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applied mechanics Applied mechanics is the branch of science concerned with the motion of any substance that can be experienced or perceived by humans without the help of instruments. In short, when mechanics concepts surpass being theoretical and are applied and e ...
, bending (also known as flexure) characterizes the behavior of a slender structural element subjected to an external
load Load or LOAD may refer to: Aeronautics and transportation *Load factor (aeronautics), the ratio of the lift of an aircraft to its weight *Passenger load factor, the ratio of revenue passenger miles to available seat miles of a particular transpo ...
applied perpendicularly to a longitudinal axis of the element. The structural element is assumed to be such that at least one of its dimensions is a small fraction, typically 1/10 or less, of the other two.Boresi, A. P. and Schmidt, R. J. and Sidebottom, O. M., 1993, Advanced mechanics of materials, John Wiley and Sons, New York. When the length is considerably longer than the width and the thickness, the element is called a
beam Beam may refer to: Streams of particles or energy *Light beam, or beam of light, a directional projection of light energy **Laser beam *Particle beam, a stream of charged or neutral particles **Charged particle beam, a spatially localized grou ...
. For example, a closet rod sagging under the weight of clothes on clothes hangers is an example of a beam experiencing bending. On the other hand, a shell is a structure of any geometric form where the length and the width are of the same order of magnitude but the thickness of the structure (known as the 'wall') is considerably smaller. A large diameter, but thin-walled, short tube supported at its ends and loaded laterally is an example of a shell experiencing bending. In the absence of a qualifier, the term ''bending'' is ambiguous because bending can occur locally in all objects. Therefore, to make the usage of the term more precise, engineers refer to a specific object such as; the ''bending of rods'', the ''bending of beams'', the '' bending of plates'', Timoshenko, S. and Woinowsky-Krieger, S., 1959, Theory of plates and shells, McGraw-Hill. the '' bending of shells''Libai, A. and Simmonds, J. G., 1998, The nonlinear theory of elastic shells, Cambridge University Press. and so on.


Quasi-static bending of beams

A beam deforms and stresses develop inside it when a transverse load is applied on it. In the quasi-static case, the amount of bending
deflection Deflection or deflexion may refer to: Board games * Deflection (chess), a tactic that forces an opposing chess piece to leave a square * Khet (game), formerly ''Deflexion'', an Egyptian-themed chess-like game using lasers Mechanics * Deflection ...
and the stresses that develop are assumed not to change over time. In a horizontal beam supported at the ends and loaded downwards in the middle, the material at the over-side of the beam is compressed while the material at the underside is stretched. There are two forms of internal stresses caused by lateral loads: * Shear stress parallel to the lateral loading plus complementary shear stress on planes perpendicular to the load direction; * Direct compressive stress in the upper region of the beam, and direct tensile stress in the lower region of the beam. These last two forces form a
couple Couple or couples may refer to : Basic meaning *Couple (app), a mobile app which provides a mobile messaging service for two people *Couple (mechanics), a system of forces with a resultant moment but no resultant force *Couple (relationship), tw ...
or
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as they are equal in magnitude and opposite in direction. This bending moment resists the sagging deformation characteristic of a beam experiencing bending. The stress distribution in a beam can be predicted quite accurately when some simplifying assumptions are used.


