Canal design involves defining types of canals based on use and discharge. There are two main types - aqueducts for water supply and navigable waterways. Canals are also classified based on discharge into main, branch, major/minor distributaries and watercourses. Design considers canal shape, lining requirements, and layout to minimize curves and balance cuts and fills. Proper drainage systems including surface ditches and subsurface pipes are also important to control water levels and allow cultivation. Explicit equations have been developed for least-cost design of common canal shapes like triangular, rectangular, trapezoidal and circular.
2. DEFINITION
An artificial channel filled with waterand designed
for navigation , or irrigating land,etc.
An artificial water course or extensivelymodified
natural channel used for inland water transport
and/or the control and diversion of water for
drainage or irrigation
3. TYPESOFCANAL
(BASEDONUSE)
There are two types ofcanals:
Aqueduct: water supply canals that are used forthe
conveyance and delivery of portable for human
consumption, municipal uses, and agriculture
irrigation
Water ways: navigable transportation canalsused
for carrying ships and boats shipping goods and
conveying people.
5. MAIN CANALS
Main canal takes of directly from the
upstream side of weir head works ordam.
Usually no direct cultivation isproposed.
6.
7. BRANCHCANAL
All off takes from main canal withhead discharge of
14-15 cumecsand above are termed asbranch
canals.
Acts asfeeder channel for major distributaries.
8.
9. MAJORDISTRIDUTARY:
All off takes from main canal or branch canal with head
discharge from 0.028 to 15 cumecsare termedasmajor
distributaries .
MINORDISTRIBUTARY:
All off takes taking off fromameasure distributary carrying
discharge lessthan 0.25 cumec are termed asminor
distributaries.
WATERCOURSE
Small channels which carry water from the outlets of amajor
or minor distributary or abranch channel to the fields to be
irrigated.
15. Unlined canal
An unlined canal is the one which asit bed
and banks made of natural soil through which
it is constructed and not provided withalining
of impreviousmaterial.
16. Disadvantages of unlined canal
• Water velocities higher then 0.7m/sec or not tolerable
becauseof erosion . Thelow operating velocitiesrequires
large cross-sectionarea.
• High seepage and conveyance water lossesresult in water
logging of adjacentland.
• Danger of canal bank breakage causedby overtopping ,
erosion and animal burrowing.
• Profuse growth of aquatic weeds retards the flowand causes
heavy maintenances cost.
17.
18. ILL-EFFECTOFWATERLOGGING
• Water seeping from canal down to the soil below may , head
times , raise the ground water very close to the ground level .
• This may result in blocking all the voids in the soil and
obstructing the plant roots tobreathe.
• Normal cultivation operations , such astilling , ploughing,etc.
cannot be easily carried out in wet soils.
19. Irrigation canallayout
• Asfor apossible, curves should be avoided in the alignment
of canals.
• The curves lead to disturbance of flow and atendency to silt
on the inner bend and scour the toe of the outer bend.
• If curves have to be provided ;theyshould be asgentle as
possible.
• Thepermissible minimum radius of curvature for achannel
curve is shorter for lined canals than unlinedones
• Thealignment should be such thatthe cutting and filling of
earth rock should be balanced , asfar aspossible.
20.
21. TYPESOFDRAINAGESYSTEM
Surface drainage
Theseconstitute open ditches , field drains,
proper land grading and relatedstructures.
Landgrading , or properly sloping theland
towards the field drains, is an important
method for effecting surfacedrainage.
23. conclusions
Explicit design equation and
sections shape co efficient havebeen
present for the minimum cost design
of lined canal of triangular,
rectangular trapezoidal& circular
shapes.
Theseequation &co efficient have
been obtained by applying the
nonlinear optimization technique