Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical) PDF Download


THIN & THICK CYLINDERS AND SPHERES

THIN CYLINDERS

  •  If the thickness of the cylinder is less than 1/10 to 1/15 of the diameter of the cylinder,  it is treated as the thin cylinder.
  •  It is assumed that the stresses are uniformly distributed through out the thickness ofthe wall.
  •  'Hoop stress’ or ‘Circumferential stress’ is given by

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •   ‘Longitudinal stress’ is given by

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •  The Maximum shear stress is given by

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •  Hoop strain is given by

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •  Longitudinal strain is given by

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •  Volumetric strain is given by

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

Where
p = internal pressure
d = diameter of cylinder
t = thickness of the cylinder
μ = Poisson's ratio

  •  If ‘sa’ be the permissible tensile stress for the shell material, then from strength  point of view, the major principal stress (s) should be less than or equal to sa

Hence

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)
or
Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

THIN SPHERICAL SHELLS 

  •  In case of thin spherical shells, longitudinal stress and circumferential stress are equal and are given by

s1 =s2 = Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical) (tensile in nature)

  •  The maximum shear stress,  

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •  The strain in any direction is given by

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •   The volumetric strain is given by

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)CYLINDERS WITH HEMISPHERICAL ENDS

Let tc = thickness of the cylinder
ts = thickness of the hemisphere

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •   Hoop stress in cylindrical part

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •   Hoop stress in hemispherical part

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •  Longitudinal stress in cylindrical part

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •  Longitudinal stress in hemispherical part

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •   Circumferential strain in hemispherical part

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •   Circumferential strain in cylindrical part

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

  •   For the condition of no distortion of the junction  

Thus, equating the two strains in order that there shall be no distortion of the junction.

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

This means thickness of cylindrical part should be more than the hemispherical part.

  •  For the condition of same maximum stress in cylindrical and hemispherical parts,

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)
THICK CYLINDRICAL SHELL

  •   If the thickness of shell is greater than of
    Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

 its diameter then it is called thick shell.

  •   In thick cylinders the circumferential stress no longer remains constant, but varies  along the thickness and the radial pressure (px) is also not negligible.

The following three types of stresses are existing in thick cylinders :

(i) The radial pressure ‘px’ (compressive)
(ii) The hoop stress fx (tensile)
(iii) The longitudinal tensile stress po (tensile)

  •  The longitudinal stress may be given by

Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)

Hoop stress, is given by
Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)
Radial pressure is given by
Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical)
Equation (ii) and (iii) are called Lame’s equation.
ro = outer radius of shell
ri = inner radius of shell
A and B are Lame’s constant

Note:-

1. Longitudinal tension is uniform across the thickness.
2. Hoop tension vary form maximum at inner face to minimum at outer face hyperbolically.
3. Radial compression varies from maximum at inner face to zero at outer face (atm.) hyperbolically.

The document Thin, Thick Cylinders & Spheres | Mechanical Engineering SSC JE (Technical) is a part of the Mechanical Engineering Course Mechanical Engineering SSC JE (Technical).
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FAQs on Thin, Thick Cylinders & Spheres - Mechanical Engineering SSC JE (Technical)

1. What are the differences between thin and thick cylinders?
Ans. Thin cylinders have a wall thickness that is small compared to the radius, while thick cylinders have a wall thickness that is significant compared to the radius. Thin cylinders experience a uniform stress distribution, while thick cylinders experience non-uniform stress distribution due to the variation in thickness.
2. How do you calculate the stress in a thin cylinder?
Ans. The stress in a thin cylinder can be calculated using the formula σ = Pd/4t, where σ is the stress, P is the internal pressure, d is the diameter, and t is the thickness of the cylinder wall.
3. What is the formula to calculate the stress in a thick cylinder?
Ans. The stress in a thick cylinder can be calculated using the Lame's equation, which is σr = (Pd/2t)(1 - (a^2/r^2)), where σr is the radial stress, P is the internal pressure, d is the diameter, t is the thickness, a is the inner radius, and r is the radial distance from the center.
4. How do you calculate the strain in a sphere?
Ans. The strain in a sphere can be calculated using the formula ε = Δr/r, where ε is the strain, Δr is the change in radius, and r is the original radius of the sphere.
5. What are the applications of thin and thick cylinders in mechanical engineering?
Ans. Thin cylinders are commonly used in pressure vessels, such as gas cylinders and pipes, while thick cylinders are used in applications where high internal pressure is present, such as hydraulic systems and steam boilers.
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