Microirrigation for Crop Production

I. MICROIRRIGATION THEORY AND DESIGN PRINCIPLES
CHAPTER 1. INTRODUCTION

1.1. DEFINITION

1.2. HISTORY AND CURRENT STATUS

1.2.1. Early History Worldwide

1.2.2. Early History in United States

1.2.3. Current Irrigated Area

1.2.4. Principal Crops Utilizing Microirrigation

1.2.5. Trends

1.2.6. Economics

1.2.7. Expansion in Developing Countries

1.3. GENERAL PRINCIPLES

1.3.1. Advantages

1.3.1.1. Increased water use efficiency

1.3.1.1.1. Improved crop yields and quality

1.3.1.1.2. Reduced nonbeneficial use

1.3.1.1.3. Reduced deep percolation

1.3.1.2. Use of saline water

1.3.1.3. Improved fertilizer and other chemical application

1.3.1.4. Decreased energy requirements

1.3.1.5. Improved cultural practices

1.3.1.6. Use of biological effluent and treated wastewaters

1.3.2. Disadvantages

1.3.2.1. Extensive maintenance requirements

1.3.2.2. Salt accumulation near plants

1.3.2.3. Restricted root development

1.3.2.4. High system costs

1.3.2.5. Restricted crop rotation

1.3.3. System Considerations

1.3.3.1. Design and installation considerations

1.3.3.2. Maintenance considerations

1.3.3.3. Management considerations

1.3.3.4. Economic considerations

1.3.3.4.1. System costs

1.4. SYSTEM COMPONENTS

1.4.1. Emission Devices

1.4.2. Distribution System

1.4.3. Control and Automation

1.4.4. Filtration

1.5. SYSTEM TYPES

1.5.1. Surface Drip Irrigation

1.5.2. Subsurface Drip Irrigation

1.5.3. Bubbler Irrigation

1.5.4. Microsprinkler Irrigation
REFERENCES
CHAPTER 2. SOIL WATER CONCEPTS

2.1. INTRODUCTION

2.1.1. Soil Water Regime for High Frequency Irrigation

2.2. SOIL WATER

2.2.1. Soil Water Content

2.2.2. Soil Water Potential

2.2.3. Soil Water Characteristic Curves

2.2.4. Soil Water Measurements

2.2.4.1. Gravimetric determination of soil water content

2.2.4.2. Neutron scattering

2.2.4.3. Time domain reflectometry (TDR)

2.2.4.4. Tensiometers

2.2.4.5. Heat dissipation

2.2.4.6. Electrical resistance

2.2.4.7. Capacitance

2.3. SOIL WATER MOVEMENT

2.3.1. Darcy’s Law

2.3.1.1. Alternative forms for Darcy’s Law

2.3.2. Richards’ Equation

2.3.3. Measurements of Soil Hydraulic Parameters

2.3.3.1. Direct measurements

2.3.3.2. Indirect measurements

2.3.3.3. Inverse methods

2.3.4. Shortcuts with Pedotransfer Functions

2.4. MODELING FOR EFFECTIVE MANAGEMENT AND DESIGN

2.4.1. Simplified Hemispherical Model

2.4.2. Quasi-Linear Solutions to Richards’ Equation

2.4.2.1. Steady state solutions for point sources

2.4.2.2. Steady state solutions for surface ponding

2.4.2.3. Steady state solutions for line sources

2.4.2.4. Transient (time-dependent) solutions

2.4.3. Root Water Uptake

2.4.3.1. Transient two and three-dimensional uptake functions

2.4.4. Influence of Soil Spatial Variability on Soil Water Distribution
ACKNOWLEDGMENTS
LIST OF TERMS AND SYMBOLS
REFERENCES
CHAPTER 3. IRRIGATION SCHEDULING

