HCF calculator

Maximum Horizontal Velocity at Node Calculator

Engineering Chemistry Financial Health More >>

↳

Civil Chemical Engineering Electrical Electronics More >>

⤿

Coastal and Ocean Engineering Bridge and Suspension Cable Columns Concrete Formulas More >>

⤿

Surf Zone Hydrodynamics Calculation of Forces on Ocean Structures Density Currents in Harbors Density Currents in Rivers More >>

⤿

Harbor Hydrodynamics Methods to Predict Channel Shoaling Nearshore Currents Surf Zone Waves More >>

⤿

Harbor Oscillations Important Formulas of Harbor Oscillation Mooring Reflection from Structures More >>

⤿

Flushing or Circulation Processes and Vessel Interactions Free Oscillation Period Open and Closed Basins

✖Standing Wave Height of Ocean results when two equal waves are going in opposite direction.ⓘ Standing Wave Height of Ocean [H_w]			+10% -10%
✖Depth of Water is the depth as measured from the water level to the bottom of the considered water body.ⓘ Depth of Water [D_w]			+10% -10%

✖Maximum Horizontal Velocity at a Node refers to the highest velocity component in the horizontal direction at that particular node in a fluid flow simulation.ⓘ Maximum Horizontal Velocity at Node [V_max]

⎘ Copy

👎

Formula

LaTeX

Reset

👍

Download Surf Zone Hydrodynamics Formula PDF PDF Image

Maximum Horizontal Velocity at Node Solution

STEP 0: Pre-Calculation Summary

Formula Used

Maximum Horizontal Velocity at a Node = (Standing Wave Height of Ocean/2)*sqrt([g]/Depth of Water)
V_max = (H_w/2)*sqrt([g]/D_w)
This formula uses 1 Constants, 1 Functions, 3 Variables

Constants Used

[g] - Gravitational acceleration on Earth Value Taken As 9.80665

Functions Used

sqrt - A square root function is a function that takes a non-negative number as an input and returns the square root of the given input number., sqrt(Number)

Variables Used

Maximum Horizontal Velocity at a Node - (Measured in Meter per Second) - Maximum Horizontal Velocity at a Node refers to the highest velocity component in the horizontal direction at that particular node in a fluid flow simulation.
Standing Wave Height of Ocean - (Measured in Meter) - Standing Wave Height of Ocean results when two equal waves are going in opposite direction.
Depth of Water - (Measured in Meter) - Depth of Water is the depth as measured from the water level to the bottom of the considered water body.

STEP 1: Convert Input(s) to Base Unit

Standing Wave Height of Ocean: 1.01 Meter --> 1.01 Meter No Conversion Required
Depth of Water: 105.4 Meter --> 105.4 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

V_max = (H_w/2)*sqrt([g]/D_w) --> (1.01/2)*sqrt([g]/105.4)

Evaluating ... ...

V_max = 0.154039255336213

STEP 3: Convert Result to Output's Unit

0.154039255336213 Meter per Second -->554.541319210368 Meter per Hour (Check conversion here)

FINAL ANSWER

554.541319210368 ≈ 554.5413 Meter per Hour <-- Maximum Horizontal Velocity at a Node

(Calculation completed in 00.021 seconds)

You are here -

Home » Engineering » Civil » Coastal and Ocean Engineering » Surf Zone Hydrodynamics » Harbor Hydrodynamics » Harbor Oscillations » Maximum Horizontal Velocity at Node

Credits

Created by Mithila Muthamma PA

Coorg Institute of Technology (CIT), Coorg

Mithila Muthamma PA has created this Calculator and 2000+ more calculators!

Verified by Chandana P Dev

NSS College of Engineering (NSSCE), Palakkad

Chandana P Dev has verified this Calculator and 1700+ more calculators!

