Shear Force for Torque and Diameter of Shaft in Journal Bearing Calculator

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✖Torque Exerted on Wheel is described as the turning effect of force on the axis of rotation. In brief, it is a moment of force. It is characterized by τ.ⓘ Torque Exerted on Wheel [τ]			+10% -10%
✖Shaft Diameter is the diameter of the shaft of the pile.ⓘ Shaft Diameter [D_shaft]			+10% -10%

✖Shear Force is the force which causes shear deformation to occur in the shear plane.ⓘ Shear Force for Torque and Diameter of Shaft in Journal Bearing [F_s]

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Shear Force for Torque and Diameter of Shaft in Journal Bearing

Formula

`"F"_{"s"} = "τ"/("D"_{"shaft"}/2)`

Example

`"26.31579N"="50N*m"/("3.8m"/2)`

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Shear Force for Torque and Diameter of Shaft in Journal Bearing Solution

STEP 0: Pre-Calculation Summary

Formula Used

Shear Force = Torque Exerted on Wheel/(Shaft Diameter/2)
F_s = τ/(D_shaft/2)
This formula uses 3 Variables

Variables Used

Shear Force - (Measured in Newton) - Shear Force is the force which causes shear deformation to occur in the shear plane.
Torque Exerted on Wheel - (Measured in Newton Meter) - Torque Exerted on Wheel is described as the turning effect of force on the axis of rotation. In brief, it is a moment of force. It is characterized by τ.
Shaft Diameter - (Measured in Meter) - Shaft Diameter is the diameter of the shaft of the pile.

STEP 1: Convert Input(s) to Base Unit

Torque Exerted on Wheel: 50 Newton Meter --> 50 Newton Meter No Conversion Required
Shaft Diameter: 3.8 Meter --> 3.8 Meter No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

F_s = τ/(D_shaft/2) --> 50/(3.8/2)

Evaluating ... ...

F_s = 26.3157894736842

STEP 3: Convert Result to Output's Unit

26.3157894736842 Newton --> No Conversion Required

FINAL ANSWER

26.3157894736842 ≈ 26.31579 Newton <-- Shear Force

(Calculation completed in 00.004 seconds)

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Home » Physics » Fluid Mechanics » Viscous Flow » Fluid Flow and Resistance » Shear Force for Torque and Diameter of Shaft in Journal Bearing

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Created by Maiarutselvan V

PSG College of Technology (PSGCT), Coimbatore

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Indian Institute of Technology (IIT), Bombay

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< 21 Fluid Flow and Resistance Calculators

Total Torque Measured by Strain in Rotating Cylinder Method

Go Torque Exerted on Wheel = (Viscosity of Fluid*pi*Inner Radius of Cylinder^2*Mean Speed in RPM*(4*Initial Height of Liquid*Clearance*Outer Radius of Cylinder+(Inner Radius of Cylinder^2)*(Outer Radius of Cylinder-Inner Radius of Cylinder)))/(2*(Outer Radius of Cylinder-Inner Radius of Cylinder)*Clearance)

Angular Speed of Outer Cylinder in Rotating Cylinder Method

Go Mean Speed in RPM = (2*(Outer Radius of Cylinder-Inner Radius of Cylinder)*Clearance*Torque Exerted on Wheel)/(pi*Inner Radius of Cylinder^2*Viscosity of Fluid*(4*Initial Height of Liquid*Clearance*Outer Radius of Cylinder+Inner Radius of Cylinder^2*(Outer Radius of Cylinder-Inner Radius of Cylinder)))

Discharge in Capillary Tube Method

Go Discharge in Capillary Tube = (4*pi*Density of Liquid*[g]*Difference in Pressure Head*Radius of Pipe^4)/(128*Viscosity of Fluid*Length of Pipe)

Rotational Speed for Torque Required in Collar Bearing

Go Mean Speed in RPM = (Torque Exerted on Wheel*Thickness of Oil Film)/(Viscosity of Fluid*pi^2*(Outer Radius of Collar^4-Inner Radius of Collar^4))

Torque Required to Overcome Viscous Resistance in Collar Bearing

Go Torque Exerted on Wheel = (Viscosity of Fluid*pi^2*Mean Speed in RPM*(Outer Radius of Collar^4-Inner Radius of Collar^4))/Thickness of Oil Film

Velocity of Piston or Body for Movement of Piston in Dash-Pot

Go Velocity of Fluid = (4*Weight of Body*Clearance^3)/(3*pi*Length of Pipe*Piston Diameter^3*Viscosity of Fluid)

Shear Force or Viscous Resistance in Journal Bearing

Go Shear Force = (pi^2*Viscosity of Fluid*Mean Speed in RPM*Length of Pipe*Shaft Diameter^2)/(Thickness of Oil Film)

Speed of Rotation for Shear Force in Journal Bearing

Go Mean Speed in RPM = (Shear Force*Thickness of Oil Film)/(Viscosity of Fluid*pi^2*Shaft Diameter^2*Length of Pipe)

Shear Stress in Fluid or Oil of Journal Bearing

Go Shear Stress = (pi*Viscosity of Fluid*Shaft Diameter*Mean Speed in RPM)/(60*Thickness of Oil Film)

