Tube wells and their design

Md Moudud Hasan
Lecturer
Department Agricultural and Industrial Engineering
Faculty of Engineering
Hajee Mohammad Danesh Science and Technology University
Dinajpur
MM HASAN,LECTURER,AIE,HSTU

Tube wells consists essentially of a hole bored in
to the ground for tapping ground water from deep
pervious zones.
Compared to open wells, tube wells have small
diameter(usually 8cm – 60cm) and deep/larger
depth ( more than 30m).
Yield from standard tube well 40-45 l/s.
Shallow tube wells : 30-60m depth, 20 L/s yield
Deep tube wells : 60-300 m depth, yield 200 L/s

No ADVANTAGES DISADVANTAGES
1 Do not require much space Requires costly & complicated
drilling equipment & machinery
2 Can be constructed quickly- not
time consuming
Requires skilled workers & great
care to drill & complete the tube
well.
3 Fairly sustained yield of water
can be obtained even in years
of drought
Installation of costly turbine or
submersible pumps is required.
4 Economical when deep seated
aquifers are encountered.
Possibility of missing the
fractures, fissures & joints in hard
rock areas resulting in many dry
holes.
5 Generally good quality of water
is tapped
ADVANTAGES AND DISADVANTAGES OF TUBE WELLS

Tube wells are classified on the basis of:
the entry of water into the well,
the method of construction,
the depth and
the type of aquifer tapped.
Based on Entry of water
Tube wells are classified as
• screen wells and
• cavity wells

Screen wells
It permit the entry of
water from the
surrounding aquifer
Screens are lowered
into the bore hole.
Usually limited to
shallow depths
Fig-1.6 Tube wells using screens to permit the entry of water

Cavity well
A cavity well is a shallow tube
well drilled in an alluvial
formation.
Draws water through the
bottom of the well pipe.
Cavity wells are very
economical and can be adopted
where the ground strata
permits its construction.
Requires strong and
dependable roof
Fig-1.7 Schematic sketch of a cavity well

Based on method of construction
Grouped as: drilled wells, driven wells and jetted wells
1. Drilled tube wells
Drilled wells are constructed by making bore holes, using
different drilling methods.
Tube well construction involves drilling the bore hole,
installing the casing and well screen, and developing the
well to ensure sand-free operation at maximum yield.
Techniques of drilling are:
- Hand-augur drilling - Percussion drilling
- Water injection (jetting) drilling - Sludge drilling.
- Rotary-percussion drilling - Rotary drilling

Drilled wells can get water from a much deeper
level than dug wells can—often up to several
hundred meters and smaller in diameter
Drilled wells are typically created using either top-
head rotary style, table rotary, or cable tool
drilling machines, all of which use drilling stems
that are turned to create a cutting action in the
formation, hence the term drilling.
Drilled wells are usually cased with a factory-made
pipe, typically steel (in air rotary or cable tool
drilling) or plastic/PVC (in mud rotary wells, also
present in wells drilled into solid rock).

Hand-auger drilling :
The cutting tool (known as the auger head) is rotated to cut into the
ground, and then withdrawn to remove excavated material. The
procedure is repeated until the required depth is reached. Note:
This method is only suitable for unconsolidated deposits.
Advantages of hand-auger drilling:
Inexpensive.
Simple to operate and maintain.
Disadvantages of hand-auger drilling:
Slow, compared with other methods.
Equipment can be heavy.
Problems can occur with unstable rock formations.
Water is needed for dry holes.

