Point Measurement of Maximum Velocity Calculator

✖Max Velocity averaged Over Inlet Cross Section entirely [length/time] depends on point measurement of maximum velocity, hydraulic radius and depth of water at current meter location.ⓘ Max Velocity averaged Over Inlet Cross Section [V_avg]			+10% -10%
✖The Hydraulic Radius is the ratio of the cross-sectional area of a channel or pipe in which a fluid flows to the conduit's wet perimeter.ⓘ Hydraulic Radius [r_H]			+10% -10%
✖Depth of Water at Current Meter Location [length] where current meter is used to measure water velocity at predetermined points.ⓘ Depth of Water at Current Meter Location [D]			+10% -10%

✖Point measurement of Maximum Velocity [length/time] depends on max velocity averaged over inlet cross section, hydraulic radius and depth of water at current meter location.ⓘ Point Measurement of Maximum Velocity [V_meas]

⎘ Copy

👎

Formula

✖

Point Measurement of Maximum Velocity

Formula

`"V"_{"meas"} = "V"_{"avg"}/("r"_{"H"}/"D")^(2/3)`

Example

`"25.33778m/s"="3m/s"/("0.33m"/"8.1m")^(2/3)`

Calculator

LaTeX

Reset

👍

Download Hydrodynamics of Tidal Inlets-2 Formulas PDF PDF Image

Point Measurement of Maximum Velocity Solution

STEP 0: Pre-Calculation Summary

Formula Used

Point Measurement of Maximum Velocity = Max Velocity averaged Over Inlet Cross Section/(Hydraulic Radius/Depth of Water at Current Meter Location)^(2/3)
V_meas = V_avg/(r_H/D)^(2/3)
This formula uses 4 Variables

Variables Used

Point Measurement of Maximum Velocity - (Measured in Meter per Second) - Point measurement of Maximum Velocity [length/time] depends on max velocity averaged over inlet cross section, hydraulic radius and depth of water at current meter location.
Max Velocity averaged Over Inlet Cross Section - (Measured in Meter per Second) - Max Velocity averaged Over Inlet Cross Section entirely [length/time] depends on point measurement of maximum velocity, hydraulic radius and depth of water at current meter location.
Hydraulic Radius - (Measured in Meter) - The Hydraulic Radius is the ratio of the cross-sectional area of a channel or pipe in which a fluid flows to the conduit's wet perimeter.
Depth of Water at Current Meter Location - (Measured in Meter) - Depth of Water at Current Meter Location [length] where current meter is used to measure water velocity at predetermined points.

STEP 1: Convert Input(s) to Base Unit

Max Velocity averaged Over Inlet Cross Section: 3 Meter per Second --> 3 Meter per Second No Conversion Required
Hydraulic Radius: 0.33 Meter --> 0.33 Meter No Conversion Required
Depth of Water at Current Meter Location: 8.1 Meter --> 8.1 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

V_meas = V_avg/(r_H/D)^(2/3) --> 3/(0.33/8.1)^(2/3)

Evaluating ... ...

V_meas = 25.3377846521108

STEP 3: Convert Result to Output's Unit

25.3377846521108 Meter per Second --> No Conversion Required

FINAL ANSWER

25.3377846521108 ≈ 25.33778 Meter per Second <-- Point Measurement of Maximum Velocity

(Calculation completed in 00.004 seconds)

You are here -

Home » Engineering » Civil » Coastal and Ocean Engineering » Hydrodynamics of Tidal Inlets-2 » Hydrodynamic and Sediment Interaction at Tidal Inlets » Tidal Prism » Point Measurement of Maximum Velocity

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 M Naveen

National Institute of Technology (NIT), Warangal

M Naveen has verified this Calculator and 900+ more calculators!

