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Vertical Alignment
CE 5720Spring 2011
Originally Created by Chris McCahill
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Components of The Alignment
Horizontal Alignment
Vertical Alignment
Cross-section
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Vertical Alignment & Topography
Texas DOT
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Today’s Class
• Maximum/minimum grade
• Properties of vertical curves (parabolic)
• Technical design of vertical curves
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Crest Curve
Sag Curve
G1
G2 G3
Vertical Alignment Tangents and Curves
Like the horizontal alignment, the vertical alignment is made up of tangent and curves
In this case the curve is a parabolic curve rather than a circular or spiral curve
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Maximum Grade
Harlech, Gwynedd, UK (G = 34%)www.geograph.org.uk
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Maximum Grade
www.nebraskaweatherphotos.org
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Maximum Grade
Dee747 at picasaweb.google.com
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Maximum and Minimum Grade
One important design consideration is the determination of the maximum and minimum grade that can be allowed on the tangent section
The minimum grade used is typically 0.5%
The maximum grade is generally a function of the
• Design Speed
• Terrain (Level, Rolling, Mountainous)
On high speed facilities such as freeways the maximum grade is generally kept to 5% where the terrain allows (3% is desirable since anything larger starts to affect the operations of trucks)
At 30 mph design speed the acceptable maximum is in the range of 7 to 12 %
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Properties of Vertical Curves
BVC
EVC
L
G2
G1
Change in grade: A = G2 - G1
where G is expressed as % (positive /, negative \)
For a crest curve, A is negative
For a sag curve, A is positive
L/2L/2
PI
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Properties of Vertical Curves
BVC
EVC
L
G2
G1
Rate of change of curvature: K = L / |A|
Which is a gentler curve - small K or large K?
L/2L/2
PI
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Properties of Vertical Curves
BVC
EVC
L
G2
G1
L/2L/2
Rate of change of grade: r = (g2 - g1) / L
where,
g is expressed as a ratio (positive /, negative \)
L is expressed in feet or meters
Note – K and r are both measuring the same characteristic of the curve
but in different ways
PI
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Properties of Vertical Curves
BVC
EVC
PI
L
G2
G1
Equation for determining the elevation at any point on the curve
y = y0 + g1x + 1/2 rx2
where,y0 = elevation at the BVC
g = grade expressed as a ratio
x = horizontal distance from BVC
r = rate of change of grade expressed as ratio
Elevation = y
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Properties of Vertical Curves
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Properties of Vertical Curves
BVC
EVC
PI
G2
G1
Example:
G1 = -1% G2 = +2%
Elevation of PI = 125.00 m
Station of EVC = 25+00
Station of PI = 24+00
Length of curve?
L/2 = Sta. EVC – Sta. PI
L/2 = 2500 m - 2400 m = 100 m
L = 200 m
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Properties of Vertical Curves
BVC
EVC
PI
G2
G1
Example:
G1 = -1% G2 = +2%
Elevation of PI = 125.00 m
Station of EVC = 25+00
Station of PI = 24+00
r - value?
r = (g2 - g1)/L
r = (0.02 - [-0.01])/200 m
r = 0.00015 / meter
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Properties of Vertical Curves
BVC
EVC
PI
G2
G1
Example:
G1 = -1% G2 = +2%
Elevation of PI = 125.00 m
Station of EVC = 25+00
Station of PI = 24+00
Station of low point?
x = -(g1/r)
x = -([-0.01] / [0.00015/m])
x = 66.67 m
Station = [23+00] + 67.67 m
Station 23+67
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Properties of Vertical Curves
BVC
EVC
PI
G2
G1
Example:
G1 = -1% G2 = +2%
Elevation of PI = 125.00 m
Station of EVC = 25+00
Station of PI = 24+00
Elevation at low point?
y = y0 + g1x + 1/2 rx2
y0 = Elev. BVC
Elev. BVC = Elev. PI - g1L/2
Elev. BVC = 125 m - [-0.01][100 m]
Elev. BVC = 126 m
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Properties of Vertical Curves
BVC
EVC
PI
G2
G1
Example:
G1 = -1% G2 = +2%
Elevation of PI = 125.00 m
Station of EVC = 25+00
Station of PI = 24+00
Elevation at low point?
y = y0 + g1x + 1/2 rx2
y = 126 m + [-0.01][66.67 m] + 1/2 [0.00015/m][66.67 m]2
y = 125.67 m
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Properties of Vertical Curves
BVC
EVC
PI
G2
G1
Example:
G1 = -1% G2 = +2%
Elevation of PI = 125.00 m
Station of EVC = 25+00
Station of PI = 24+00
Elevation at station 23+50?
y = 126 m + [-0.01][50 m] + 1/2 [0.00015/m][50 m]2
y = 125.69 m
Elevation at station 24+50?
y = 126 m + [-0.01][150 m] + 1/2 [0.00015/m][150 m]2
y = 126.19 m
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Design of Vertical Curves
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Design of Vertical Curves
The first step in the design is to determine the minimum length (or minimum K) for a given design speed.
Factors affecting the minimum length include
– Sufficient sight distance
– Driver comfort
– Appearance
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Design of Vertical Curves
Crest Vertical Curve
If sight distance requirements are satisfied then safety, comfort, and appearance requirements are also satisfied.
h1 = height of driver’s eyes, in ft h2 = height of object, in ft
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Design of Vertical Curves
Crest Vertical Curve
Lmin | A |S2
200 h1 h2 2 for S L
Equation relating sight distance to minimum length
From AASHTO:
h1 ≈ 3.5 ft
h2 ≈ 0.5 ft (stopping sight distance)
h3 ≈ 4.25 ft (passing sight distance)
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Design of Vertical Curves
Sag Vertical Curve
Stopping sight distance not an issue for sag vertical curves
Instead the design controls are one of the following
– Headlight sight distance
– Rider comfort
– Drainage
– Appearance
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Sag Vertical Curve
Check also:
• Comfort
– Change in grade, A
– Design Speed
• Appearance
– Change in grade, A
Design of Vertical Curves