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Civil Engineering S S KA Sr. Prof. (Civil Engg), N 1/2/22 SPCE 1
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Wednesday, May 3, 2023SPCE
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Civil Engineering
S S KALRASr. Prof. (Civil Engg), NAIR
Wednesday, May 3, 2023SPCE
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GAUGES ON WORLD RAILWAYSTYPE OF GAUGE
GAUGE IN mm
%OF TOTAL
LENGTH
NAMES OF COUNTRIES
BROAD GAUGE (5’6’’)
1676 6 INDIA, PAKISTAN, SRI LANKA, BRAZIL, ARGENTINA
BROAD GAUGE (5’)
1524 9 RUSSIA, FINLAND
STANDARD GAUGE (4’8.5’’)
1435 62 ENGLAND,USA, CANADA, TURKEY, PERSIA & CHINA
CAPE GAUGE (3’6’’)
1067 8 AFRICA, JAPAN, AUSTRALIA, NEWZEALAND,
METRE GAUGE (3’3.5’’)
1000 9 INDIA, FRANCE, SWITZERLAND, ARGENTINA
VARIOUS OTHER GAUGES
VARIOUS GAUGES
6 INDIA-NARROW GAUGE (762mm & 610mm) – 2’6’’ & 2’)
TOTAL 100
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CLASSIFICATION OF LINES ON INDIAN RAILWAYS
GROUP SPEED POTENTIAL (KMPH)
A 160B 130C SuburbanD 110 and GMT<20
D ‘Spl’ 110 and GMT>20E <110and GMT<5
E ‘Spl’ <110and GMT>5
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MAJOR AREAS OF RESPONSIBILITY
1. PERMANENT WAY
2. WORKS
3. BRIDGES
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PRINCIPAL FEATURES OF PERMANENT-WAY
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Function• Support & guide vehicles running on it
SleepersBallast
Embankment
Rails
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Rails are members of the track laid in two parallel lines to provide continuous surface for the movement of Trains.
Function of rails Provide a continuous and level surface Provide a pathway which is smooth and offers
less friction Lateral guide for the wheels Bear changes due to vertical loads etc. Transfers load to formation through sleepers on
wider area.
RAILS
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BG 60 KG, 52 KG, 90R MG 90R, 75 R, 60R NG 50 R
Rail is Designated by Weight Per Unit Length (Kg/m or Lb/yd) KG- Means Kg/m (Indian Railway Standards) R- Revised British Standards ( Lb/yd)
IRS 52 kg 880 SAIL X10 OBIRS 52 kg 710 TISCO V 1991 OB
Standard Rail section
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SERVICE LIFE OF RAILS
RAIL SECTION
TOTAL GMT CARRIED, FOR 72 UTS (MM) RAILS
TOTAL GMT CARRIED
FOR 90UTS RAILS
60 KG 550 800
52 KG 350 525
90 R 250 375
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Functions: To Maintain Gauge distance To distributes load over a greater area To provide resilient bed To maintain track to level & line
SLEEPERS
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Wooden -0.3%
Steel- 1.5%
Cast Iron – 4.0%
Pre Stressed Concrete- 94.2%
Fibre Reinforced Plastic
Different Types of Sleepers
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Type Wooden Steel CI PSC
Service life (Yrs) 12-15 40-50 40-50 50-60
Weight(Kg) 33 79 87 267
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Concrete sleepers (PSC)Advantages
(a) Being heavy, tend more strength and stability to the track and specially suited to LWR
(b) With elastic fastening, all along the track to maintain better gauge, cross level & alignment
(c) Being flat bottom, suited for mechanical maintenance(d) Can be used in track circuited areas
Disadvantages(b) Handling and laying difficult(c) Damage at time of derailment(d) No scrap value(e) Not suitable for beater packing
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Elastic fastenings
Requirement of an elastic fastening
1. It should hold the gauge firmly in place2. It should have an adequate toe load3. It should provide sufficient elasticity to absorb the
vibratory shocks4. It should offer adequate lateral resistance.