< 18 Tidal Prism Calculators

Maximum Cross-Sectionally Averaged Velocity given Tidal Prism of Non-sinusoidal Prototype Flow

Go Maximum Cross Sectional Average Velocity = (Tidal Prism Filling Bay*pi*Keulegan Constant for Non-sinusoidal Character)/(Tidal Duration*Average Area over the Channel Length)

Tidal Period when Tidal Prism Accounting for Non-sinusoidal Prototype Flow by Keulegan

Go Tidal Duration = (Tidal Prism Filling Bay*pi*Keulegan Constant for Non-sinusoidal Character)/(Maximum Cross Sectional Average Velocity*Average Area over the Channel Length)

Average Area over Channel Length given Tidal Prism of Non-Sinusoidal Prototype Flow

Go Average Area over the Channel Length = (Tidal Prism Filling Bay*pi*Keulegan Constant for Non-sinusoidal Character)/(Tidal Duration*Maximum Cross Sectional Average Velocity)

Tidal Prism Filling Bay Accounting for Non-sinusoidal Prototype Flow by Keulegan

Go Tidal Prism Filling Bay = (Tidal Duration*Maximum Instantaneous Ebb Tide Discharge)/(pi*Keulegan Constant for Non-sinusoidal Character)

Maximum Ebb Tide Discharge Accounting for Non-Sinusoidal Character of Prototype Flow by Keulegan

Go Maximum Instantaneous Ebb Tide Discharge = (Tidal Prism Filling Bay*pi*Keulegan Constant for Non-sinusoidal Character)/Tidal Duration

Tidal Period Accounting for Non-sinusoidal Character of Prototype Flow by Keulegan

Go Tidal Duration = (Tidal Prism Filling Bay*pi*Keulegan Constant for Non-sinusoidal Character)/Maximum Instantaneous Ebb Tide Discharge

Tidal Prism for Non-sinusoidal character of Prototype Flow by Keulegan

Go Tidal Prism Filling Bay = Tidal Duration*Maximum Instantaneous Ebb Tide Discharge/(pi*Keulegan Constant for Non-sinusoidal Character)

Maximum Cross-Sectionally Averaged Velocity during Tidal Cycle given Tidal Prism

Go Maximum Cross Sectional Average Velocity = (Tidal Prism Filling Bay*pi)/(Tidal Duration*Average Area over the Channel Length)

Tidal Period given Maximum Cross-sectionally Averaged Velocity and Tidal Prism

Go Tidal Duration = (Tidal Prism Filling Bay*pi)/(Maximum Cross Sectional Average Velocity*Average Area over the Channel Length)

Average Area over Channel Length given Tidal Prism

Go Average Area over the Channel Length = (Tidal Prism Filling Bay*pi)/(Tidal Duration*Maximum Cross Sectional Average Velocity)

Tidal Prism given Average Area over Channel Length

Go Tidal Prism Filling Bay = (Tidal Duration*Maximum Cross Sectional Average Velocity*Average Area over the Channel Length)/pi

Maximum Velocity Averaged over Entire Cross-Section

Go Max Velocity averaged Over Inlet Cross Section = Point Measurement of Maximum Velocity*(Hydraulic Radius/Depth of Water at Current Meter Location)^(2/3)

Hydraulic Radius of Entire Cross-Section

Go Hydraulic Radius = Depth of Water at Current Meter Location*(Max Velocity averaged Over Inlet Cross Section/Point Measurement of Maximum Velocity)^(3/2)

Depth of Water at Current Meter Location

Go Depth of Water at Current Meter Location = Hydraulic Radius/(Max Velocity averaged Over Inlet Cross Section/Point Measurement of Maximum Velocity)^(3/2)

Point Measurement of Maximum Velocity

Go Point Measurement of Maximum Velocity = Max Velocity averaged Over Inlet Cross Section/(Hydraulic Radius/Depth of Water at Current Meter Location)^(2/3)

Tidal Period given Maximum Instantaneous Ebb Tide Discharge and Tidal Prism

Go Tidal Duration = (Tidal Prism Filling Bay*pi)/Maximum Instantaneous Ebb Tide Discharge