Jetting:
Water is pumped down the center of the drill-rods, emerging as a jet. It then
returns up the borehole or drill-pipe bringing with it cuttings and debris. The
washing and cutting of the formation is helped by rotation, and by the up-and-
down motion of the drill-string. A foot-powered treadle pump or a small internal-
combustion pump are equally suitable.
Advantages of jetting:
The equipment is simple to use.
Possible above and below the water-table.
Disadvantages of jetting:
Water is required for pumping.
Suitable for unconsolidated rocks only (e.g. sand, silt, clay)
Boulders can prevent further drilling

Sludging (reverse jetting)
Water flows down the borehole annulus (ring) and back up the
drill pipe, bringing debris with it. A small reservoir is needed at
the top of the borehole for recirculation. Simple teeth at the
bottom of the drill-pipe, preferably made of metal, help cutting
efficiency.
Advantages of sludging:
The equipment can be made from local,
low-cost materials, and is simple to use.
Disadvantages of sludging:
Water is required for pumping.
Suitable for unconsolidated rocks only.
Boulders can prevent further drilling

Rotary-percussion drilling: In very hard rocks, such as granite, the only way
to drill a hole is to pulverize the rock, using 'down-the-hole hammer' (DTH).
Compressed air is needed to drive this tool. The air also flushes the cuttings and
dust from the borehole.
Advantages of rotary percussion drilling:
Drills hard rocks.
Possible to penetrate gravel.
Fast.
Operation is possible above and below the water-table.
Disadvantages of rotary-percussion drilling:
Higher tool cost than other tools illustrated here.
Air compressor required.
Requires experience to operate and maintain

Percussion drilling
The lifting and dropping of a heavy (50kg+) cutting tool will chip and
excavate material from a hole. The tool can be fixed to rigid drill-
rods, or to a rope or cable.
With a mechanical winch, depths of hundreds of meters can be
reached
Advantages of percussion drilling:
• Simple to operate and maintain.
• Suitable for a wide variety of rocks.
• Operation is possible above and below the water-table.
• It is possible to drill to considerable depths.
Disadvantages of percussion drilling:
• Slow, compared with other methods.
• Equipment can be heavy.
• Problems can occur with unstable rock formations.
• Water is needed for dry holes to help remove cuttings

2. Driven tube wells
It consists of a pipe and well point which are forced into the
water-bearing formation by driving with a wooden maul, drop
hammer or other suitable means.
They develop small yields and their construction is limited to
shallow depths in soft unconsolidated formations free from
boulders and other obstructions.
They are commonly used for domestic water supply.
Constructed by driving a small-diameter, perforated tube with a
pointed end into friable ground like sand or gravel using a
vertical to-and-fro movement
Driven wells may be very simply created in unconsolidated
material with a well or hole structure,

Techniques of driving:
Percussion driving :percussion involves driving
a tube with a pointed
Water injection (or water jetting) driving :
by injecting water under pressure inside a tube
to facilitate digging the soil and removing the
spoil.

3. Jetted tube wells
It is constructed with hand-operated equipment or power-
driven machines, depending upon the type of formation
and the size and depth of the well. A hole in the ground is
made by the cutting action of a stream of water.
The water is pumped into the well through a pipe of small
diameter. It is forced against the bottom of the hole
through the nozzles of a jetting bit.
The hole is cased to prevent a cave-in.
Jetted tube wells have small yields and their construction
is possible only in unconsolidated formations.

Based on Depth
1. Shallow tube wells
are wells of low yield capacity(20 l/s).
The average depth of the well is usually less than 60 m.
Cavity tube wells and strainer tube wells with coir
strainers generally fall in this category. The latter usually
tap only the unconfined aquifer.
2. Deep tube wells
Deep tube wells are wells of high capacity, tapping more
than one aquifer.
Their depth usually ranges from 60-300 m.
May be strainer wells or gravel-pack wells

Based on type of aquifer
Tube wells under this category are classified as:
1. water table wells,
2. semi-artesian wells,
3. artesian wells and
4. hard rock bore wells.
The classification is based on the location of the well and the characteristics
of the aquifer.
Wells may be defined as water table or artesian wells, depending upon
whether they tap a water table aquifer or an artesian aquifer.
Artesian wells are further classified as semi-artesian wells and flowing
artesian wells.
Tube wells bored in hard rock formations are classified as hard rock bore
wells.

Water table wells
These are installed in unconfined aquifers
which are under water table conditions, i.e. the
water level is not under pressure. Generally,
shallow tube wells fall under this category.
Semi-artesian wells
Semi-artesian wells are installed under semi-
artesian conditions of aquifer.
The water is under pressure, but not so high as
to flow out of the well.

