Step 3b_ Select Riprap Coefficient Parameters

The riprap equation has several empirical coefficients or coefficient equations that the riprap calculator selects based on user options in the Edit Ribbon:

These options translate into the following equation coefficients, equations, and parameters in the d₃₀ calculation described in the next section:

These parameters and equations will be discussed in more detail in the next section on the d₃₀ calculations, but are briefly described below:
Channel Type: Choose Natural for a non-engineered channel with native materials in the bed and banks and some bank vegetation. Chose Trapezoidal for an engineered channel. The riprap calculator will choose the equation to compute the side slope velocity based on this selection. The calculator will generally compute higher side slope velocities for trapezoidal channels for all observed bends (R/W>1).
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Rock Type: The Stability Coefficient (C_s) was the original coefficient in the riprap equation. This is a linear coefficient in the equation, and is 0.3 for rounded rock (e.g. natural river stone and cobbles) and 0.375 for angular rock (e.g. riprap).
Warning: Community partners, project biologists, and landscape architects will often advocate for rounded river rock instead of riprap because it is aesthetically appealing. It is important to make a careful cost-benefit analysis and carefully account for rock type in the stability analysis. According to this equation, rounded rock must be 25% larger and 100% heavier (weight increases to the cube power of size) to provide comparable protection.
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Site Alignment: The riprap calculator will also require a larger d₃₀ if the site alignment deviates from a straight channel. This option selects the Vertical Velocity Distribution Coefficient (C_v) in the riprap equation, which is 1 for straight channels and 1.25 for locations where the channel transitions Images?
from an engineered section to an un-protected section (downstream of a concrete lining or the end of a dike. At the outside of the bend, it computes the Cv coefficient based on the logarithm of the R/W ratio:
Cv=1.283-0.2logRW
This value falls between 1 and 1.22 for 2<R/W<25. If R/W>25 the equation computes C_v less than 1, but the Riprap Calculator enforces a minimum value of C_v=1.
K1 Method: The riprap equation incudes a Side Slope Correction Factor (K₁). This factor is in the denominator of the Maynord equation and is a function of a trigonometric function of the side slope angle (), making the rock size directly related side slope (e.g. steeper slopes require larger rock).
Early approaches used a relationship between the side slope angle and the angle of repose from Carter, Carleson, and Lane (1953):
K1=1-sin2θsin2∅
This is the Analytical Approach in the riprap calculator.
But the USACE Manual of Practice (EM 1110-2-1601) follows Maynord (1988), who found this relationship too conservative, and unhelpfully dependent on the angle of repose – which is uncertain. Therefore, they recommended, USACE, approach selects K₁ based on a recommended curve from Plate 39 in EM 1110-2-1601:

Note: Increasing the side slope has a direct, gravitational, impact on side slope rock size. But the K₁ factor is also included in the bed size equation. This effect is less direct.