3.1. INTRODUCTION

3.1.1. System Capacity

3.1.2. System Uniformity Effects on Scheduling

3.1.3. System Maintenance Effects on Scheduling

3.1.4. Scheduling Constraints

3.2. IRRIGATION SCHEDULING TECHNIQUES

3.2.1 Water Balance (Evapotranspiration Base)

3.2.1.1. Climatic factors affecting crop water use

3.2.1.2. Crop factors affecting ET

3.2.1.3. Soil factors affecting ET

3.2.1.4. A direct ET approach

3.2.1.5. Evaporation pans and atmometers

3.2.1.6. Scheduling principles using evapotranspiration

3.2.2. Soil Water Control

3.2.2.1. Soil water measurement and controls

3.2.2.2. Placement and implementation

3.2.3. Plant Water Deficit Indicators

3.2.3.1. Irrigation scheduling feedback loop using plant stress indicators

3.2.3.2. Plant water potential measurements

3.2.3.3. Plant size changes from plant-water stress

3.2.3.4. Plant stress based on plant temperature

3.2.3.5. Transpiration measurements by sap flow

3.3. SUMMARY
LIST OF TERMS AND SYMBOLS
REFERENCES
CHAPTER 4. SALINITY

4.1. INTRODUCTION

4.2. QUANTIFYING SALINITY AND SODICITY

4.2.1. Salinity

4.2.2. Sodicity

4.3. CROP TOLERANCE

4.3.1. Crop Salt Tolerance

4.3.2. Factors Modifying Salt Tolerance

4.3.3. Tolerance to Specific Solutes

4.4. LEACHING

4.4.1. Leaching Requirement

4.4.2. Impact of Rainfall

4.5. INFLUENCES OF IRRIGATION SYSTEM AND WATER SOURCE ON
SOIL SALINITY

4.5.1. Influence of Irrigation Method

4.5.2. Reuse and Conjunctive Use of Waters

4.5.2.1. Reuse

4.5.2.2. Blending

4.5.2.3. Cycling

4.5.3. Environmental Consequences

4.6. SALINITY MANAGEMENT PRACTICES

4.6.1. Soil Salinity Distribution

4.6.2. Crop Considerations

4.6.2.1. Crop selection

4.6.2.2. Other management techniques

4.6.3. Infiltration

4.6.4. Reclamation of Salt-Affected Soils

4.6.4.1. Saline soils

4.6.4.2. Sodic soils

4.6.4.3. Boron leaching

4.7. SUMMARY AND CONCLUSIONS
REFERENCES
CHAPTER 5. GENERAL SYSTEM DESIGN PRINCIPLES

5.1. OVERVIEW OF THE DESIGN PROCESS

5.1.1. Initial Assessment

5.1.2. Microirrigation Layout and Components

5.1.3. The Design Process

5.2. SOURCES OF WATER

5.2.1. Water Quantity and Quality

5.2.2. Groundwater

5.2.3. Surface Water

5.3. SYSTEM HYDRAULICS

5.3.1. Hydraulic Principles

5.3.1.1. Total head

5.3.1.2. Pump energy requirements

5.3.1.3. Total friction head

5.3.1.3.1. Pipeline friction head loss

5.3.1.3.2. Multiple outlet pipes

5.3.1.3.3. Fitting, valve and component losses

5.3.1.3.4. Emitter connection losses

5.3.2. Emitter Hydraulics

5.3.3. Microirrigation Lateral Lines

5.3.3.1. Lateral line design procedures

5.3.4. Manifolds

5.3.5. Mainline Pipe System Design

5.4. FILTRATION

5.5 SUMMARY OF THE DESIGN PROCESS
ACKNOWLEDGEMENTS
LIST OF TERMS AND SYMBOLS
REFERENCES
SUPPLEMENTAL READING
CHAPTER 6. ECONOMIC IMPLICATIONS OF MICROIRRIGATION

