✖Driving Moment is the moment (or torque) that drives or causes rotational movement in a soil mass or structural element, such as a retaining wall or pile foundation.ⓘ Driving Moment [M_D]			+10% -10%
✖Radius of Slip Circle is the distance between center and one point on slip circle.ⓘ Radius of Slip Circle [r]			+10% -10%

✖Sum of All Tangential Component in Soil Mechanics means total tangential component.ⓘ Sum of Tangential Component given Driving Moment [F_t]

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Formula

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Sum of Tangential Component given Driving Moment

Formula

`"F"_{"t"} = "M"_{"D"}/"r"`

Example

`"16.66667N"="10.0kN*m"/"0.6m"`

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Sum of Tangential Component given Driving Moment Solution

STEP 0: Pre-Calculation Summary

Formula Used

Sum of All Tangential Component in Soil Mechanics = Driving Moment/Radius of Slip Circle
F_t = M_D/r
This formula uses 3 Variables

Variables Used

Sum of All Tangential Component in Soil Mechanics - (Measured in Newton) - Sum of All Tangential Component in Soil Mechanics means total tangential component.
Driving Moment - (Measured in Kilonewton Meter) - Driving Moment is the moment (or torque) that drives or causes rotational movement in a soil mass or structural element, such as a retaining wall or pile foundation.
Radius of Slip Circle - (Measured in Meter) - Radius of Slip Circle is the distance between center and one point on slip circle.

STEP 1: Convert Input(s) to Base Unit

Driving Moment: 10 Kilonewton Meter --> 10 Kilonewton Meter No Conversion Required
Radius of Slip Circle: 0.6 Meter --> 0.6 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

F_t = M_D/r --> 10/0.6

Evaluating ... ...

F_t = 16.6666666666667

STEP 3: Convert Result to Output's Unit

16.6666666666667 Newton --> No Conversion Required

FINAL ANSWER

16.6666666666667 ≈ 16.66667 Newton <-- Sum of All Tangential Component in Soil Mechanics

(Calculation completed in 00.004 seconds)

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< 25 The Swedish Slip Circle Method Calculators

Sum of Normal Component given Factor of Safety

Go Sum of All Normal Component in Soil Mechanics = ((Factor of Safety*Sum of All Tangential Component in Soil Mechanics)-(Unit Cohesion*Length of Slip Arc))/tan((Angle of Internal Friction of Soil*pi)/180)

Length of Slip Circle given Sum of Tangential Component

Go Length of Slip Arc = ((Factor of Safety*Sum of All Tangential Component in Soil Mechanics)-(Sum of all Normal Component*tan((Angle of Internal Friction*pi)/180)))/Unit Cohesion

Sum of Tangential Component given Factor of Safety

Go Sum of All Tangential Component in Soil Mechanics = ((Unit Cohesion*Length of Slip Arc)+(Sum of all Normal Component*tan((Angle of Internal Friction*pi)/180)))/Factor of Safety

Total Length of Slip Circle given Resisting Moment

Go Length of Slip Arc = ((Resisting Moment/Radius of Slip Circle)-(Sum of all Normal Component*tan((Angle of Internal Friction of Soil))))/Unit Cohesion

Sum of Normal Component given Resisting Moment

Go Sum of all Normal Component = ((Resisting Moment/Radius of Slip Circle)-(Unit Cohesion*Length of Slip Arc))/tan((Angle of Internal Friction of Soil))

Resisting Moment given Radius of Slip Circle

Go Resisting Moment = Radius of Slip Circle*((Unit Cohesion*Length of Slip Arc)+(Sum of all Normal Component*tan((Angle of Internal Friction of Soil))))

Radial Distance from Centre of Rotation given Factor of Safety

Go Radial Distance = Factor of Safety/((Unit Cohesion*Length of Slip Arc)/(Weight of Body in Newtons*Distance between LOA and COR))

Distance between Line of Action of Weight and Line Passing through Center

Go Distance between LOA and COR = (Unit Cohesion*Length of Slip Arc*Radial Distance)/(Weight of Body in Newtons*Factor of Safety)

Normal Component given Resisting Force from Coulomb's Equation

Go Normal Component of Force in Soil Mechanics = (Resisting Force-(Unit Cohesion*Curve Length))/tan((Angle of Internal Friction))

Resisting Force from Coulomb's Equation

Go Resisting Force = ((Unit Cohesion*Curve Length)+(Normal Component of Force*tan((Angle of Internal Friction))))

Curve Length of Each Slice given Resisting Force from Coulomb's Equation

Go Curve Length = (Resisting Force-(Normal Component of Force*tan((Angle of Internal Friction))))/Unit Cohesion

Distance between Line of Action and Line Passing through Center given Mobilized Cohesion

Go Distance between LOA and COR = Mobilized Shear Resistance of Soil/((Weight of Body in Newtons*Radial Distance)/Length of Slip Arc)

