Pressure Vessel (Hoop Stress) Calculator

Does the wall hold? Hoop and longitudinal stress in a thin-walled cylinder or sphere, checked against the allowable — plus the minimum wall thickness and the maximum pressure the vessel can take.

Units

Shape

Internal pressure p (psi)

Inside diameter D (in)

Wall thickness t (in)

Material (allowable stress)

Allowable stress S (psi)

Hoop stress—

Why a Pressure Vessel Splits Lengthwise

Put pressure inside a pipe or tank and the wall feels two stresses at once. The hoop (circumferential) stress tries to burst it open along its length; the longitudinal stress tries to pull the ends apart. For a cylinder the hoop stress is exactly twice the longitudinal — which is why a failed pressure vessel splits along a seam rather than popping its ends, and why the hoop direction governs the design.

Hoop: σ = p D / 2t · Longitudinal: σ = p D / 4t

p is the internal pressure, D the inside diameter and t the wall thickness. A sphere carries the pressure equally in every direction, so its wall stress is only p D / 4t — half a cylinder. That efficiency is exactly why high-pressure storage tanks are spherical.

The Decision: Thickness and Pressure

Turned around, the same relationship sizes the vessel. The minimum wall to keep the hoop stress within an allowable S is t = p D / 2S, and the most pressure a given wall can take is p = 2 S t / D. The calculator reports both, plus how much of the allowable the current design uses.

Thin Wall vs Thick Wall

These formulas assume a thin wall — a diameter-to-thickness ratio of about 20 or more — where the stress is roughly uniform through the wall. Below that, the inner surface carries noticeably more stress and you need the thick-wall (Lame) equations instead. The calculator flags when D/t drops too low.

Frequently Asked Questions

Inside or outside diameter?

Thin-wall formulas use the inside diameter (some references use the mean); the difference is small when the wall is thin, and larger differences are a sign you should switch to thick-wall analysis.

What allowable stress should I use?

Not the yield strength. Use a code allowable – typically the lesser of a fraction of yield and of ultimate (around a quarter of ultimate in ASME work), and reduce it further by the weld joint efficiency.

What about corrosion?

Add a corrosion allowance to the calculated minimum thickness so the vessel still has full wall after years of service. This tool gives the structural minimum only.

Related calculators

Mechanical Stress Calculator — general stress, strain and safety factor.
Pipe Flow Calculator — what is moving through the pipe.
Pressure Drop Calculator — the pressure the line actually sees.
Engineering Unit Converter — pressure and stress units.

For education and preliminary sizing only. Pressure vessel and piping design is governed by codes such as the ASME Boiler and Pressure Vessel Code, including joint efficiency, corrosion allowance, fatigue and inspection, and must be performed and certified by a qualified engineer.