Rotational Speed for Torque Required in Foot-Step Bearing

Go Mean Speed in RPM = (Torque Exerted on Wheel*Thickness of Oil Film)/(Viscosity of Fluid*pi^2*(Shaft Diameter/2)^4)

Torque Required to Overcome Viscous Resistance in Foot-Step Bearing

Go Torque Exerted on Wheel = (Viscosity of Fluid*pi^2*Mean Speed in RPM*(Shaft Diameter/2)^4)/Thickness of Oil Film

Velocity of Sphere in Falling Sphere Resistance Method

Go Velocity of Sphere = Drag Force/(3*pi*Viscosity of Fluid*Diameter of Sphere)

Drag Force in Falling Sphere Resistance Method

Go Drag Force = 3*pi*Viscosity of Fluid*Velocity of Sphere*Diameter of Sphere

Density of Fluid in Falling Sphere Resistance Method

Go Density of Liquid = Buoyant Force/(pi/6*Diameter of Sphere^3*[g])

Buoyant Force in Falling Sphere Resistance Method

Go Buoyant Force = pi/6*Density of Liquid*[g]*Diameter of Sphere^3

Velocity at Any Radius given Radius of Pipe, and Maximum Velocity

Go Velocity of Fluid = Maximum Velocity*(1-(Radius of Pipe/(Pipe Diameter/2))^2)

Maximum Velocity at any Radius using Velocity

Go Maximum Velocity = Velocity of Fluid/(1-(Radius of Pipe/(Pipe Diameter/2))^2)

Rotational Speed considering Power Absorbed and Torque in Journal Bearing

Go Mean Speed in RPM = Power Absorbed/(2*pi*Torque Exerted on Wheel)

Torque Required Considering Power Absorbed in Journal Bearing

Go Torque Exerted on Wheel = Power Absorbed/(2*pi*Mean Speed in RPM)

Shear Force for Torque and Diameter of Shaft in Journal Bearing

Go Shear Force = Torque Exerted on Wheel/(Shaft Diameter/2)

Torque Required to Overcome Shear Force in Journal Bearing

Go Torque Exerted on Wheel = Shear Force*Shaft Diameter/2

Shear Force for Torque and Diameter of Shaft in Journal Bearing Formula

Shear Force = Torque Exerted on Wheel/(Shaft Diameter/2)
F_s = τ/(D_shaft/2)

What is viscous resistance of journal bearing?

Let us consider that a shaft is rotating in a journal bearing and think that oil is used as a lubricant in order to fill the clearance between the shaft and journal bearing. Therefore oil will offer viscous resistance to the rotating shaft.

What is shear force in the oil?

Shear forces acting tangentially to a surface of a solid body cause deformation. When the fluid is in motion, shear stresses are developed due to the particles in the fluid moving relative to one another.

How to Calculate Shear Force for Torque and Diameter of Shaft in Journal Bearing?

Shear Force for Torque and Diameter of Shaft in Journal Bearing calculator uses Shear Force = Torque Exerted on Wheel/(Shaft Diameter/2) to calculate the Shear Force, The Shear force for torque and diameter of shaft in journal bearing is known while considering the terms of vicious resistance or shear force and diameter of the shaft from the journal bearing derivation in viscous flow. Shear Force is denoted by F_s symbol.

How to calculate Shear Force for Torque and Diameter of Shaft in Journal Bearing using this online calculator? To use this online calculator for Shear Force for Torque and Diameter of Shaft in Journal Bearing, enter Torque Exerted on Wheel (τ) & Shaft Diameter (D_shaft) and hit the calculate button. Here is how the Shear Force for Torque and Diameter of Shaft in Journal Bearing calculation can be explained with given input values -> 26.31579 = 50/(3.8/2).

FAQ

What is Shear Force for Torque and Diameter of Shaft in Journal Bearing?

The Shear force for torque and diameter of shaft in journal bearing is known while considering the terms of vicious resistance or shear force and diameter of the shaft from the journal bearing derivation in viscous flow and is represented as F_s = τ/(D_shaft/2) or Shear Force = Torque Exerted on Wheel/(Shaft Diameter/2). Torque Exerted on Wheel is described as the turning effect of force on the axis of rotation. In brief, it is a moment of force. It is characterized by τ & Shaft Diameter is the diameter of the shaft of the pile.

How to calculate Shear Force for Torque and Diameter of Shaft in Journal Bearing?

The Shear force for torque and diameter of shaft in journal bearing is known while considering the terms of vicious resistance or shear force and diameter of the shaft from the journal bearing derivation in viscous flow is calculated using Shear Force = Torque Exerted on Wheel/(Shaft Diameter/2). To calculate Shear Force for Torque and Diameter of Shaft in Journal Bearing, you need Torque Exerted on Wheel (τ) & Shaft Diameter (D_shaft). With our tool, you need to enter the respective value for Torque Exerted on Wheel & Shaft Diameter 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 Shear Force?

In this formula, Shear Force uses Torque Exerted on Wheel & Shaft Diameter. We can use 1 other way(s) to calculate the same, which is/are as follows -

Shear Force = (pi^2*Viscosity of Fluid*Mean Speed in RPM*Length of Pipe*Shaft Diameter^2)/(Thickness of Oil Film)

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