Grooved Rubber Pads Liners Elastic rail clips MK III
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Different Types of Concrete SleepersNormal line sleepers
Points & Crossings
Guard rails
Switch Expansion Joints
Check rail on curves
Level crossings
Dual Gauge
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BALLAST Sleeper rests on a bed of stones called ‘Ballast’ Functions:
Distributes load over a greater area to ‘formation’ Provides elastic & resilient bed Helps to maintain track to level & line Helps in drainage. Longitudinal & lateral stability to track
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REQUIREMENTS OF GOOD BALLAST Tough and wear resistant Hard to resist abrasion and attrition Non-porous and non-absorbent of water Durable and should not get pulverised due to
weather Cubicle having sharp edges Cheap and economical Size between 20mm – 65mm
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FLAWS IN RAILS/WELDS Inherent defects Defects due to fault in rolling stock Excessive corrosion Badly maintained joints Defects in weld joints Improper maintenance of track
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ULTRA SONIC FLAW DETECTION OF RAILS
BY TROLLY 2-3 KM/DAY BY SPURT CAR 100-200 KM/DAY
SPURT- SELF PROPELLED ULTRASONIC RAIL TESTING CAR.
SPCE
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SYSTEMS OF TRACK MAINTENANCE
Conventional system From one end - periodic
Directed Track Maintenance (DTM) Need based - as per requirement
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METHODS OF PACKING OF TRACK
Manual (beater) Packing Systematic Through Packing Systematic Overhauling Picking up of slacks
Machine Packing
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MACHINE MAINTENANCE
Necessitated due to Heavier track, difficult to maintain manually.
Damage to Concrete Sleepers due to beater packing
For Uniform Packing
Longer retentivity
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TRACK GEOMETRYMAIN PARAMETERS
Gauge
Alignment
Unevenness- deviation in vertical plane
Cross Level/Twist –out of planeness of one of the four wheels
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METHODS OF MEASUREMENT OF TRACK GEOMETRY.
Manual Track Recording Devices
Microprocessor Based Track Recording Car
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WORKS ON TRACK
Works of routine maintenance Works of short duration Works of long duration
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PROTECTION OF LINE IN CASE OF WORKS OF SHORT DURATION AT STOP DEAD RESTRICTION
DOUBLE LINE SECTION
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PROTECTION OF LINE IN CASE OF WORKS OF SHORT DURATION AT REDUCED SPEED
SAME AS IN CASE OF STOP DEAD RESTRICTION EXCEPT THAT DETONATORS ARE NOT PLACED AND FLAGMAN SHALL LIFT THE FLAG ONLY WHEN DRIVER HAS REDUCED THE SPEED. TRAIN WILL BE HAND SIGNALLED FORWARD
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WORKS OF LONG DURATION Line blocked by P-Way Inspector in consultation with
operating department Caution order issued by Station Master
Temporary Engineering Signals provided at site by PWI
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PROVIDED AT INTERSECTION OF TWO TRACKS TO PERMIT TRAIN TO PASS FROM ONE TO OTHER.
POINTS AND CROSSINGS
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TURNOUT
AN ARRANGEMENT OF POINTS & CROSSINGS WITH LEAD RAILS BY MEANS OF WHICH ROLLING STOCK IS DIVERTED FROM ONE TRACK TO ANOTHER .
LEFT HAND RIGHT HAND
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LEFT HAND SWITCH, WING RAIL & STOCK RAILS
ON OBSERVER’S LEFT.
RIGHT HAND SWITCH, WING & STOCK RAILS
ON OBSERVER’S RIGHT.
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COMPONENTS OF A TURNOUT
• POINTSTOCK RAILSWITCH RAILSTRETCHER BARS
• CROSSING
CROSSING BODYWING RAILSCHECK RAILS
• LEAD RAILS
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DESIGNS OF SWITCHES
LOOSE HEEL: Tongue rails are joined to lead rails at heel with fish plates Weak Joint
FIXED HEEL: Tongue rails are held to stock rails at heel by distance blocks & Bolts Rigid Joint
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SHAPES OF SWITCHES STRAIGHT SWITCH
Tongue rails is straight from the tip of the switch to the heel.
