Thin cylindrical vessels under internal pressure: if two vessels have the same wall thickness but different diameters, which one can withstand the higher internal pressure before reaching the same hoop stress limit?

Chemical Engineering Process Equipment and Plant Design Difficulty: Easy
Choose an option
  • A
    Larger dia vessel.
  • B
    Smaller dia vessel.
  • C
    Larger dia long vessel.
  • D
    Strength of the vessel is same irrespective of the diameter.

Answer

Correct Answer: Smaller dia vessel.

Explanation

Introduction / Context:For thin-walled cylinders, the dominant stress from internal pressure is the circumferential (hoop) stress. Understanding how geometry influences allowable pressure is fundamental in preliminary sizing and material selection.

Given Data / Assumptions:

  • Same material and same wall thickness t for both vessels.
  • Thin-wall assumption applies (t ≪ d).
  • Internal pressure only; no significant external loads.

Concept / Approach:The hoop stress for a thin cylinder is σ_h = p d / (2 t). For a given allowable stress and fixed t, the allowable pressure scales inversely with diameter: p_allow ∝ 1/d. Thus, reducing diameter increases the pressure that can be sustained before reaching the same stress limit.

Step-by-Step Solution:Write σ_h = p d / (2 t).For fixed σ_allow and t, solve p = 2 t σ_allow / d.Smaller d → larger p, hence the smaller diameter vessel withstands higher pressure.

Verification / Alternative check:Doubling diameter halves allowable pressure at unchanged thickness and allowable stress; this simple proportionality check confirms the conclusion.

Why Other Options Are Wrong:Larger dia vessel / larger dia long vessel: Both have higher hoop stress at the same pressure; thus lower allowable pressure for the same thickness.“Same strength irrespective of diameter”: Incorrect; the hoop-stress formula shows explicit dependence on d.

Common Pitfalls:Confusing longitudinal with hoop stress; applying thick-wall formulas to thin shells.

Final Answer:Smaller dia vessel.

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