Wind Load Calculators State Requirements ASCE 7 Resources

2D Ridge Topographic Effects

Interactive animation of wind flow over elongated ridges

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Overview
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Flat Terrain
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Escarpment
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2D Ridge
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3D Hill

Interactive Wind Load Animation

Use the controls to adjust wind speed, exposure category, and watch real-time wind particle flow

Understanding 2D Ridge Wind Loads

Two-dimensional ridges are elongated topographic features that create significant wind speed-up effects perpendicular to their long axis. Unlike isolated hills that affect wind from all directions, 2D ridges primarily amplify wind loads when wind flows perpendicular to the ridge crest. These features include mountain ridges, levees, long hills, and elevated terrain features where the length significantly exceeds the width, making them common in mountainous regions, coastal dune systems, and areas with linear geological formations.

What is a 2D Ridge?

In ASCE 7 terminology, a 2D (two-dimensional) ridge is a topographic feature with an elongated crest where the length is significantly greater than the width. The ridge slopes upward from both sides to a crest that runs in an approximately straight line for a considerable distance. The key distinction from a 3D hill is that wind approaching parallel to the ridge experiences minimal speed-up, while wind perpendicular to the ridge encounters maximum acceleration.

Defining Characteristics

ASCE 7 Requirements for 2D Ridges

ASCE 7 Section 26.8 provides specific guidance for 2D ridges, treating them similarly to escarpments but with different K1 values from Table 26.8-1. The methodology accounts for the two-dimensional nature of the feature.

ASCE 7 Ridge Criteria

2D Ridge topographic effects apply when ALL of the following are met:

  1. The ridge is isolated and unobstructed for 100H or 2 miles
  2. The ridge protrudes above upwind terrain features significantly
  3. The structure is in the speed-up region (typically 0 to 5H from crest)
  4. H/Lh ≥ 0.2 where H is ridge height and Lh is upwind distance to half-height
  5. Wind direction is within ±45° of perpendicular to ridge axis

Topographic Factor Calculation for Ridges

The topographic factor for 2D ridges uses the same general formula as escarpments but with different K1 values specific to ridge geometry:

Kzt Formula for 2D Ridges

Kzt = (1 + K1 K2 K3)²

K1 = shape factor for 2D ridges (Table 26.8-1)
K2 = horizontal distance factor
K3 = vertical height factor

Calculation Procedure

  1. Measure H - Height of ridge above upwind terrain
  2. Determine Lh - Horizontal distance upwind from crest to half-height point
  3. Calculate H/Lh - Confirm ≥ 0.2 to apply topographic effects
  4. Select K1 - Use 2D ridge values from ASCE 7 Table 26.8-1
  5. Determine K2 - Based on structure's position relative to crest (x/Lh)
  6. Calculate K3 - Based on height above local ground (z/Lh)
  7. Compute Kzt - Apply formula and use in velocity pressure calculations

Wind Direction Considerations

2D ridges have a critical directional component that affects when topographic factors apply:

Real-World Ridge Examples

Engineering Best Practices

Key Considerations for 2D Ridge Design:

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