Several forces are applied to the pipe assembly shown. the inner and outer diameters of the pipe are equal to 1.50 and 1.75 inches, respectively. (a) determine the principal planes and principal stresses at pt. h located at the top of the outside surface of the pipe (b) determine the maximum shear stress at pt. h (c) provide a sketch (to-scale) of mohr's circle for the state of stress at pt. h

Question

Physics

Annabel Lutz

14 April, 17:55

Several forces are applied to the pipe assembly shown. the inner and outer diameters of the pipe are equal to 1.50 and 1.75 inches, respectively. (a) determine the principal planes and principal stresses at pt. h located at the top of the outside surface of the pipe (b) determine the maximum shear stress at pt. h (c) provide a sketch (to-scale) of mohr's circle for the state of stress at pt. h

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Answers (1)

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Carlie Williams · Answer 1

To replace all forces on a pipe by the equivalent force

T = 8 * 50 = 400lb. in

M = 16.30 = 480lb. in

F₂ = 50lb

To calculate the polar moment of inertia of shaft is

J = π/π² * (R⁴-r⁴)

= π²/2 * (0.875⁴ - 0.750⁴)

= 0.423in.³

To calculate the moment of inertia

J = 1/2 (J)

=1/2 (0.423)

=0.21188in.³

To calculate shear flow

Qy = 2/3 (R³-r³)

= 2/3 (0.875³ - 0.750³)

= 0.16536in.³

To calculate the thickness of the shaft

t = R-r = 0.875 - 0.750 = 0.125 in.

The stress due to torsions is.

Tx = TR/J = 400 * 0.875/0.42376

=825. 9psi.

The stress due to bending

Qx = My/T = 480 * 0.875/0.2118

=1982.3psi

The stress due to transverse shear

Qx = VQ/I (2t)

=50 * 0.16536/0.2118 * 0.250

=156.1psi