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CTC / MTC 222 Strength of Materials

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Title: CTC / MTC 222 Strength of Materials


1
CTC / MTC 222 Strength of Materials
  • Chapter 6
  • Centroids and Moments of Inertia of Areas

2
Chapter Objectives
  • Define centroid and locate the centroid of a
    shape by inspection or calculation
  • Define moment of inertia and compute its values
    with respect to the centroidal axes of the area
  • Use the parallel axis theorem to compute the
    moment of inertia of composite shapes

3
Centroid of an Area
  • Centroid of an area the geometric center of the
    area
  • Centroid of simple shapes circle, rectangle,
    triangle
  • Often, easily visualized
  • Centroids and other properties shown in Appendix
    A-1
  • Centroid of complex shapes with axes of symmetry
  • If area has an axis of symmetry centroid is on
    that axis
  • If area has two axes of symmetry centroid is at
    the intersection of the two axes
  • Centroid of complex shapes without axes of
    symmetry
  • Can often be considered as a composite of two or
    more simple shapes
  • Centroid of complex shape can be calculated using
    centroids of the simple shapes and the locations
    of these centroids with respect to some reference
    axis

4
Centroid of an Area
  • Centroid of complex shapes can be calculated
    using
  • AT Y ? (Ai yi ) where
  • AT total area of composite shape
  • Y distance to centroid of composite shape
    from some reference axis
  • Ai area of one component part of shape
  • yi distance to centroid of the component part
    from the reference axis
  • Solve for Y ? (Ai yi ) / AT
  • Perform calculation in tabular form
  • See Examples 6-1 6-2

5
Moment of Inertia
  • Moment of Inertia - a measure of the stiffness of
    a beam, or of its resistance to deflection due to
    bending
  • Sometimes referred to as the second moment of
    area, or the area moment of inertia
  • Moment of inertia of an area with respect to a
    particular axis the sum of the products of each
    (infinitesimal) element of the area by the square
    of its distance from the axis
  • Approximately I ? y2 (?A)
  • Exactly - I ? y2 dA
  • Moment of inertia of simple shapes circle,
    rectangle, triangle
  • Formulas derived from basic definition, shown in
    Appendix A-1
  • Moment of inertia standard structural shapes
    wide flange sections, channels, angles, pipe,
    etc.
  • Tabulated in standard references such as Steel
    Design Manual
  • Some in Appendix A

6
Moment of Inertia
  • Moment of inertia complex shapes
  • Can often be considered as a composite of two or
    more simple shapes
  • If all component parts have the same centroidal
    axis
  • Add or subtract the moments of inertia of the
    component parts with respect to the centroidal
    axis
  • If all component parts do not have the same
    centroidal axis
  • Moment of inertia can be calculated using the
    parallel axis theorem
  • Parallel axis theorem
  • Moment of inertia of a shape with respect to a
    given axis is equal to the sum if the moment of
    inertia of the shape to its own centroidal axis
    plus the transfer term, Ad2, where A is the area
    of the shape and d is the distance from the
    centroidal axis to the axis of interest
  • I I0 Ad2

7
Moment of Inertia ofComposite Shapes
  • Perform calculation in tabular form
  • Divide the shape into component parts which are
    simple shapes
  • Locate the centroid of each component part, yi
    from some reference axis
  • Calculate the centroid of the composite section,
    Y from some reference axis
  • Compute the moment of inertia of each part with
    respect to its own centroidal axis, Ii
  • Compute the distance, di Y - yi of the
    centroid of each part from the overall centroid
  • Compute the transfer term Ai di2 for each part
  • The overall moment of inertia IT , is then
  • IT ? (Ii Ai di2)
  • See Examples 6-5 through 6-7

8
Radius of Gyration, r
  • Radius of Gyration - a measure of a compression
    members slenderness, or its resistance to
    buckling due to compressive load
  • Buckling Failure under compressive load by
    excessive lateral deflection at a stress below
    the yield stress (elastic buckling)
  • Buckling will occur about the axis with the least
    radius of gyration
  • The tendency for a compression member to buckle
    is directly proportional to its length squared
    and indirectly proportional to its radius of
    gyration squared.
  • Radius of Gyration r v (I /A )
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