6.1. INTRODUCTION

6.1.1. The Farm-Level Perspective

6.1.2. The Public Perspective

6.2. FARM-LEVEL COSTS OF MICROIRRIGATION

6.2.1. Fixed and Variable Costs

6.2.2. Examples from the Literature

6.2.2.1. Irrigating vegetables in Florida

6.2.2.2. Irrigating field crops with subsurface drip irrigation systems

6.2.2.3. Other examples

6.3. FARM-LEVEL BENEFITS OF MICROIRRIGATION

6.3.1. Crop Yield Effects

6.3.1.1. Deciduous fruits and nuts

6.3.1.2. Citrus

6.3.1.3. Small fruits

6.3.1.4. Tomato

6.3.1.5. Melons

6.3.1.6. Other fruits and vegetables

6.3.1.7. Cotton

6.3.1.8. Sugarcane and sugarbeets

6.3.2. Frost and Freeze Protection with Microsprinklers

6.3.3. Fertigation

6.3.4. Chemical Application of Non-Fertilizer Materials

6.3.5. Irrigation with Saline Water and Effluent

6.4. FARM-LEVEL OBSERVATIONS

6.5. PUBLIC BENEFITS AND POLICY IMPLICATIONS

6.6. SUMMARY
ACKNOWLEDGEMENTS
REFERENCES
II. OPERATION AND MAINTENANCE PRINCIPLES
CHAPTER 7. AUTOMATION

7.1. INTRODUCTION

7.2. CONTROL THEORY

7.2.1. Control Methods

7.2.1.1. On-off control

7.2.1.2. Stepwise control

7.2.1.3. Continuous control

7.2.2. Linear Systems

7.3. AUTOMATIC CONTROL SYSTEMS

7.3.1. Soil Water Methods

7.3.1.1. Soil water potential

7.3.1.2. Soil water content

7.3.1.3. Wetting front detection

7.3.2. Plant Water Methods

7.3.2.1. Leaf water potential method

7.3.2.2. Plant canopy temperature method

7.3.2.3. Plant turgor methods

7.3.2.4. Evapotranspiration estimates

7.3.2.4.1. Evapotranspiration models

7.3.2.4.2. Direct measurement of Etc

7.4. INSTRUMENTATION AND HARDWARE

7.4.1. Controllers

7.4.2. Valves

7.4.3. Flowmeters

7.4.4. Environmental Sensors

7.4.5. Filters

7.4.6. Chemical Injectors

7.5. SUMMARY
REFERENCES
CHAPTER 8. APPLICATION OF CHEMICAL MATERIALS

8.1. INTRODUCTION

8.1.1. Definitions

8.1.2. Basic Information

8.1.3. Advantages of Chemigation

8.1.4. Disadvantages of Chemigation

8.1.5. Types of Agrochemicals

8.1.5.1. Water soluble chemicals

8.1.5.2. Wettable powders

8.1.5.3. Emulsifiable (oil soluble) chemicals

8.1.5.4. Gases

8.1.6. Safety

8.1.6.1. Following the label and other regulations

8.1.7. General Considerations

8.1.7.1. Problems with chemical mixes

8.2. CHEMICAL INJECTION METHODS

8.2.1. Injection Pumps and Systems

8.2.2. Pollution Prevention

8.2.2.1. Electrical and mechanical interlock system

8.2.2.2. Backflow prevention in the irrigation line

8.2.2.3. Injection line components

8.2.3. Chemical Supply Tanks and Secondary Containment

8.2.4. Corrosion Resistance of Surfaces

8.2.5. Maintenance

8.3. CHEMICALS AND CALCULATION OF INJECTION RATES

8.3.1. Fertigation

8.3.1.1. Calculation of plant nutrient requirements

8.3.1.2. Fertilizer selection and calculation of injection rates

8.3.2. Chemigation of Non-Fertilizer Materials
REFERENCES
CHAPTER 9. APPLICATION OF BIOLOGICAL EFFLUENT

9.1. INTRODUCTION

9.1.1. Advantages of Applying Biological Effluent