Radial Distance from Centre of Rotation given Mobilized Shear Resistance of Soil

Go Radial Distance = Mobilized Shear Resistance of Soil/((Weight of Body in Newtons*Distance between LOA and COR)/Length of Slip Arc)

Mobilized Shear Resistance of Soil given Weight of Soil on Wedge

Go Mobilized Shear Resistance of Soil = (Weight of Body in Newtons*Distance between LOA and COR*Radial Distance)/Length of Slip Arc

Radial Distance from Center of Rotation given Length of Slip Arc

Go Radial Distance = (360*Length of Slip Arc)/(2*pi*Arc Angle*(180/pi))

Arc Angle given Length of Slip Arc

Go Arc Angle = (360*Length of Slip Arc)/(2*pi*Radial Distance)*(pi/180)

Radial Distance from Centre of Rotation given Moment of Resistance

Go Radial Distance = Resisting Moment/(Unit Cohesion*Length of Slip Arc)

Moment of Resistance given Unit Cohesion

Go Resisting Moment = (Unit Cohesion*Length of Slip Arc*Radial Distance)

Sum of Tangential Component given Driving Moment

Go Sum of All Tangential Component in Soil Mechanics = Driving Moment/Radius of Slip Circle

Driving Moment given Radius of Slip Circle

Go Driving Moment = Radius of Slip Circle*Sum of All Tangential Component in Soil Mechanics

Moment of Resistance given Factor of Safety

Go Moment of Resistance with Factor of Safety = Factor of Safety*Driving Moment

Distance between Line of Action and Line Passing through Center given Driving Moment

Go Distance between LOA and COR = Driving Moment/Weight of Body in Newtons

Driving Moment given Weight of Soil on Wedge

Go Driving Moment = Weight of Body in Newtons*Distance between LOA and COR

Mobilized Shear Resistance of Soil given Factor of Safety

Go Mobilized Shear Resistance of Soil = Unit Cohesion/Factor of Safety

Driving Moment given Factor of Safety

Go Driving Moment = Resisting Moment/Factor of Safety

Sum of Tangential Component given Driving Moment Formula

Sum of All Tangential Component in Soil Mechanics = Driving Moment/Radius of Slip Circle
F_t = M_D/r

What is Moment of Force?

The Moment of a force is a measure of its tendency to cause a body to rotate about a specific point or axis. This is different from the tendency for a body to move, or translate, in the direction of the force.

How to Calculate Sum of Tangential Component given Driving Moment?

Sum of Tangential Component given Driving Moment calculator uses Sum of All Tangential Component in Soil Mechanics = Driving Moment/Radius of Slip Circle to calculate the Sum of All Tangential Component in Soil Mechanics, The Sum of Tangential Component given Driving Moment is defined as the value of forces or components acting tangentially to a surface or along a specified direction. In soil mechanics, tangential forces could relate to shear forces along a failure plane or along the interface of soil and a structure. Sum of All Tangential Component in Soil Mechanics is denoted by F_t symbol.

How to calculate Sum of Tangential Component given Driving Moment using this online calculator? To use this online calculator for Sum of Tangential Component given Driving Moment, enter Driving Moment (M_D) & Radius of Slip Circle (r) and hit the calculate button. Here is how the Sum of Tangential Component given Driving Moment calculation can be explained with given input values -> 16.66667 = 10000/0.6.

FAQ

What is Sum of Tangential Component given Driving Moment?

The Sum of Tangential Component given Driving Moment is defined as the value of forces or components acting tangentially to a surface or along a specified direction. In soil mechanics, tangential forces could relate to shear forces along a failure plane or along the interface of soil and a structure and is represented as F_t = M_D/r or Sum of All Tangential Component in Soil Mechanics = Driving Moment/Radius of Slip Circle. Driving Moment is the moment (or torque) that drives or causes rotational movement in a soil mass or structural element, such as a retaining wall or pile foundation & Radius of Slip Circle is the distance between center and one point on slip circle.

How to calculate Sum of Tangential Component given Driving Moment?

The Sum of Tangential Component given Driving Moment is defined as the value of forces or components acting tangentially to a surface or along a specified direction. In soil mechanics, tangential forces could relate to shear forces along a failure plane or along the interface of soil and a structure is calculated using Sum of All Tangential Component in Soil Mechanics = Driving Moment/Radius of Slip Circle. To calculate Sum of Tangential Component given Driving Moment, you need Driving Moment (M_D) & Radius of Slip Circle (r). With our tool, you need to enter the respective value for Driving Moment & Radius of Slip Circle 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 Sum of All Tangential Component in Soil Mechanics?

In this formula, Sum of All Tangential Component in Soil Mechanics uses Driving Moment & Radius of Slip Circle. We can use 1 other way(s) to calculate the same, which is/are as follows -

Sum of All Tangential Component in Soil Mechanics = ((Unit Cohesion*Length of Slip Arc)+(Sum of all Normal Component*tan((Angle of Internal Friction*pi)/180)))/Factor of Safety

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