DERIVATION OF TORSIONAL EQUATION

We were discussing the concept of Torsion or twisting moment, Torque transmitted by a circular solid shaft and torque transmitted by a circular hollow shaft in our previous posts. 

Now we are going further to start a new topic i.e. Derivation of torsional equation with the help of this post.

Before going ahead, let us recall the basic definition of twisting moment or torsion.

A shaft will said to be in torsion, if it will be subjected with two equal and opposite torques applied at its two ends.

When a shaft will be subjected to torsion or twisting moment, there will be developed shear stress and shear strain in the shaft material.

We will consider here one case of circular shaft which will be subjected to torsion and we will derive here the torsion equation for circular shaft.

We have following information from above figure

R = Radius of the circular shaft

D = Diameter of the circular shaft

dr = Thickness of small elementary circular ring

r = Radius of the small elementary of circular ring

q = Shear stress at a radius r from the centre of the circular shaft

τ = Shear stress at outer surface of shaft

dA = Area of the small elementary of circular ring

dA = 2П x r x dr

Shear stress, at a radius r from the centre, could be determined as mentioned here

q/r = τ /R

q = τ x r/R

Turning force due to shear stress at a radius r from the centre could be determined as mentioned here

dF = q x dA

dF = τ x r/R x 2П x r x dr

dF = τ/R x 2П r²dr

Twisting moment at the circular elementary ring could be determined as mentioned here

dT = Turning force x r

dT = τ/R x 2П r³dr

dT = τ/R x r² x (2П x r x dr)

dT = τ/R x r² x dA

Total torque could be easily determined by integrating the above equation between limits 0 and R

Therefore total torque transmitted by a circular solid shaft could be given in following way as displayed here in following figure.

Let us recall here the basic concept of Polar moment of inertia and we can write here the formula for polar moment inertia. Further, we will use this formula of polar moment of inertia in above equation.

Polar moment of inertia

Therefore total torque transmitted by a circular solid shaft could be given by following equation as mentioned here.

We have already derived the expression for shear stress produced in a circular shaft subjected to torsion and therefore we have following result from that expression

Considering above two equations, we can write here the expression for torsion equation for circular shaft as displayed here.

Where, 

C = Modulus of rigidity

L = Length of shaft

θ = Angle of twist (Radian)

Do you have suggestions? Please write in comment box.

We will now discuss another topic i.e. Power transmitted by a circular solid shaft, in the category of strength of material, in our next post.

Reference:

Strength of material, By R. K. Bansal

Image Courtesy: Google

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An introduction to hydraulic machine  

Various types of hydraulic turbines  

Gross head, Net head and efficiencies of a hydraulic turbine  

Fundamental of Pelton wheel or Pelton hydraulic turbine  

Basics of radial flow reaction turbines  

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Francis turbine 

Axial flow reaction turbine 

Specific speed of turbine 

Draft-tube 

Governing of turbines 

Governing of impulse turbine or Pelton turbine  

Governing of reaction turbine  

Stirling cycle 

Ericsson cycle

Rankine cycle

Carnot cycle

PV diagram of a pure substance

Brayton cycle

Effect of regeneration on Brayton cycle efficiency