9.1.2. Disadvantages of Applying Biological Effluent

9.2. CHARACTERISTICS OF BIOLOGICAL EFFLUENTS

9.2.1. Effluent Source and Degree of Treatment

9.2.2. Composition of Effluent

9.2.3. Characteristics of Effluents Used in Some Microirrigation Studies

9.3. BIOLOGICAL EFFLUENT CONSTITUENT BEHAVIOR IN SOILS

9.3.1. Nitrogen Uptake by Plants and Potential Loss Mechanisms

9.3.2. Phosphorus Uptake by Plants and Potential Loss Mechanisms

9.3.3. Trace Element Uptake by Plants and Potential Loss Mechanisms

9.3.4. Salinity Management

9.3.5. Pathogenic Organisms

9.4. HEALTH CONSIDERATIONS

9.4.1. Typical Regulations

9.4.2. Practices to Meet the Regulations

9.5. SITE CONSIDERATIONS

9.5.1. Soils

9.5.2. Climate

9.5.3. Crops

9.5.4. Land Area

9.6. DESIGN AND MANAGEMENT CONSIDERATIONS

9.6.1. System Components

9.6.2. Filtration Requirements

9.6.3. Chemical Treatment Requirements

9.6.4. Dripline Flushing

9.6.5. Monitoring Procedures
ACKNOWLEDGEMENTS
REFERENCES
CHAPTER 10. FIELD PERFORMANCE AND EVALUATION

10.1. INTRODUCTION

10.1.1. Uniformity of Water Application

10.1.2. Order of Significance of Design Parameters

10.1.3. The Goal of Microirrigation Application

10.2. VARIATIONS OF IRRIGATION APPLICATION

10.2.1. Variations from Hydraulic Design

10.2.2. Manufacturer’s Variation

10.2.3. Effects by Grouping of Emitters

10.2.4. Possible Clogging Effects

10.2.5. Total Variation

10.3. UNIFORMITY CONSIDERATIONS

10.3.1. Uniformity Parameters

10.3.2. A Linearized Water Application Function

10.3.3. Uniformity and Total Yield

10.3.4. Uniformity and Total Economic Return

10.4. FIELD PERFORMANCE AND IRRIGATION STRATEGY

10.4.1. Significance of Irrigation Scheduling

10.4.2. Optimal Irrigation

10.4.3. Conventional Irrigation

10.4.4. A Simple Irrigation Schedule

10.4.5. Irrigation Strategy for Environmental Protection

10.4.6. Microirrigation for Water Conservation

10.4.6.1. Comparing optimal schedule with conventional irrigation schedule

10.4.6.2. Comparing simple irrigation schedule with conventional irrigation schedule

10.4.6.3. Comparing simple irrigation schedule with the optimal irrigation schedule

10.4.6.4. Comparing the irrigation schedule for environmental protection with the optimal irrigation schedule

10.4.6.5. Comparing the irrigation schedule for environmental protection with the simple irrigation schedule

10.5. FIELD EVALUATION AND ADJUSTMENT

10.5.1. Design Criteria of Microirrigation

10.5.1.1 Uniformity parameters

10.5.1.2. Determination of design criteria

10.5.1.3. Selection of design criteria

10.5.2. Field Evaluation

10.5.2.1. Significance of field evaluation

10.5.2.2. Uniformity measurement

10.5.3. Repairs and Adjustment

10.5.3.1. Repairing leaks in the system

10.5.3.2. Adjustment of irrigation time

10.5.3.3. Adjustments for changes in uniformity
LIST OF TERMS AND SYMBOLS
REFERENCES
CHAPTER 11. MAINTENANCE

11.1. EMITTER OPERATION