< Harbor Oscillations Calculators

Period for Fundamental Mode

LaTeX Go Natural Free Oscillating Period of a Basin = (4*Length of Basin along Axis)/sqrt([g]*Water Depth at Harbor)

Basin Length along axis given Maximum Oscillation Period corresponding to Fundamental Mode

LaTeX Go Length of Basin along Axis = Maximum Oscillation Period*sqrt([g]*Water Depth)/2

Maximum Oscillation Period corresponding to Fundamental Mode

LaTeX Go Maximum Oscillation Period = 2*Length of Basin along Axis/sqrt([g]*Water Depth)

Water Depth given Maximum Oscillation Period corresponding to Fundamental Mode

LaTeX Go Water Depth at Harbor = (2*Length of Basin along Axis/Natural Free Oscillating Period of a Basin)^2/[g]

< Important Formulas of Harbor Oscillation Calculators

Resonant Period for Helmholtz Mode

LaTeX Go Resonant Period for Helmholtz Mode = (2*pi)*sqrt((Channel Length (Helmholtz Mode)+Additional Length of the Channel)*Surface Area of Bay/([g]*Cross Sectional Area))

Standing Wave Height given Maximum Horizontal Velocity at Node

LaTeX Go Standing Wave Height of Ocean = (Maximum Horizontal Velocity at a Node/sqrt([g]/Depth of Water))*2

Maximum Horizontal Velocity at Node

LaTeX Go Maximum Horizontal Velocity at a Node = (Standing Wave Height of Ocean/2)*sqrt([g]/Depth of Water)

Water Depth given Maximum Horizontal Velocity at Node

LaTeX Go Depth of Water = [g]/(Maximum Horizontal Velocity at a Node/(Standing Wave Height of Ocean/2))^2

Maximum Horizontal Velocity at Node Formula

LaTeX Go

Maximum Horizontal Velocity at a Node = (Standing Wave Height of Ocean/2)*sqrt([g]/Depth of Water)
V_max = (H_w/2)*sqrt([g]/D_w)

What are Open Basins?

Open Basins are Exorheic, or open lakes drain into a river, or other body of water that ultimately drains into the ocean.

What are Closed Basins?

Enclosed basins can experience oscillations due to a variety of causes. Lake oscillations are usually the result of a sudden change, or a series of intermittent-periodic changes, in atmospheric pressure or wind velocity. Oscillations in canals can be initiated by suddenly adding or subtracting large quantities of water. Harbor oscillations are usually initiated by forcing through the entrance; hence, they deviate from a true closed basin. Local seismic activity can also create oscillations in an enclosed basin.

How to Calculate Maximum Horizontal Velocity at Node?

Maximum Horizontal Velocity at Node calculator uses Maximum Horizontal Velocity at a Node = (Standing Wave Height of Ocean/2)*sqrt([g]/Depth of Water) to calculate the Maximum Horizontal Velocity at a Node, The Maximum Horizontal Velocity at Node formula is defined as the highest velocity component in the horizontal direction at that particular node in a fluid flow simulation. Maximum Horizontal Velocity at a Node is denoted by V_max symbol.

How to calculate Maximum Horizontal Velocity at Node using this online calculator? To use this online calculator for Maximum Horizontal Velocity at Node, enter Standing Wave Height of Ocean (H_w) & Depth of Water (D_w) and hit the calculate button. Here is how the Maximum Horizontal Velocity at Node calculation can be explained with given input values -> 2E+6 = (1.01/2)*sqrt([g]/105.4).

FAQ

What is Maximum Horizontal Velocity at Node?

The Maximum Horizontal Velocity at Node formula is defined as the highest velocity component in the horizontal direction at that particular node in a fluid flow simulation and is represented as V_max = (H_w/2)*sqrt([g]/D_w) or Maximum Horizontal Velocity at a Node = (Standing Wave Height of Ocean/2)*sqrt([g]/Depth of Water). Standing Wave Height of Ocean results when two equal waves are going in opposite direction & Depth of Water is the depth as measured from the water level to the bottom of the considered water body.

How to calculate Maximum Horizontal Velocity at Node?

The Maximum Horizontal Velocity at Node formula is defined as the highest velocity component in the horizontal direction at that particular node in a fluid flow simulation is calculated using Maximum Horizontal Velocity at a Node = (Standing Wave Height of Ocean/2)*sqrt([g]/Depth of Water). To calculate Maximum Horizontal Velocity at Node, you need Standing Wave Height of Ocean (H_w) & Depth of Water (D_w). With our tool, you need to enter the respective value for Standing Wave Height of Ocean & Depth of Water and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

Home

FREE PDFs

🔍 Search