We first look at a cylindrical pressure vessel shown in Diagram 1, where we have cut a cross section of the vessel, and have shown the forces due to the internal pressure, and the balancing forces due to the longitudinal stress which develops in the vessel walls. (There is also a transverse or circumferential stress which develops, and which we will consider next.)
The longitudinal stress may be found by equating the force due to internal gas/fluid pressure with the force due to the longitudinal stress as follows:
P(A) = (A'); or P(3.1416 * R2) = (2 * 3.1416 * R * t), then canceling terms and solving for the longitudinal stress, we have:
= P R / 2 t ; where
P = internal pressure in cylinder; R = radius of cylinder, t = wall thickness
To determine the relationship for the transverse stress, often called the hoop stress, we use the same approach, but first cut the cylinder lengthwise as shown in Diagram 2.
We once again equate the force on the cylinder section wall due to the internal pressure with the resistive force which develops in walls and may be expressed in terms of the hoop stress, . The effective area the internal pressure acts on may be consider to be the flat cross section given by (2*R*L). So we may write:
P(A) = (A'); or P(2*R*L) = (2*t*L), then canceling terms and solving for the hoop stress, we have:
= P R / t ; where
P = internal pressure in cylinder; R = radius of cylinder, t = wall thickness
We note that the hoop stress is twice the value of the longitudinal stress, and is normally the limiting factor. The vessel does not have to be a perfect cylinder. In any thin wall pressure vessel in which the pressure is uniform and which has a cylindrical section, the stress in the cylindrical section is given by the relationships above.
Example A: A thin wall pressure vessel is shown in Diagram 3. It's cylindrical section has a radius of 2 feet, and a wall thickness of the 1". The internal pressure is 500 lb/in2. Determine the longitudinal and hoop stresses in the cylindrical region.
Solution:We apply the relationships developed for stress in cylindrical vessels.
= P R / 2 t = 500 lb/in2 * 24"/2 * 1" = 6000 lb/in2.
= P R / t = 500 lb/in2 * 24"/ 1" = 12, 000 lb/in2.
Next we consider the stress in thin wall spherical pressure vessels. Using the approach as in cylindrical vessels, in Diagram 4 we have shown a half section of a spherical vessel. If we once again equal the force due to the internal pressure with the resistive force expressed in term of the stress, we have:
P(A) = (A'); or P(3.1416 * R2) = (2 * 3.1416 * R * t), then canceling terms and solving for the stress, we have:
= P R / 2 t ; where
P = internal pressure in sphere; R = radius of sphere, t = wall thickness
Note that we have not called this a longitudinal or hoop stress. We do not do so since the symmetry of the sphere means that the stress in equal in what we could consider a longitudinal and/or transverse direction.
Example B. In Example A, above, if the radius of the spherical section of the container is also 2 feet, determine the stress in the spherical region.
Solution: We apply our spherical relationship:
= P R / 2 t = 500 lb/in2 * 24"/2 * 1" = 6000 lb/in2.
Thus in the container in Example A, the limiting (maximum) stress occurs in the in the cylindrical region and has a value of 12,000 lb/in2.
http://physics.uwstout.edu/statstr/statics/Columns/cols65.htm
Hi
ReplyDeleteI want to know the total pressure due to vehicles on a buried pipeline at a depth of 1.2 meters. the pipeline details are API5X Gr60 Design code-ASME-31.4, Diameter-20inches, pipe thickness is 6.4mm, design pressure-70.6 bar and operating pressure is 7 bar. Please suggest which equation to use for calculation of maximum vertical load on pipe how much it can withstand.