CURVED SWITCH
Tongue rail is curved from the tip to heel to same radius as of turnout.
Permits higher speeds on turnouts.
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CHECK RAIL CLEARANCE:
BG
Min 44 mm Max 48 mm
MG Min 41 mm Max 44 mm
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In IRS design, denoted by the co-tangent of the angle
Designated as 1 in N i.e. 1 in 12 crossing will have an angle whose co-tangent is 12.
On Indian Railways 4 sizes are used 1 in 8 ½ 1 in 12 1 in 16 & 1 in 20 ( Flatter Angle - Larger value)
ANGLE OF CROSSING
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BUILT UP CROSSING
4 pieces of rails bent & joined by bolts & blocks
Disadvantage : Not very rigid . Advantage : Cheap.
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One piece cast without Bolts.
Advantages: Better wear resistant Less cost of maintenance
Disadvantage High initial cost
CAST MANGANESE STEEL (CMS) CROSSING
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DIAMOND CROSSING When one track crosses another at an angle
Comprising of two acute and two obtuse crossings
When required, Train on one track may also be diverted to other track
Made possible by the inclusion of two or four pair of switches with the connecting lead rails
Diamond crossing with slips
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FACTORS LIMITING SPEEDS OVER TURNOUTS
Sudden change in direction of the running edge, at the entry to the switch from a straight track.
Variation in cross level caused by raising of the switch rails.
Absence of super-elevation over the turnout curve.
Non transitioned entry from the curved lead to the straight crossing.
Gaps in the gauge face and running table at the crossing.
Direction and location of the track in horizontal and vertical planes.
Basic requirements –
To serve the purpose of the project – Strategic, Political, Development of backward area, Shortening of existing route, Connecting major trade centers
Economic considerations Aesthetic considerations Maximum safety and comfort
Alignment
Gauge Obligatory points Topography Geological formation Effect of flood Position of road crossings Proximity of labour and material Location of stations Cost considerations Traffic considerations Strategic & Political considerations Overall economy
Factors Affecting Choice of Alignment
Curves are provided on a railway track:
To avoid obstructions To pass through obligatory points To have crossings at desired angle with rivers etc.
To develop required length between two points without exceeding prescribed ruling Grade.
Curvature
Horizontal curves – When a change in direction of the track is required.
Vertical curves – Provided at points where two gradients meet and algebraic difference between two grades is equal or more than 0.04 %
Transition curves – is an easement curve, in which the change of radius is progressive throughout its length
Reverse curve
Compound curves
Equilibrium speed – when centrifugal force generated is exactly balanced by cant provided.
Cant deficiency – Difference of cant provided and theoretically required at speed higher than equilibrium speed. Max limit 100 mm on Group A & B and 75 mm on others.
Cant excess – Difference of cant provided and theoretically required at speed lower than equilibrium speed. Max limit on BG is 75 mm.
SUPERELEVATION
B.G. 100 80 with check rails )
M.G. 160 (>140 with check rails )
N.G.( 0.762m) 400
Existing curves are surveyed @ 10 meters apart with the chord of 20 m length
MAXIMUM DEGREE OF CURVATURE
GRADIENT
To negotiate the rise or fall in the level of the railway track
Gradient = h/x (1 in N) = 100h/x (%)
h
x
To connect various stations at different elevations To provide uniform rise or fall To follow the natured contours of the ground To reduce the cost of earthwork
REQUIREMENT OF GRADIENT
1. Ruling gradient
2. Pusher or Helper gradient
3. Momentum gradient
4. Gradients in yards
TYPES OF GRADIENTS
Curves provide extra resistance to movement of trains.
To limit it as on ruling gradient, grade on curve is compensated (flattened) @ –
0.04% per degree of curve on BG 0.03% per degree of curve on MG and 0.02% per degree of curve on NG.
Grade Compensation on Curves