Artesian wells
A flowing well gets its supply from an aquifer where the
water is under such high pressure that Water overflows
at the top.
The static water level in this case is above the ground
surface and can be measured within the well casing, if
the pipe is extended high enough so that the overflow
does not occur.
Alternatively, flow can be contained by capping the well
casing, after which the shut-in head can be measured
with a pressure gauge.

A multiple-well system is a group of closely installed shallow
tube wells, usually connected to a common header pipe or
manifold and pumped by suction lift of a centrifugal pump.
Adapted under the following conditions:
1. Where the water table is at shallow depth
2. Where the installation of medium and deep tube wells is not
economical
3. Where the hydraulic characteristics of the aquifer are poor
4. Where salts are present in the deeper layers of the water-bearing
formation
5. Wherever there is a problem of waterlogging
6. Where the conditions are such that a constant level of water is required
to be maintained at some depth from ground surface.

A radial collector well system comprises a series
of horizontal wells discharging water into a
central caisson.
They are located at or close to rivers and other
surface-water bodies.

Infiltration galleries may be described as
trenches dug in river beds
Parallel to the axis of the river or transverse to it
In which are laid perforated pipes or masonry-
lined galleries with openings to permit the entry
of water.
Used in surface water pumping in rural water
supply schemes

The design of a tube well involves the following steps:
1. Mechanical analysis of samples of the underground formation
obtained from various depths and the preparation of a well
log.
2. Design of housing pipe and well casing
3. Design of well screen
4. Design of gravel pack
5. Design for sanitary protection

Effective Size “d10”
• The term ‘effective size’ is defined as formation
particle size, where 10 per cent of the sand is
finer and 90 per cent coarser.
• d10= 0.25 mm ?
• 90% sand grains > 0.25 mm
• 10 % sand grains < 0.25 mm

This is the ratio expressing the variation in grain
size of a granular material.
𝐶 𝑢 =
𝑑60( 40% 𝑟𝑒𝑡𝑎𝑖𝑛𝑒𝑑)
𝑑10(90% 𝑟𝑒𝑡𝑎𝑖𝑛𝑒𝑑)
Uniform material, Cu< 2

Diameter of housing pipe
• Should be at least 5 cm more in diameter than
the nominal diameter of the pump.

Depth of housing pipe
• Pump should be always submerged in water.
• Pump must be set a few meters below the
lowest drawdown level.

Diameter of Well casing pipe
• Is fixed by the permissible velocity of water
through the pipe.
• Velocity may vary between – 1.5 to 4.5 m/s
• Most suitable velocity – 2.5 to 3 m/s.
• a= Q/v
• a= πd2/4
• Where, Q= discharge, a= x-section area, d=
diameter

Thickness of Well casing pipe
• Steel pipes are produced in several thickness.
• Heavier pipes – severe corrosive soil and water
• Lighter pipes – mildly corrosive soil and water
• Thickness of well casing is a function of the
diameter and depth of the well.

Bore size
At least 5 cm bigger in diameter than the casing pipe
If Gravel pack used
Bore size= outside dia of casing pipe + (2 x gravel pack thickness)
Well depth
Depends upon the locations of water-bearing formations
Desired yield of the well
Economic considerations
Hydraulic conductivity of the aquifer material

Permeability of the aquifer a (d10)2 (for same Cu)
Low Cu = more permeable aquifer ( for same d10)
Thick and homogeneous unconfined aquifer- lower 1/3rd
thickness screened
Thick and homogeneous confined aquifer- central 80-90%
thickness screened

The basic requirements of a well screen are
i. It should be resistant to corrosion and deterioration
ii. It should be strong enough to prevent collapse
iii. It should offer minimum resistance to the flow of water
iv. It should prevent excessive movement of sand into the well

