Course Content
Introduction
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Definition:
Importance of Irrigation in Agriculture
Physical properties of soil in relation to irrigation.
Volume and mass relationships of soil constituents
Kinds of soil water
Soil Moisture Retention and Movement
Soil moisture
Range of available water holding capacity of soil
Movement of water within Soils
Factors affecting the infiltration
Rooting characteristics and moisture extraction pattern
Effective Root Zone
Critical stages of crops for soil moisture (Moisture sensitive period)
Crop water requirement
Terminology
Measurement of ET
Types of field water losses
Farm water requirement and determination of stream size
Duty and Delta
Relationship between delta and Duty
Measurement of irrigation water
Measurement Devices
Types of weir:
Advantages of flumes
Types of orifice
Irrigation scheduling
Indicators for planning irrigation scheduling .
Method of irrigation
Adaptability of ring method:
Adaptability of border strip method
Parameters for furrow
Adaptability of furrow irrigation
Components of drip irrigation system
Advantages of Drip method of irrigation
Types of sprinkler irrigation system
Advantages of Sprinkler system
Types of irrigation system in Nepal and their Structural components
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Summary
Types of flow of irrigation depending on the source of water
Lift irrigation system:
Water Conveyance and control
Types of Open Channel
Some common terms describing flow in open channels
Estimating velocity of flow in open channels
Darcy-Weisbach Formula
Value of ‘n’ for different types of the channel
Discharge Capacity of the Channel
Permissible slope of the Earth channels
Define hydraulically best section of a channel.
Structures to control erosion in irrigation channel
Water control and diversion structures
Channel Crossing structures
Performance of farm irrigation.
Types of efficiencies
Occurrence and utilization of ground water for irrigation.
Irrigation wells
Types of Aquifier
Types of wells
Methods of well digging
Water lifting devices
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Introduction
Displacement pump
Types of reciprocating pump
Force Required to operate reciprocating pump
Pump characteristics (Parameters)
Centrifugal Pump
Principle of operation of centrifugal pump
Priming of the pump
Single stage and Multistage pump
Performance of irrigation pumps
Specific Speed
Vertical Turbine Pump:
Propeller pump
Land Grading and field layout
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Land Grading
Field layout
Reclamation of problem soils
Reclamation procedures
Field Drainage system
Problem of poor-quality water
Water quality criteria
Learn Principles and Practices of Farm Water Management with Rahul
About Lesson

Farm water requirement and determination of stream size

a. Water requirement:

  • It is the quantity of water required by a crop in a given period of time for its normal growth under field condition at a given place.
  • It includes losses during the application of water and the quantity of water required for special operation such as land preparation, transplanting, leaching, etc.

 

WR = ET or CU + Application losses + Special needs

 

Numerically,

WR = IR + ER + S

Where,

WR = Field water requirement

IR = Irrigation requirement

ER = Effective rainfall

S= soil profile contribution

 

b. Field Irrigation Requirement:

  • It refers to the water requirement of crops exclusive of effective rainfall and contribution from soil profile and it may be given as ,

 

IR = WR – [ ER + S]

  • It depends on irrigation need of individual crop, their area and the losses in the farm water distribution systems, mainly by the way of seepage.
  • The irrigation requirement of an outlet command area includes the irrigation requirement of individual farm holdings and the losses in the conveyance and distribution system.

 

c. Effective rainfall:

  • It is that portion of the total rainfall which directly satisfy crop water needs.

 

d. Field water Balance:

  • It includes all gains, losses and changes of storage of water occurring in a given field within specified boundaries during a specified period of time.
  • Gains includes precipitation, irrigation, accumulation of runoff from higher tracts of land.
  • Losses includes surface runoff, deep percolation out of the root zone, evaporation from soil surface and transpiration from the crop canopy.

 

Change in Storage = gains – lossess

Or, Δ S + Δ V = ( P+I) – ( R+D+E+T)

 

Where,

P = precipitation

I= Irrigation

R= Run off from field

D = Downward drainage

E= Evaporation from soil

T = Transpiration by the crop canopy

ΔS = The change in soil water content of the root zone

ΔV = The Change in plant water content

 

e. Net Irrigation Requirement (NIR):

  • It is the depth of irrigation water or the amount of water required to bring or drain the soil moisture in the effective root zone of the soil upto the field capacity.

 

NIR = £ni=1  x Ai x Di

 

 Where,

NIR = Net irrigation requirement

Mfci, Mbi = Moisture content % in Fc and before irrigation in the ith layer in the soil

Ai = Apparent specific gravity

D = Depth of soil in the ith layer

 

 

f. Field irrigation Requirement (FIR)

  • It is the amount of water required to meet net irrigation requirement plus the water losses, percolation in he field water courses, field channels and the field application of water.

 

FIR = NIR/ ηa

Where η = water application efficiency

 

Note: Losses in the water conduct channel is called conveyances or transit losses.

 

g. Gross Irrigation Requirement:

  • It is the sum of water required to satisfy the field irrigation requirement and the water lost as the conveyance losses in the distribution in the fields.

 

GIR = FIR/ ηc

Where, ηc = water conveyance efficiencies.

 

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