Maximum Instantaneous Ebb Tide Discharge given Tidal Prism

Go Maximum Instantaneous Ebb Tide Discharge = Tidal Prism Filling Bay*pi/Tidal Duration

Tidal Prism filling Bay given Maximum Ebb Tide Discharge

Go Tidal Prism Filling Bay = Tidal Duration*Maximum Instantaneous Ebb Tide Discharge/pi

Point Measurement of Maximum Velocity Formula

Point Measurement of Maximum Velocity = Max Velocity averaged Over Inlet Cross Section/(Hydraulic Radius/Depth of Water at Current Meter Location)^(2/3)
V_meas = V_avg/(r_H/D)^(2/3)

What is Inlet Flow Patterns?

An Inlet has a "gorge" where flows converge before they expand again on the opposite side. Shoal (shallow) areas that extend bayward and oceanward from the gorge depend on inlet hydraulics, wave conditions, and general geomorphology. All these interact to determine flow patterns in and around the inlet and locations where flow channels occur.

What is Tidal Prism?

A Tidal Prism is the volume of water in an estuary or inlet between mean high tide and mean low tide, or the volume of water leaving an estuary at ebb tide. It can also be thought of as the volume of the incoming tide plus the river discharge.

How to Calculate Point Measurement of Maximum Velocity?

Point Measurement of Maximum Velocity calculator uses Point Measurement of Maximum Velocity = Max Velocity averaged Over Inlet Cross Section/(Hydraulic Radius/Depth of Water at Current Meter Location)^(2/3) to calculate the Point Measurement of Maximum Velocity, The Point Measurement of Maximum Velocity formula is defined as a parameter that recommends ways to relate point measurements of maximum velocity in the center of the channel to velocities representative of the entire inlet. Point Measurement of Maximum Velocity is denoted by V_meas symbol.

How to calculate Point Measurement of Maximum Velocity using this online calculator? To use this online calculator for Point Measurement of Maximum Velocity, enter Max Velocity averaged Over Inlet Cross Section (V_avg), Hydraulic Radius (r_H) & Depth of Water at Current Meter Location (D) and hit the calculate button. Here is how the Point Measurement of Maximum Velocity calculation can be explained with given input values -> 25.33778 = 3/(0.33/8.1)^(2/3).

FAQ

What is Point Measurement of Maximum Velocity?

The Point Measurement of Maximum Velocity formula is defined as a parameter that recommends ways to relate point measurements of maximum velocity in the center of the channel to velocities representative of the entire inlet and is represented as V_meas = V_avg/(r_H/D)^(2/3) or Point Measurement of Maximum Velocity = Max Velocity averaged Over Inlet Cross Section/(Hydraulic Radius/Depth of Water at Current Meter Location)^(2/3). Max Velocity averaged Over Inlet Cross Section entirely [length/time] depends on point measurement of maximum velocity, hydraulic radius and depth of water at current meter location, The Hydraulic Radius is the ratio of the cross-sectional area of a channel or pipe in which a fluid flows to the conduit's wet perimeter & Depth of Water at Current Meter Location [length] where current meter is used to measure water velocity at predetermined points.

How to calculate Point Measurement of Maximum Velocity?

The Point Measurement of Maximum Velocity formula is defined as a parameter that recommends ways to relate point measurements of maximum velocity in the center of the channel to velocities representative of the entire inlet is calculated using Point Measurement of Maximum Velocity = Max Velocity averaged Over Inlet Cross Section/(Hydraulic Radius/Depth of Water at Current Meter Location)^(2/3). To calculate Point Measurement of Maximum Velocity, you need Max Velocity averaged Over Inlet Cross Section (V_avg), Hydraulic Radius (r_H) & Depth of Water at Current Meter Location (D). With our tool, you need to enter the respective value for Max Velocity averaged Over Inlet Cross Section, Hydraulic Radius & Depth of Water at Current Meter Location 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