Second moment of area

This article is about the geometrical property of an area, termed the second moment of area. For the moment of inertia dealing with the rotation of an object with mass, see mass moment of inertia.
For a list, see list of second moments of area.

The second moment of area, also known as moment of inertia of plane area, area moment of inertia, or second area moment, is a geometrical property of an area which reflects how its points are distributed with regard to an arbitrary axis. The second moment of area is typically denoted with either an I for an axis that lies in the plane or with a J for an axis perpendicular to the plane. In both cases, it is calculated with a multiple integral over the object in question. Its unit of dimension is length to fourth power, L4.

In the field of structural engineering, the second moment of area of the cross-section of a beam is an important property used in the calculation of the beam's deflection and the calculation of stress caused by a moment applied to the beam.


Note: Different disciplines use "Moment of Inertia" (MOI) to refer to either or both of the planar second moment of area,  I = \textstyle\iint_{R} x^2\, \mathrm dA , where x is the distance to some reference plane, or the polar second moment of area,  I = \textstyle\iint_{R} r^2\, \mathrm dA , where r is the distance to some reference axis. In each case the integral is over all the infinitesimal elements of area, dA, in some two-dimensional cross-section. In math and physics, "Moment of Inertia" is strictly the second moment of mass with respect to distance from an axis:  I = \textstyle\int_{Q} r^2 \mathrm dm , where r is the distance to some potential rotation axis, and the integral is over all the infinitesimal elements of mass, dm, in a three-dimensional space occupied by an object Q. The MOI, in this sense, is the analog of mass for rotational problems. In engineering (especially mechanical and civil), "Moment of Inertia" commonly refers to the second moment of the area.[1]

Definition

An arbitrary shape. ρ is the radial distance to the element dA, with projections x and y on the axes.

The second moment of area for an arbitrary shape R with respect to an arbitrary axis BB' is defined as

J_{BB'} = \iint\limits_{R} {\rho}^2 \, \mathrm dA

where

\mathrm dA is the differential area of the arbitrary shape, and
\rho is the distance from the axis BB' to \mathrm dA.[2]

For example, when the desired reference axis is the x-axis the second moment of area, I_{xx} (often denoted as I_x) can be computed in Cartesian coordinates as

I_{x} = \iint\limits_{R} y^2\, \mathrm dx\, \mathrm dy

The second moment of the area is crucial in Euler–Bernoulli theory of slender beams.

Product moment of area

More generally, the product moment of area is defined as[3]

I_{xy} = \iint\limits_{R} xy\, \mathrm dx\, \mathrm dy

Parallel axis theorem

A shape with centroidal axis x. The parallel axis theorem can be used to obtain the second moment of area with respect to the x' axis.
Main article: Parallel axis theorem

It is sometimes necessary to calculate the second moment of area of a shape with respect to an x' axis different to the centroidal axis of the shape. However, it is often easier to derive the second moment of area with respect to its centroidal axis, x, and use the parallel axis theorem to derive the second moment of area with respect to the x' axis. The parallel axis theorem states

I_{x'} = I_x + A d^2

where

A is the area of the shape, and
d is the perpendicular distance between the x and x' axes.[4][5]

A similar statement can be made about a y' axis and the parallel centroidal y axis. Or, in general, any centroidal B axis and a parallel B' axis.

Perpendicular axis theorem

For the simplicity of calculation, it is often desired to define the polar moment of area (with respect to a perpendicular axis) in terms of two area moments of inertia (both with respect to in-plane axes). The simplest case relates J_z to I_x and I_y.

J_z = \iint\limits_{R} \rho^2\,\mathrm dA = \iint\limits_{R} (x^2 + y^2)\,\mathrm dA = \iint\limits_{R} x^2\,\mathrm dA + \iint\limits_{R} y^2\,\mathrm dA = I_x + I_y

This relationship relies on the Pythagorean theorem which relates x and y to \rho and on the linearity of integration.

Composite shapes

For more complex areas, it is often easier to divide the area into a series of "simpler" shapes. The second moment of area for the entire shape is the sum of the second moment of areas of all of its parts about a common axis. This can include shapes that are "missing" (i.e. holes, hollow shapes, etc.), in which case the second moment of area of the "missing" areas are subtracted, rather than added. In other words, the second moment of area of "missing" parts are considered negative for the method of composite shapes.

Examples

See list of second moments of area for other shapes.

Rectangle with centroid at the origin

Rectangle with base b and height h.

Consider a rectangle with base b and height h whose centroid is located at the origin. I_x represents the second moment of area with respect to the x-axis; I_y represents the second moment of area with respect to the y-axis; J_z represents the polar moment of inertia with respect to the z-axis.

I_{x} = \iint\limits_{R} y^2\,\mathrm dA = \int^{b/2}_{-b/2} \int^{h/2}_{-h/2} y^2 \,\mathrm dy \,\mathrm dx = \int^{b/2}_{-b/2} \frac{1}{3}\frac{h^3}{4}\,\mathrm dx = \frac{b h^3}{12}
I_{y} = \iint\limits_{R} x^2\,\mathrm dA = \int^{b/2}_{-b/2} \int^{h/2}_{-h/2} x^2 \,\mathrm dy \,\mathrm dx = \int^{b/2}_{-b/2} h x^2\,\mathrm dx = \frac{b^3 h}{12}

Using the perpendicular axis theorem we get the value of J_z.

