Though generally section modulus is calculated for the extreme tensile or compressive fibres in a bending beam, often compression is the most critical case due to onset of flexural torsional (F/T) buckling. ( January 2014) ( Learn how and when to remove this template message) Unsourced material may be challenged and removed. Please help improve this section by adding citations to reliable sources. Shape factor for a rectangular section is 1.5. Section modulus equations Cross-sectional shape It is also often used to determine the yield moment ( M y) such that M y = S ⋅ σ y, where σ y is the yield strength of the material. It is often reported using y = c, where c is the distance from the neutral axis to the most extreme fibre, as seen in the table below. The elastic section modulus is defined as S = I / y, where I is the second moment of area (or area moment of inertia, not to be confused with moment of inertia) and y is the distance from the neutral axis to any given fibre. Eurocode 3 (EN 1993 - Steel Design) resolves this by using W for both, but distinguishes between them by the use of subscripts - W el and W pl.įor general design, the elastic section modulus is used, applicable up to the yield point for most metals and other common materials. Elastic modulus is S in North America, but Z in Britain/Australia, and vice versa for the plastic modulus. North American and British/Australian convention reverse the usage of S & Z. The section moduli of different profiles can also be found as numerical values for common profiles in tables listing properties of such. There are two types of section moduli, the elastic section modulus and the plastic section modulus. Equations for the section moduli of common shapes are given below. Any relationship between these properties is highly dependent on the shape in question. Other geometric properties used in design include area for tension and shear, radius of gyration for compression, and second moment of area and polar second moment of area for stiffness. Section modulus is a geometric property for a given cross-section used in the design of beams or flexural members. JSTOR ( October 2009) ( Learn how and when to remove this template message).Please help improve this article by adding citations to reliable sources. ** Search this PAGE ONLY, click on Maginifying Glass **Īll calculators require a java enabled browser.This article needs additional citations for verification. Section Properties Radius of Gyration Cases 35 - 37.Section Properties Radius of Gyration Cases 32 - 34.Section Properties Radius of Gyration Cases 28 - 31.Section Properties Radius of Gyration Cases 23 - 27.Section Properties Radius of Gyration Cases 17 - 22.Section Properties Radius of Gyration Cases 11 - 16.Section Properties Radius of Gyration Cases 1 - 10.Section Modulus Equations and Calculators.Beam Deflection Stress Equation Calculators.Each calculator is associated with web pageor on-page equations for calculating the sectional properties. The links will open a new browser window. The following links are to calculators which will calculate the Section Area Moment of Inertia Properties of common shapes. Section Area Moment of Inertia Properties Area Moment of Inertia of Common ShapesĮngineering Metals and Materials Table of Contents
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