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## Discharge (Q) when Velocity Approach (Va) is given Solution

STEP 0: Pre-Calculation Summary
Formula Used
discharge = Velocity*(Width of the Channel*Depth of Flow )
Q = v*(w*d)
This formula uses 3 Variables
Variables Used
Velocity - Velocity, in physics, is a vector quantity (it has both magnitude and direction), and is the time rate of change of position (of an object). (Measured in Meter per Second)
Width of the Channel - Width of the Channel is the dimension of the channel of MOSFET (Measured in Micrometer)
Depth of Flow - Depth of Flow of the discharge in the electro-magnetic method of stream flow measurements. (Measured in Meter)
STEP 1: Convert Input(s) to Base Unit
Velocity: 60 Meter per Second --> 60 Meter per Second No Conversion Required
Width of the Channel: 10 Micrometer --> 1E-05 Meter (Check conversion here)
Depth of Flow : 10 Meter --> 10 Meter No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Q = v*(w*d) --> 60*(1E-05*10)
Evaluating ... ...
Q = 0.006
STEP 3: Convert Result to Output's Unit
0.006 Meter³ per Second --> No Conversion Required
0.006 Meter³ per Second <-- Discharge
(Calculation completed in 00.031 seconds)

## < 11 Other formulas that you can solve using the same Inputs

Stokes Force
Archimedes Principle
archimedes_principle = Density*Acceleration Due To Gravity*Velocity Go
Angular Frequency (Using Velocity )
angular_frequency = (2*pi*Velocity)/Wavelength Go
Centripetal Force
Air Resistance Force
air_resistance = Air Constant*Velocity^2 Go
Wavelength Of The Wave(Using Velocity)
wavelength_wave = Velocity*Time Period Of Progressive Wave Go
Frequency Of Wavelength ( Using Velocity )
frequency = Velocity/Wavelength Of A Wave Go
Wave Number (Using Angular Frequency)
wave_number = Angular Frequency/Velocity Go
Kinetic Energy
kinetic_energy = (Mass*Velocity^2)/2 Go
Time Period (Using Velocity )
time_period = Wavelength/Velocity Go
Wavelength Of The Wave(Using Frequency)
wavelength = Velocity/frequency Go

## < 11 Other formulas that calculate the same Output

Discharge with velocity of approach
discharge = (2/3)*coefficient of discharging*Length*sqrt(2*[g])*(((initial height of liquid+final height of liquid)^1.5)-(final height of liquid^1.5)) Go
Discharge over rectangle weir for Bazin's formula with velocity approach
Discharge over rectangle weir with two end contractions
discharge = (2/3)*coefficient of discharging*(Length-(0.2*head of the liquid))*sqrt(2*[g])*(head of the liquid^1.5) Go
Discharge without velocity of approach
discharge = (2/3)*coefficient of discharging*Length*sqrt(2*[g])*(initial height of liquid^1.5) Go
Discharge over rectangle weir considering Bazin's formula
Discharge over rectangle weir considering Francis's formula
discharge = 1.84*Length*(((initial height of liquid+final height of liquid)^1.5)-(final height of liquid^1.5)) Go
Discharge from Manning's equation
discharge = (1/Manning’s Roughness Coefficient)*Cross sectional area*hydraulic radius^2/3*Bed Slope^1/2 Go
discharge = 1.705*coefficient of discharging*Length*(head of the liquid^1.5) Go
Discharge during retraction
discharge = Velocity*(Area of piston-Area of piston rod) Go
Discharge during extension
discharge = Velocity*Area of piston Go

### Discharge (Q) when Velocity Approach (Va) is given Formula

discharge = Velocity*(Width of the Channel*Depth of Flow )
Q = v*(w*d)

## What is Velocity of Approach?

The Velocity Approach (Va) is defined as the rate of change of relative displacement between two bodies (i.e. how fast a body approaches another body ).

## How to Calculate Discharge (Q) when Velocity Approach (Va) is given?

Discharge (Q) when Velocity Approach (Va) is given calculator uses discharge = Velocity*(Width of the Channel*Depth of Flow ) to calculate the Discharge, The Discharge (Q) when Velocity Approach (Va) is given is the volumetric flow rate of water that is transported through a given cross-sectional area. Discharge and is denoted by Q symbol.

How to calculate Discharge (Q) when Velocity Approach (Va) is given using this online calculator? To use this online calculator for Discharge (Q) when Velocity Approach (Va) is given, enter Velocity (v), Width of the Channel (w) and Depth of Flow (d) and hit the calculate button. Here is how the Discharge (Q) when Velocity Approach (Va) is given calculation can be explained with given input values -> 0.006 = 60*(1E-05*10).

### FAQ

What is Discharge (Q) when Velocity Approach (Va) is given?
The Discharge (Q) when Velocity Approach (Va) is given is the volumetric flow rate of water that is transported through a given cross-sectional area and is represented as Q = v*(w*d) or discharge = Velocity*(Width of the Channel*Depth of Flow ). Velocity, in physics, is a vector quantity (it has both magnitude and direction), and is the time rate of change of position (of an object). , Width of the Channel is the dimension of the channel of MOSFET and Depth of Flow of the discharge in the electro-magnetic method of stream flow measurements.
How to calculate Discharge (Q) when Velocity Approach (Va) is given?
The Discharge (Q) when Velocity Approach (Va) is given is the volumetric flow rate of water that is transported through a given cross-sectional area is calculated using discharge = Velocity*(Width of the Channel*Depth of Flow ). To calculate Discharge (Q) when Velocity Approach (Va) is given, you need Velocity (v), Width of the Channel (w) and Depth of Flow (d). With our tool, you need to enter the respective value for Velocity, Width of the Channel and Depth of Flow and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Discharge?
In this formula, Discharge uses Velocity, Width of the Channel and Depth of Flow . We can use 11 other way(s) to calculate the same, which is/are as follows -
• discharge = Velocity*Area of piston
• discharge = Velocity*(Area of piston-Area of piston rod)
• discharge = (2/3)*coefficient of discharging*Length*sqrt(2*[g])*(((initial height of liquid+final height of liquid)^1.5)-(final height of liquid^1.5))
• discharge = (2/3)*coefficient of discharging*Length*sqrt(2*[g])*(initial height of liquid^1.5)
• discharge = (1/Manning’s Roughness Coefficient)*Cross sectional area*hydraulic radius^2/3*Bed Slope^1/2
• discharge = 1.84*Length*(((initial height of liquid+final height of liquid)^1.5)-(final height of liquid^1.5))