Flexural rigidity: Difference between revisions
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where <math>E</math> is the [[flexural modulus]] (in Pa), <math>I</math> is the [[second moment of area]] (in m<sup>4</sup>), <math>y</math> is the transverse displacement of the beam at '''x''', and <math>M(x)</math> is the [[bending moment]] at ''x''. The flexural rigidity (stiffness) of the beam is therefore related to both <math>E</math>, a material property, and <math>I</math>, the physical geometry of the beam. If the material exhibits Isotropic behavior then the Flexural Modulus is equal to the Modulus of Elasticity (Young's Modulus). |
where <math>E</math> is the [[flexural modulus]] (in Pa), <math>I</math> is the [[second moment of area]] (in m<sup>4</sup>), <math>y</math> is the transverse displacement of the beam at '''x''', and <math>M(x)</math> is the [[bending moment]] at ''x''. The flexural rigidity (stiffness) of the beam is therefore related to both <math>E</math>, a material property, and <math>I</math>, the physical geometry of the beam. If the material exhibits Isotropic behavior then the Flexural Modulus is equal to the Modulus of Elasticity (Young's Modulus). |
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Flexural rigidity has SI units of [[pascal (unit)|Pa]]·m<sup>4</sup> (which also equals [[newton (unit)|N]]·m²). |
Flexural rigidity has SI units of [[pascal (unit)|Pa]]·m<sup>4</sup> (which also equals [[newton (unit)|N]]·m²), and so it is a standard [[mechanical quantity]]. |
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==Flexural rigidity of a plate (e.g. the lithosphere)== |
==Flexural rigidity of a plate (e.g. the lithosphere)== |
Revision as of 09:32, 17 December 2022
This article needs additional citations for verification. (December 2009) |
Flexural rigidity is defined as the force couple required to bend a fixed non-rigid structure by one unit of curvature, or as the resistance offered by a structure while undergoing bending.
Flexural rigidity of a beam
Although the moment and displacement may vary along the length of the beam or rod, the flexural rigidity (defined as ) is a property of the beam itself and is generally constant. The flexural rigidity, moment, and transverse displacement are related by the following equation along the length of the rod, :
where is the flexural modulus (in Pa), is the second moment of area (in m4), is the transverse displacement of the beam at x, and is the bending moment at x. The flexural rigidity (stiffness) of the beam is therefore related to both , a material property, and , the physical geometry of the beam. If the material exhibits Isotropic behavior then the Flexural Modulus is equal to the Modulus of Elasticity (Young's Modulus).
Flexural rigidity has SI units of Pa·m4 (which also equals N·m²), and so it is a standard mechanical quantity.
Flexural rigidity of a plate (e.g. the lithosphere)
In the study of geology, lithospheric flexure affects the thin lithospheric plates covering the surface of the Earth when a load or force is applied to them. On a geological timescale, the lithosphere behaves elastically (in first approach) and can therefore bend under loading by mountain chains, volcanoes and other heavy objects. Isostatic depression caused by the weight of ice sheets during the last glacial period is an example of the effects of such loading.
The flexure of the plate depends on:
- The plate elastic thickness (usually referred to as effective elastic thickness of the lithosphere).
- The elastic properties of the plate
- The applied load or force
As flexural rigidity of the plate is determined by the Young's modulus, Poisson's ratio and cube of the plate's elastic thickness, it is a governing factor in both (1) and (2).
Flexural Rigidity[1]
= elastic thickness (~5–100 km)
Flexural rigidity of a plate has units of Pa·m3, i.e. one dimension of length less than the same property for the rod, as it refers to the moment per unit length per unit of curvature, and not the total moment. I is termed as moment of inertia. J is denoted as 2nd moment of inertia/polar moment of inertia.
See also
References
- ^ L.D. Landau, E.M. Lifshitz (1986). Theory of Elasticity. Vol. 7 (3rd ed.). Butterworth-Heinemann. p. 42. ISBN 978-0-7506-2633-0.