 2 Source: Dept of Agriculture Bulletin 462, 1960.

Water Budget IV: Soil Water Processes P = Q + ET + G + ΔS.

Soil Water Balance Reading: Applied Hydrology Sections 4.3 and 4.4

Horticulture Science Lesson 27 Understanding Moisture Holding Capacity.

Infiltration Evapotranspiration and Soil Water Processes

Excess Rainfall and Direct Runoff

Irrigation Engineering CE-301

Infiltration : Objectives

Infiltration and unsaturated flow (Mays p )

Basic Hydrology & Hydraulics: DES 601

Infiltration and unsaturated flow

Groundwater Basics.

Infiltration and unsaturated flow

Infiltration and unsaturated flow (Mays p )

Example Estimate the average drawdown over an area where 25 million m3 of water has been pumped through a number of uniformly distributed wells.

Green and Ampt Infiltration

Digital Elevation Model based Hydrologic Modeling

Applied Hydrology Infiltration

Watersheds in Austin Area

Water Resources Engineering Hydrological Analysis and Simulation Model HEC-HMS Prof. Ke-Sheng Cheng Department of Bioenvironmental Systems Engineering.

Stochastic Hydrology Hydrological Frequency Analysis (I) Fundamentals of HFA Prof. Ke-Sheng Cheng Department of Bioenvironmental Systems Engineering.

Applied Hydrology Hydrological Analysis and Simulation Model HEC-HMS

SWAT – Land Phase of the Hydrologic Cycle

INFILTRATION The downward flow of water from the land surface into the soil medium is called infiltration. The rate of this movement is called the infiltration.

Groundwater Where does the water go?.

Presentation transcript:

Applied Hydrology Infiltration Prof. Ke-Sheng Cheng Department of Bioenvironmental Systems Engineering National Taiwan University

Water Distribution in the Soil (Unsaturated zone) 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

The capillary zone lies above the lower saturated layers. The soil water zone begins at the ground surface and extends downward, encompassing the root layers. During periods of rainfall (or other water application such as irrigation), this area may become saturated. It is otherwise in an unsaturated state, part of the soil pores are filled with air. The intermediate zone extends down to the capillary fringe. It is unsaturated except during periods of extreme precipitation. The capillary zone lies above the lower saturated layers. The saturated zone has all pores filled with water (surficial aquifer). 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Subsurface water appears as hydroscopic, capillary, or gravitational water. Hydroscopic and capillary water are held by molecular forces in thin films around soil particles. Hydroscopic water is essentially unavailable. Capillary water results when more water is available filling gaps between soil particles but in a discontinuous fashion. Capillary water can be in direct connection with groundwater or in isolated pockets. 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Soil moisture at some depth in the intermediate layer may not change with time. In humid or well-irrigated areas, field capacity (FC), the maximum amount of water the soil can hold against gravity, is a good moisture assumption for this layer. 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Definition of soil moisture content max =s (Saturated soil moisture content) 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Soil Moisture Profile 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Infiltration rate and infiltration capacity Infiltration rate: the actual rate of movement of water through soil surface (e.g. cm/hr, inch/hr) Infiltration capacity: the maximum rate of infiltration when there is an excess supply of water at the surface. Infiltration capacity is influenced by soil type and initial soil moisture content primarily. Factors affecting infiltration rate: SMC landcover soil type (hydraulic connectivity) 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Typical soil moisture distribution profile during the downward movement of water. 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Modeling the Infiltration Process Horton's model for infiltration capacity The Horton's equation assumes the soil surface is saturated at all time, i.e. excess water at surface. The value of fc is equivalent to the saturated hydraulic conductivity. The Horton’s infiltration model is used for modeling point-scale infiltration capacity. 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Horton’s infiltration model Actual infiltration rate vs infiltration capacity What is the real infiltration rate at time t1? 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Ponding time Case A. Excess water at surface (ponded infiltration) (fi*=infiltration capacity, fi=actual infiltration rate) Case B. Non-ponding infiltration until ponding at surface occurs. 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Assume a constant rainfall intensity i (fc < i < fo) 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

SCS Curve Number (CN) method The SCS CN method is proposed for infiltration rate estimation in watershed-scale. P=Pe+Ia+Fa 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

P: total rainfall depth of a storm Pe: total depth of direct runoff, or excess rainfall (inch) Fa: depth of water retained in the watershed after runoff begins (i.e. the amount of infiltration after runoff begins) (inch) Ia: initial abstraction before ponding (no runoff occurs) S: potential maximum retention after runoff begins (inch) 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Initial abstraction (Ia) is all losses before runoff begins Initial abstraction (Ia) is all losses before runoff begins. It includes water retained in surface depressions, water intercepted by vegetation, evaporation, and infiltration. Ia is highly variable but generally is correlated with soil and cover parameters. Through studies of many small agricultural watersheds, Ia was found to be approximated by the following empirical equation: Ia =0.2S 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

CN=100  S=0, Ia=0 CN<100  S>0, Ia>0 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

SCS CN method Initial abstraction 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU

Introduction of NRCS TR-55 model 12/6/2018 Lab for Remote Sensing Hydrology and Spatial Modeling, Dept. of Bioenvironmental Systems Eng., NTU