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Saturday, 8 December 2018

Highway Geometric Design (Transition Curves)


Transition Curves: (introduced between a straight and a circular curve).

(A) Objects of providing transition curves:
>> To introduce gradually the centrifugal force between the Tangent point and beginning of circular          curve, avoiding sudden jerk on the vehicle.
>> To enable the driver turn the steering gradually for comfort and security.
>> It introduces super elevation and extra widening on curves, gradually
>> To improve aesthetic appearance of road.


Transition curves have got radius of curvature gradually changing from infinity to the designed radius.

(B) Types of Transition Curves:



(i) Spiral (or Clothoid or Glover’s spiral):

>>This is the ‘Ideal transition curve’.
>> Radius of curvature at every point is inversely proportional to the distance of the point from the          beginning of the curve. 
>>Thus the rate of change of acceleration is uniform
>> L.R = Constant or 1 directly proportional to 1 / r
>> IRC recommends ‘Spiral’ as ideal transition curve

(ii) Bernoullie’s  Lemniscate :

>> Mostly used in modern roads where deflection angle n the curve is large
>> Radius of curve decreases more rapidly with the length
>> It is an auto genesis curve (follows a path which is actually traced by a vehicle when turning                freely)
>> The curve can be set by polar coordinates
(iii) Cubic parabola (Froude’s transition or easement curve)
>> Can be set by simple Cartesian coordinates
>> Used for valley curves
>> 

>> Condition is x=1; or cosφ =1


(iv) Cubic spiral:
>>simple to set the curve
>>

>>Condition is sinφ =φ = dy/dl

(c) Length of Transition Curves:
(i) Rate of change of radial (or centrifugal) acceleration:

v = Velocity in ‘m/see’
R = radius of curve in ‘m’
C = rate of change of centrifugal acceleration

(ii) Rate of change of Super elevation:


>> If pavement is rotated outer edge
Ls =  eN (W+Ww)
>> If pavement is rotated about centre line
LS = eN ( W + We)/2
Where
W = normal width of pavement,
We = extra widening on circular curve
e= Super elevation
1 in N = Rate of change of super elevation.
As per IRC
>> N = 150 in plane and rolling trains
>> N = 60 in hill roads.

(iii) Empirical formulae (as per IRC):

For plain and rolling terrain,
Ls = 2.7V2/R
For mountainous or steep terrain, Ls =V2 /R
The length of transition curve shall be the highest of the above.
Shift of the curve is s = Ls  2 = 24R

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