Maximum flood current given friction factor for propagation velocity of tide wave Solution

STEP 0: Pre-Calculation Summary
Formula Used
Maximum Flood Current = (6*pi^2*Chezy's constant^2*Average Depth*tan(Friction Factor in Terms of Degree/0.5))/(Tidal Period*8*[g])
Vmax = (6*pi^2*C^2*h'*tan(Θf/0.5))/(T*8*[g])
This formula uses 2 Constants, 1 Functions, 5 Variables
Constants Used
[g] - Gravitational acceleration on Earth Value Taken As 9.80665
pi - Archimedes' constant Value Taken As 3.14159265358979323846264338327950288
Functions Used
tan - The tangent of an angle is a trigonometric ratio of the length of the side opposite an angle to the length of the side adjacent to an angle in a right triangle., tan(Angle)
Variables Used
Maximum Flood Current - (Measured in Cubic Meter per Second) - Maximum Flood Current influencing the friction factor.
Chezy's constant - The Chezy's constant is a dimensionless quantity that can be calculated by three formulas, namely: Bazin Formula. Ganguillet -Kutter Formula. Manning's Formula.
Average Depth - (Measured in Meter) - Average Depth influencing the propagation velocity of the tide wave.
Friction Factor in Terms of Degree - (Measured in Radian) - Friction factor in terms of degree is the measure of resistance of fluid flow in terms of degree.
Tidal Period - (Measured in Second) - Tidal Period is an efficient way of guesstimating how much water there is, at any given time of day, over a particular point.
STEP 1: Convert Input(s) to Base Unit
Chezy's constant: 15 --> No Conversion Required
Average Depth: 26 Meter --> 26 Meter No Conversion Required
Friction Factor in Terms of Degree: 30 Degree --> 0.5235987755982 Radian (Check conversion here)
Tidal Period: 130 Second --> 130 Second No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Vmax = (6*pi^2*C^2*h'*tan(Θf/0.5))/(T*8*[g]) --> (6*pi^2*15^2*26*tan(0.5235987755982/0.5))/(130*8*[g])
Evaluating ... ...
Vmax = 58.8319812803911
STEP 3: Convert Result to Output's Unit
58.8319812803911 Cubic Meter per Second --> No Conversion Required
FINAL ANSWER
58.8319812803911 58.83198 Cubic Meter per Second <-- Maximum Flood Current
(Calculation completed in 00.020 seconds)

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7 River Navigation Calculators

Chezy's friction factor given friction factor for propagation velocity of tide wave
Go Chezy's constant = sqrt((Tidal Period*8*[g]*Maximum Flood Current)/(6*pi^2*Average Depth*tan(Friction Factor in Terms of Degree/0.5)))
Tidal period for friction factor and propagation velocity of tide wave
Go Tidal Period = (6*(pi^2)*(Chezy's constant^2)*Average Depth*tan(Friction Factor in Terms of Degree/0.5))/(8*[g]*Maximum Flood Current)
Maximum flood current given friction factor for propagation velocity of tide wave
Go Maximum Flood Current = (6*pi^2*Chezy's constant^2*Average Depth*tan(Friction Factor in Terms of Degree/0.5))/(Tidal Period*8*[g])
Average depth given friction factor for propagation velocity of tide wave
Go Average Depth = (Tidal Period*8*[g]*Maximum Flood Current)/(6*pi^2*Chezy's constant^2*tan(Friction Factor in Terms of Degree/0.5))
Friction factor for propagation velocity of tide wave
Go Friction Factor in Terms of Degree = 0.5*atan(Tidal Period*8*[g]*Maximum Flood Current/(6*pi^2*Chezy's constant^2*Average Depth))
Propagation velocity of tide wave
Go Wave Speed = sqrt([g]*Average Depth*(1-tan(Friction Factor in Terms of Degree)^2))
Average depth given propagation velocity of tide wave
Go Average Depth = Wave Speed^2/([g]*(1-tan(Friction Factor in Terms of Degree)^2))

Maximum flood current given friction factor for propagation velocity of tide wave Formula

Maximum Flood Current = (6*pi^2*Chezy's constant^2*Average Depth*tan(Friction Factor in Terms of Degree/0.5))/(Tidal Period*8*[g])
Vmax = (6*pi^2*C^2*h'*tan(Θf/0.5))/(T*8*[g])

What is River Navigation?

When a stretch of river is made navigable, a lock is sometimes required to bypass an obstruction such as a rapid, dam, or mill weir – because of the change in river level across the obstacle.
In large scale river navigation improvements, weirs and locks are used together. A weir will increase the depth of a shallow stretch, and the required lock will either be built in a gap in the weir, or at the downstream end of an artificial cut which bypasses the weir and perhaps a shallow stretch of river below it. A river improved by these means is often called a Waterway or River Navigation.

How to Calculate Maximum flood current given friction factor for propagation velocity of tide wave?

Maximum flood current given friction factor for propagation velocity of tide wave calculator uses Maximum Flood Current = (6*pi^2*Chezy's constant^2*Average Depth*tan(Friction Factor in Terms of Degree/0.5))/(Tidal Period*8*[g]) to calculate the Maximum Flood Current, Maximum flood current given friction factor for propagation velocity of tide wave is defined as parameter influencing prediction of water depth at each shallow channel reach at time of arrival of ship. Maximum Flood Current is denoted by Vmax symbol.

How to calculate Maximum flood current given friction factor for propagation velocity of tide wave using this online calculator? To use this online calculator for Maximum flood current given friction factor for propagation velocity of tide wave, enter Chezy's constant (C), Average Depth (h'), Friction Factor in Terms of Degree f) & Tidal Period (T) and hit the calculate button. Here is how the Maximum flood current given friction factor for propagation velocity of tide wave calculation can be explained with given input values -> 58.83198 = (6*pi^2*15^2*26*tan(0.5235987755982/0.5))/(130*8*[g]).

FAQ

What is Maximum flood current given friction factor for propagation velocity of tide wave?
Maximum flood current given friction factor for propagation velocity of tide wave is defined as parameter influencing prediction of water depth at each shallow channel reach at time of arrival of ship and is represented as Vmax = (6*pi^2*C^2*h'*tan(Θf/0.5))/(T*8*[g]) or Maximum Flood Current = (6*pi^2*Chezy's constant^2*Average Depth*tan(Friction Factor in Terms of Degree/0.5))/(Tidal Period*8*[g]). The Chezy's constant is a dimensionless quantity that can be calculated by three formulas, namely: Bazin Formula. Ganguillet -Kutter Formula. Manning's Formula, Average Depth influencing the propagation velocity of the tide wave, Friction factor in terms of degree is the measure of resistance of fluid flow in terms of degree & Tidal Period is an efficient way of guesstimating how much water there is, at any given time of day, over a particular point.
How to calculate Maximum flood current given friction factor for propagation velocity of tide wave?
Maximum flood current given friction factor for propagation velocity of tide wave is defined as parameter influencing prediction of water depth at each shallow channel reach at time of arrival of ship is calculated using Maximum Flood Current = (6*pi^2*Chezy's constant^2*Average Depth*tan(Friction Factor in Terms of Degree/0.5))/(Tidal Period*8*[g]). To calculate Maximum flood current given friction factor for propagation velocity of tide wave, you need Chezy's constant (C), Average Depth (h'), Friction Factor in Terms of Degree f) & Tidal Period (T). With our tool, you need to enter the respective value for Chezy's constant, Average Depth, Friction Factor in Terms of Degree & Tidal Period and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
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