J_{z} = I_x + I_y = \frac{b h^3}{12} + \frac{h b^3}{12} = \frac{b h}{12}(b^2 + h^2)

Annulus centered at origin

Annulus with inner radius r1 and outer radius r2.

Consider an annulus whose center is at the origin, outside radius is r_2, and inside radius is r_1. Because of the symmetry of the annulus, the centroid also lies at the origin. We can determine the polar moment of inertia, J_z, about the z axis by the method of composite shapes. This polar moment of inertia is equivalent to the polar moment of inertia of a circle with radius r_2 minus the polar moment of inertia of a circle with radius r_1, both centered at the origin. First, let us derive the polar moment of inertia of a circle with radius r with respect to the origin. In this case, it is easier to directly calculate J_z as we already have r^2, which has both an x and y component. Instead of obtaining the second moment of area from Cartesian coordinates as done in the previous section, we shall calculate I_x and J_z directly using Polar Coordinates.

I_{x, circle} = \iint\limits_{R} y^2\,dA = \iint\limits_{R} (r\sin{\theta)}^2\,dA = \int_0^{2\pi}\int_0^r (r\sin{\theta})^2\left(r\,dr\,d\theta\right) =

 = \int_0^{2\pi}\int_0^r r^3\sin^2{\theta}\,dr\,d\theta = \int_0^{2\pi} \frac{r^4\sin^2{\theta}}{4}\,d\theta = \frac{\pi}{4}r^4

J_{z,circle} = \iint\limits_{R} r^2\,dA = \int_0^{2\pi}\int_0^r r^2\left(r\,dr\,d\theta\right) = \int_0^{2\pi}\int_0^r r^3\,dr\,d\theta =

 = \int_0^{2\pi} \frac{r^4}{4}\,d\theta = \frac{\pi}{2}r^4

Now, the polar moment of inertia about the z axis for an annulus is simply, as stated above, the difference of the second moments of area of a circle with radius r_2 and a circle with radius r_1.

J_{z} = J_{z, r_2} - J_{z, r_1} = \frac{\pi}{2}r_2^4 - \frac{\pi}{2}r_1^4 = \frac{\pi}{2}({r_2} ^4 - {r_1} ^4)

Alternatively, we could change the limits on the dr integral the first time around to reflect the fact that there is a hole. This would be done like this.

J_{z} = \iint\limits_{R} r^2\,dA = \int_0^{2\pi}\int_{r_1}^{r_2} r^2\left(r\,dr\,d\theta\right) = \int_0^{2\pi}\int_{r_1}^{r_2} r^3\,dr\,d\theta =

 = \int_0^{2\pi}\left[\frac{r_2^4}{4} - \frac{r_1^4}{4}\right]\,d\theta = \frac{\pi}{2}\left(r_2^4 - r_1^4\right)

Any polygon

A simple polygon.

The second moment of area for any simple polygon on the XY-plane can be computed in general by summing contributions from each segment of the polygon. A polygon is assumed to be counter clock wise (for clockwise polygon all values will be negative with same absolute value)

I_x = \frac{1}{12}\sum_{i=1}^{i=N} ( y_i^2 + y_i y_{i+1} + y_{i+1}^2 ) ( x_i y_{i+1} - x_{i+1} y_i)
I_y = \frac{1}{12}\sum_{i=1}^{i=N} ( x_i^2 + x_i x_{i+1} + x_{i+1}^2 ) (  x_i y_{i+1} - x_{i+1} y_i )
I_{xy} = \frac{1}{24}\sum_{i=1}^{i=N} ( x_i y_{i+1} + 2 x_i y_i + 2 x_{i+1} y_{i+1} + x_{i+1} y_{i}) ( x_i y_{i+1} - x_{i+1} y_i )

where  x_i , y_i (with  x_{n+1} = x_1, y_{n+1} = y_1 ) are the coordinates of any polygon vertex.[6]

See also

References

  1. Beer, Ferdinand P. (2013). Vector Mechanics for Engineers (10th ed.). New York: McGraw-Hill. p. 471. ISBN 978-0-07-339813-6. The term second moment is more proper than the term moment of inertia, since, logically, the latter should be used only to denote integrals of mass (see Sec. 9.11). In engineering practice, however, moment of inertia is used in connection with areas as well as masses.
  2. Pilkey, Walter D. (2002). Analysis and Design of Elastic Beams. John Wiley & Sons, Inc. p. 15. ISBN 978-0-471-38152-5.
  3. Beer, Ferdinand P. (2013). "Chapter 9.8: Product of inertia". Vector Mechanics for Engineers (10th ed.). New York: McGraw-Hill. p. 495. ISBN 978-0-07-339813-6.
  4. Hibbeler, R. C. (2004). Statics and Mechanics of Materials (Second ed.). Pearson Prentice Hall. ISBN 0-13-028127-1.
  5. Beer, Ferdinand P. (2013). "Chapter 9.6: Parallel-axis theorem". Vector Mechanics for Engineers (10th ed.). New York: McGraw-Hill. p. 481. ISBN 978-0-07-339813-6.
  6. "Mechanical Symmetry".

External links

This article is issued from Wikipedia - version of the Saturday, April 23, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.