11.1.1. Evaluation of Emitter Clogging

11.1.1.1. Source of water

11.1.1.2. Surface water

11.1.1.3. Groundwater

11.1.1.4. Wastewater

11.1.2. Water Quality

11.1.2.1. Physical aspects

11.1.2.2. Chemical aspects

11.1.2.3. Biological aspects

11.1.3. Causes

11.1.3.1. Physical, chemical, and biological factors

11.1.3.2. Microorganisms

11.1.3.3. Macroorganisms

11.2. WATER TREATMENT

11.2.1. Filtration

11.2.1.1. Screen filters

11.2.1.2. Disk filters

11.2.1.3. Media filters

11.2.1.4. Settling basins

11.2.1.5. Cyclonic filters or centrifugal separators

11.2.1.6. Filter design and operation

11.2.2. Chemical Treatment

11.2.2.1. Chemical precipitation

11.2.2.2. Acid treatment

11.2.2.3. Chlorination

11.2.2.4. Chemical injection

11.3. MAINTENANCE OPERATION

11.3.1. Approach

11.3.1.1. Chemical water treatment research

11.3.1.2. Preventive maintenance practices

11.3.1.3. Flushing

11.3.1.4. Reclamation

11.4. GUIDELINE AND PRACTICES
REFERENCES
SUPPLEMENTAL READING
III. SYSTEM TYPE AND MANAGEMENT PRINCIPLES
CHAPTER 12. SURFACE DRIP IRRIGATION

12.1. INTRODUCTION

12.2. SURFACE DRIP IRRIGATION OF PERMANENT CROPS

12.2.1. Introduction

12.2.2. Advantages and Disadvantages of Surface Drip Irrigation for Permanent Crops

12.2.3. Suitability

12.2.3.1. Suitable tree and vine crops

12.2.3.2. Geographical considerations

12.2.3.3. Water supply and quality

12.2.3.4. Maintenance and longevity

12.2.3.5. Irrigation uniformity

12.2.4. Surface Drip Design and Application

12.2.4.1. Drip emitters

12.2.4.1.1. Physical description of drip emitters

12.2.4.1.2. Emitter hydraulic characteristics

12.2.4.1.3. Coefficient of manufacturing variation

12.2.4.2. Lateral line drip tubing

12.2.4.2.1. Lateral line spacing

12.2.4.2.2. Lateral length

12.2.4.3. Emitter spacing

12.2.4.4. Design emission uniformity

12.2.4.5. Installation issues

12.2.5. Management, Evaluation, and Maintenance of Surface Drip
Irrigation Systems

12.2.5.1. Water requirements

12.2.5.2. Crop response

12.2.5.3. Drip irrigation system application rate

12.2.5.4. Irrigation efficiency

12.2.5.5. Irrigation frequency

12.2.5.6. Special management issues

12.2.6. Evaluation of Surface Drip Irrigation Systems

12.3 SURFACE DRIP IRRIGATION FOR ROW CROPS

12.3.1. Advantages and Disadvantages of Surface Drip irrigation for Row Crops

12.3.2. Suitability

12.3.3. Drip Materials

12.3.4. Driplines

12.3.5. Manifolds

12.3.6. Emitter and Dripline Spacing

12.3.7. Installation and Extraction of Surface Driplines

12.3.8. Patterns of Soil Water Content

12.3.9. Patterns of Soil Salinity

12.3.10. Crop Response to Surface Drip Irrigation

12.3.10.1. Surface versus subsurface drip irrigation

12.3.10.2. Irrigation frequency effects

12.3.11. Managing a Drip Irrigation System of Row Crops

12.3.12. Using Plastic Mulch with Surface Drip Irrigation
LIST OF TERMS AND SYMBOLS
REFERENCES
CHAPTER 13. SUBSURFACE DRIP IRRIGATION

