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Total Vertical Force when Vertical Normal Stress at upstream face is Given Solution

STEP 0: Pre-Calculation Summary
Formula Used
vertical_force = Maximum Normal Stress/((1/(144*Breadth))*(1-((6*Eccentricity)/Breadth)))
Fv = σn-max/((1/(144*b))*(1-((6*e)/b)))
This formula uses 3 Variables
Variables Used
Maximum Normal Stress - The Maximum Normal Stress Value (Measured in Megapascal)
Breadth - Breadth is the measurement or extent of something from side to side. (Measured in Meter)
Eccentricity - Eccentricity of an ellipse is a non-negative real number that uniquely characterizes its shape. (Measured in Centimeter)
STEP 1: Convert Input(s) to Base Unit
Maximum Normal Stress: 10 Megapascal --> 10000000 Pascal (Check conversion here)
Breadth: 2 Meter --> 2 Meter No Conversion Required
Eccentricity: 10 Centimeter --> 0.1 Meter (Check conversion here)
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Fv = σn-max/((1/(144*b))*(1-((6*e)/b))) --> 10000000/((1/(144*2))*(1-((6*0.1)/2)))
Evaluating ... ...
Fv = 4114285714.28572
STEP 3: Convert Result to Output's Unit
4114285714.28572 Newton --> No Conversion Required
FINAL ANSWER
4114285714.28572 Newton <-- Vertical component of force
(Calculation completed in 00.031 seconds)

11 Other formulas that you can solve using the same Inputs

Surface Area of Cuboid
surface_area = 2*((Length*Height)+(Height*Breadth)+(Length*Breadth)) Go
Diagonal of a Rectangle when breadth and perimeter are given
diagonal = sqrt((2*(Breadth)^2)-(Perimeter*Breadth)+((Perimeter)^2/4)) Go
Magnetic Flux
magnetic_flux = Magnetic Field*Length*Breadth*cos(θ) Go
Diagonal of a Rectangle when breadth and area are given
diagonal = sqrt(((Area)^2/(Breadth)^2)+(Breadth)^2) Go
Area of a Rectangle when breadth and diagonal are given
area = Breadth*(sqrt((Diagonal)^2-(Breadth)^2)) Go
Area of a Rectangle when breadth and perimeter are given
area = (Perimeter*(Breadth/2))-(Breadth)^2 Go
Diagonal of a Rectangle when length and breadth are given
diagonal = sqrt(Length^2+Breadth^2) Go
Length of rectangle when diagonal and breadth are given
length = sqrt(Diagonal^2-Breadth^2) Go
Length of rectangle when perimeter and breadth are given
length = (Perimeter-2*Breadth)/2 Go
Area of a Rectangle when length and breadth are given
area = Length*Breadth Go
Length of rectangle when area and breadth are given
length = Area/Breadth Go

5 Other formulas that calculate the same Output

Vertical Upward Force on Piston when Piston Velocity is Given
vertical_force = Length*pi*Dynamic viscosity*Velocity of piston*(0.75*((Diameter/Clearance)^3)+1.5*((Diameter/Clearance)^2)) Go
Total Vertical Force when Vertical Normal Stress at downstream face is Given
vertical_force = Maximum Normal Stress/((1/(144*Breadth))*(1+((6*Eccentricity)/Breadth))) Go
Vertical Upward Force on Piston
vertical_force = Velocity of piston*0.25*pi*Diameter*Diameter Go
Resolution of force with angle (θ) along vertical direction
vertical_force = Force*sin(Angle) Go
Vertical Force when Total Force is Given
vertical_force = Force-Shear Force Go

Total Vertical Force when Vertical Normal Stress at upstream face is Given Formula

vertical_force = Maximum Normal Stress/((1/(144*Breadth))*(1-((6*Eccentricity)/Breadth)))
Fv = σn-max/((1/(144*b))*(1-((6*e)/b)))

What is safe bearing capacity of the soil ?

Safe bearing capacity of soil field test is done to check the capacity of the soil to withstand loads .The maximum load per unit area which the soil can bear without any displacement or settlements is designated as the “Safe bearing capacity of the soil.”

How to Calculate Total Vertical Force when Vertical Normal Stress at upstream face is Given?

Total Vertical Force when Vertical Normal Stress at upstream face is Given calculator uses vertical_force = Maximum Normal Stress/((1/(144*Breadth))*(1-((6*Eccentricity)/Breadth))) to calculate the Vertical component of force, The Total Vertical Force when Vertical Normal Stress at upstream face is Given formula is defined as net force in vertical direction. Vertical component of force and is denoted by Fv symbol.

How to calculate Total Vertical Force when Vertical Normal Stress at upstream face is Given using this online calculator? To use this online calculator for Total Vertical Force when Vertical Normal Stress at upstream face is Given, enter Maximum Normal Stress n-max), Breadth (b) and Eccentricity (e) and hit the calculate button. Here is how the Total Vertical Force when Vertical Normal Stress at upstream face is Given calculation can be explained with given input values -> 4.114E+9 = 10000000/((1/(144*2))*(1-((6*0.1)/2))).

FAQ

What is Total Vertical Force when Vertical Normal Stress at upstream face is Given?
The Total Vertical Force when Vertical Normal Stress at upstream face is Given formula is defined as net force in vertical direction and is represented as Fv = σn-max/((1/(144*b))*(1-((6*e)/b))) or vertical_force = Maximum Normal Stress/((1/(144*Breadth))*(1-((6*Eccentricity)/Breadth))). The Maximum Normal Stress Value, Breadth is the measurement or extent of something from side to side and Eccentricity of an ellipse is a non-negative real number that uniquely characterizes its shape.
How to calculate Total Vertical Force when Vertical Normal Stress at upstream face is Given?
The Total Vertical Force when Vertical Normal Stress at upstream face is Given formula is defined as net force in vertical direction is calculated using vertical_force = Maximum Normal Stress/((1/(144*Breadth))*(1-((6*Eccentricity)/Breadth))). To calculate Total Vertical Force when Vertical Normal Stress at upstream face is Given, you need Maximum Normal Stress n-max), Breadth (b) and Eccentricity (e). With our tool, you need to enter the respective value for Maximum Normal Stress, Breadth and Eccentricity 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 Vertical component of force?
In this formula, Vertical component of force uses Maximum Normal Stress, Breadth and Eccentricity. We can use 5 other way(s) to calculate the same, which is/are as follows -
  • vertical_force = Force*sin(Angle)
  • vertical_force = Velocity of piston*0.25*pi*Diameter*Diameter
  • vertical_force = Length*pi*Dynamic viscosity*Velocity of piston*(0.75*((Diameter/Clearance)^3)+1.5*((Diameter/Clearance)^2))
  • vertical_force = Force-Shear Force
  • vertical_force = Maximum Normal Stress/((1/(144*Breadth))*(1+((6*Eccentricity)/Breadth)))
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