Slot Opening
Well screen slot openings is determined by matching the
size of the opening with the grain-size distribution of the
material surrounding the screen.
Slot size varies from as low as 0.2 mm to as large as 5mm
a) Non-Gravel-Pack wells
• For Homogeneous and non corrosive aquifer- slot opening – d60
• For Homogeneous and corrosive aquifer- slot opening – d50
• Optimum size --- 40% line intersects the sample-analysis curve—
screen opening from the horizontal scale---d60
b) Gravel-Pack Wells
• Slot opening – d10 ± 8%

Percent Open Area
It is desirable to provide an open area of about 20 per cent
for well screens .
Diameter of the Screen
Should produce a screen entrance velocity of not
more than 3 cm/s
Maximum entrance velocity – 5 cm/s ( sufficent
sand thickness)

Water table aquifers
Bottom 1/3 to bottom ½ of aquifer may be screened
Artesian Aquifer
75-90 per cent of the thickness of the aquifer may be screened
At least 30 cm of aquifer depth at the top and bottom of the
screen should be left unscreened to safeguard against an error
in the placement of screen during installation.

Minimum length of screen:
For a non-gravel pack well is designed on the basis of the
following equation
ℎ =
𝑄0
𝐴0 𝑉𝑒
Where,
h= minimum length of the well screen, m
Q0= maximum expected discharge capacity of well, m3/min
A0= effective open area per meter length of the well screen, m2
Ve= entrance velocity at the screen, m/min

The term gravel packing refers to the placing of gravel around
the well screen.
The artificial gravel packing may be used under following
conditions:
1. To stabilize fine-grained, poorly-sorted sand aquifers and to avoid sand
pumping.
2. To permit the use of larger slot openings and the resultant higher well
efficiency in fine-grained aquifers.
3. The use of an artificial gravel pack will permit the use of a single slot-
size screen and eliminate the positioning problem in formation of
alternating zones of course and fine aquifer material.

The mean grain size of the pack material bears a specific
relationship to the mean grain size of the formation material.
P A ratio=
50 % 𝑠𝑖𝑧𝑒 𝑜𝑓 𝑔𝑟𝑎𝑣𝑒𝑙 𝑝𝑎𝑐𝑘
50% 𝑠𝑖𝑧𝑒 𝑜𝑓 𝑎𝑞𝑢𝑖𝑓𝑒𝑟
a) Uniform aquifer (Cu ≤ 2)
P A ratio=
should lie between 9 and 12.5
b) Graded Aquifer ( Cu ≥ 2)
P A ratio=
should lie between 12 and 15.5

The following are the desirable characteristics of a good gravel
material
1. It should be clean
2. The grains should be smooth and round (flat particles should be
avoided)
3. It should be a hard, insoluble, siliceous material with less than 5
per cen calcareous particles (limestone). Particles of shale and
gypsum are undesirable.
4. It should be uniform in size.

The gravel-pack material may be screened first through the
screen with the larger openings to remove over-size particles,
and then through the screen with smaller openings to screen
out the under size particles.

The following are the common paths of entry of contaminated
surface water into the tube well:
1. Between the pump and the well casing
2. Around the well casing
3. Improperly placed gravel pack
4. Reverse flow through the pump
5. Subsidence of the soil or aquifer around the well casing due to
sand pumping.

Protecting the top section of a tube well from entry of
contaminants
Grouting and sealing of well casing
Example: 4.1 + 4.2 + 4.3 (Assignment)

The development of tube well is essential process to obtain an
efficient and long –lasting well.
Development of a tube well involves removal of finer material from
around the well screen, thereby enlarging the passages in the
water-bearing formation to facilitate entry of water.
Development increases the effective radius of the well and,
consequently, its yield.

1. Repair to damage done to the formation by drilling operation
and restore the original hydraulic conductivity of the aquifer.
2. To increase the porosity and permeability of the water bearing
formation in the vicinity of the well by removing finer material
of aquifer.
3. To stabilize the formation around well screen to yield sand free
discharge.

1. Over pumping
2. Surging with surge block or boiler
3. Surging and pumping with air-compressor
4. Back washing
5. High velocity jetting
6. Aquifer development techniques:
7. Use of explosive
8. Use of acid

Tube wells and their design

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