13.1. APPLICATION AND GENERAL SUITABILITY

13.1.1. Advantages of SDI

13.1.2. Disadvantages of SDI

13.1.3. Suitability Considerations

13.1.3.1. Suitable crops

13.1.3.2. Geographical and topographical considerations

13.1.3.3. Water supply and quality

13.1.3.4. Maintenance and longevity

13.1.3.5. System uniformity considerations

13.1.3.5.1. System uniformity considerations related to emitter clogging

13.1.3.5.2. System uniformity considerations related to root intrusion and root pinching

13.1.3.5.3. System uniformity considerations related to mechanical or pest damage

13.1.3.5.4. System uniformity considerations related to soil overburden and/or compaction

13.1.3.5.5. System uniformity considerations related to soil hydraulic
parameters

13.1.3.5.6. System uniformity and longevity

13.2. SYSTEM DESIGN AND INSTALLATION

13.2.1. Materials and Components

13.2.1.1. Emitter and dripline characteristics

13.2.1.2. Additional SDI system components

13.2.2. Dripline and Manifold Design Issues

13.2.2.1. Dripline, crop row, and emitter spacing

13.2.2.2. Emitter flowrate

13.2.2.3. Dripline length

13.2.2.4. Flushing requirements and flushline design

13.2.2.4.1. Flushing velocity

13.2.2.4.2. Dripline inlet pressure and flowrate during flushing

13.2.2.4.3. Sizing the flushline and flush valve

13.2.2.5. Dripline depth

13.2.3. Installation Issues

13.2.4. Special or Unique Design Considerations

13.2.4.1. SDI design and electrical technologies

13.2.4.2. SDI design issues for recycled waters and biological effluent

13.2.4.3. Use of SDI in fully enclosed subirrigation (FES) systems

13.3. SOIL AND CROP MANAGEMENT

13.3.1. Soil Issues

13.3.1.1. Soil physical characteristics and soil water redistribution

13.3.1.2. Salinity aspects

13.3.1.3. Soil water redistribution problems caused by backpressure

13.3.1.4. Soil compaction

13.3.1.5. Managing the soil water budget components

13.3.1.6. Special or unique soil issues

13.3.1.6.1. Weed control

13.3.1.6.2. Application of insecticides for crop protection

13.3.1.6.3. Application of biological effluent

13.3.1.6.4. Soil profile injection of gases

13.3.2. Crop Issues

13.3.2.1. Crop water uptake and crop growth

13.3.2.2. Frequency of irrigation

13.3.2.3. Crop response to conjunctive water and nutrient management

13.4. SUMMARY
ACKNOWLEDGMENTS
LIST OF TERMS AND SYMBOLS
REFERENCES
CHAPTER 14. BUBBLER IRRIGATION

14.1. APPLICATION AND GENERAL SUITABILITY

14.1.1. Advantages and disadvantages

14.1.1.1. Potential advantages

14.1.1.2. Potential disadvantages

14.2. SYSTEM DESIGN AND APPLICATION

14.2.1. Materials and components

14.2.1.1. Gravity system emitters

14.2.1.2. Pressurized system emitters

14.2.1.3. Laterals and manifolds

14.2.1.4. System design procedures

14.3. SAMPLE DESIGN—LOW HEAD BUBBLER SYSTEM

14.4. MANAGEMENT, EVALUATION, AND MAINTENANCE

14.4.1. Soil Issues

14.4.2. Crops

14.4.3. Evaluation and Maintenance
LIST OF TERMS AND SYMBOLS
REFERENCES
CHAPTER 15. MICROSPRINKLER IRRIGATION

15.1. APPLICATION AND SUITABILITY OF MICROSPRINKLERS

15.1.1. Advantages of Microsprinkler Systems

15.1.2. Disadvantages of Microsprinkler Systems

15.2. MATERIALS AND COMPONENTS

15.2.1. Materials Used in Systems

15.2.1.1. Ferrous materials

15.2.1.2. Non-ferrous metals

15.2.1.3. Plastics

15.2.1.4. Elastomers

15.2.2. Microsprinkler Emitters

15.2.2.1. Emitter hydraulic characteristics

15.2.3. Emitter Manufacturing Variation

15.2.4. Emitter Types

15.2.4.1. Orifice control emitters

15.2.4.2. Vortex control emitters

15.2.4.3. Pressure compensating emitters

15.2.5. Emitter Wetting Patterns

15.2.6. Stake Assemblies

15.2.7. Lateral Tubing

15.3. LATERAL AND MANIFOLD DESIGN

15.3.1. Head Losses in Lateral Lines

15.3.2. Pressure Variation

15.3.3. Lateral Design

15.4. UNIQUE MANAGEMENT CONSIDERATIONS

15.4.1. Young Trees

15.4.2. Application Volumes

15.4.4. Freeze Protection

15.5. EVALUATION OF MICROSPRINKLER SYSTEMS

15.5.1. Uniformity

15.5.2. Irrigation System Efficiency

15.5.3. Wetting Pattern

15.5.4. Effects of Wear
LIST OF TERMS AND SYMBOLS