Euler–Bernoulli bending theory

In the Euler–Bernoulli theory of slender beams, a major assumption is that 'plane sections remain plane'. In other words, any deformation due to shear across the section is not accounted for (no shear deformation). Also, this linear distribution is only applicable if the maximum stress is less than the
yield stress In materials science and engineering, the yield point is the point on a stress-strain curve that indicates the limit of elastic behavior and the beginning of plastic behavior. Below the yield point, a material will deform elastically and wi ...
of the material. For stresses that exceed yield, refer to article
plastic bending Plastic bending is a nonlinear behavior particular to members made of ductile materials that frequently achieve much greater ultimate bending strength than indicated by a linear elastic bending analysis. In both the plastic and elastic bending ana ...
. At yield, the maximum stress experienced in the section (at the furthest points from the neutral axis of the beam) is defined as the flexural strength. Consider beams where the following are true: * The beam is originally straight and slender, and any taper is slight * The material is isotropic (or orthotropic), linear elastic, and
homogeneous Homogeneity and heterogeneity are concepts often used in the sciences and statistics relating to the uniformity of a substance or organism. A material or image that is homogeneous is uniform in composition or character (i.e. color, shape, siz ...
across any cross section (but not necessarily along its length) * Only small deflections are considered In this case, the equation describing beam deflection (w) can be approximated as: :\cfrac=\frac where the second derivative of its deflected shape with respect to x is interpreted as its curvature, E is the Young's modulus, I is the
area moment of inertia The second moment of area, or second area moment, or quadratic moment of area and also known as the area moment of inertia, is a geometrical property of an area which reflects how its points are distributed with regard to an arbitrary axis. The ...
of the cross-section, and M is the internal bending moment in the beam. If, in addition, the beam is
homogeneous Homogeneity and heterogeneity are concepts often used in the sciences and statistics relating to the uniformity of a substance or organism. A material or image that is homogeneous is uniform in composition or character (i.e. color, shape, siz ...
along its length as well, and not tapered (i.e. constant cross section), and deflects under an applied transverse load q(x), it can be shown that: : EI~\cfrac = q(x) This is the Euler–Bernoulli equation for beam bending. After a solution for the displacement of the beam has been obtained, the bending moment (M) and shear force (Q) in the beam can be calculated using the relations : M(x) = -EI~\cfrac ~;~~ Q(x) = \cfrac. Simple beam bending is often analyzed with the Euler–Bernoulli beam equation. The conditions for using simple bending theory are: # The beam is subject to
pure bending Pure bending ( Theory of simple bending) is a condition of stress where a bending moment is applied to a beam without the simultaneous presence of axial, shear, or torsional forces. Pure bending occurs only under a constant bending moment (M) sinc ...
. This means that the
shear force In solid mechanics, shearing forces are unaligned forces acting on one part of a body in a specific direction, and another part of the body in the opposite direction. When the forces are collinear (aligned with each other), they are called t ...
is zero, and that no torsional or axial loads are present. # The material is
isotropic Isotropy is uniformity in all orientations; it is derived . Precise definitions depend on the subject area. Exceptions, or inequalities, are frequently indicated by the prefix ' or ', hence ''anisotropy''. ''Anisotropy'' is also used to describe ...
(or orthotropic) and
homogeneous Homogeneity and heterogeneity are concepts often used in the sciences and statistics relating to the uniformity of a substance or organism. A material or image that is homogeneous is uniform in composition or character (i.e. color, shape, siz ...
. # The material obeys Hooke's law (it is linearly elastic and will not deform plastically). # The beam is initially straight with a cross section that is constant throughout the beam length. # The beam has an axis of symmetry in the plane of bending. # The proportions of the beam are such that it would fail by bending rather than by crushing, wrinkling or sideways buckling. # Cross-sections of the beam remain plane during bending. Compressive and tensile forces develop in the direction of the beam axis under bending loads. These forces induce stresses on the beam. The maximum compressive stress is found at the uppermost edge of the beam while the maximum tensile stress is located at the lower edge of the beam. Since the stresses between these two opposing maxima vary linearly, there therefore exists a point on the linear path between them where there is no bending stress. The locus of these points is the neutral axis. Because of this area with no stress and the adjacent areas with low stress, using uniform cross section beams in bending is not a particularly efficient means of supporting a load as it does not use the full capacity of the beam until it is on the brink of collapse. Wide-flange beams ( -beams) and truss girders effectively address this inefficiency as they minimize the amount of material in this under-stressed region. The classic formula for determining the bending stress in a beam under simple bending is:Gere, J. M. and Timoshenko, S.P., 1997, Mechanics of Materials, PWS Publishing Company. :\sigma_x = \frac = \frac where * is the bending stress *M_z – the moment about the neutral axis *y – the perpendicular distance to the neutral axis *I_z – the second moment of area about the neutral axis ''z''. *W_z - the Resistance Moment about the neutral axis ''z''. W_z = I_z / y


Extensions of Euler-Bernoulli beam bending theory


Plastic bending

The equation \sigma = \tfrac is valid only when the stress at the extreme fiber (i.e., the portion of the beam farthest from the neutral axis) is below the
yield stress In materials science and engineering, the yield point is the point on a stress-strain curve that indicates the limit of elastic behavior and the beginning of plastic behavior. Below the yield point, a material will deform elastically and wi ...
of the material from which it is constructed. At higher loadings the stress distribution becomes non-linear, and ductile materials will eventually enter a ''plastic hinge'' state where the magnitude of the stress is equal to the yield stress everywhere in the beam, with a discontinuity at the neutral axis where the stress changes from tensile to compressive. This plastic hinge state is typically used as a
limit state Limit State Design (LSD), also known as Load And Resistance Factor Design (LRFD), refers to a design method used in structural engineering. A limit state is a condition of a structure beyond which it no longer fulfills the relevant design criteria ...
in the design of steel structures.


Complex or asymmetrical bending

The equation above is only valid if the cross-section is symmetrical. For homogeneous beams with asymmetrical sections, the maximum bending stress in the beam is given by : \sigma_x(y,z) = - \frac y + \frac z where y,z are the coordinates of a point on the cross section at which the stress is to be determined as shown to the right, M_y and M_z are the bending moments about the y and z centroid axes, I_y and I_z are the second moments of area (distinct from moments of inertia) about the y and z axes, and I_ is the product of moments of area. Using this equation it is possible to calculate the bending stress at any point on the beam cross section regardless of moment orientation or cross-sectional shape. Note that M_y, M_z, I_y, I_z, I_ do not change from one point to another on the cross section.


Large bending deformation

For large deformations of the body, the stress in the cross-section is calculated using an extended version of this formula. First the following assumptions must be made: # Assumption of flat sections – before and after deformation the considered section of body remains flat (i.e., is not swirled). # Shear and normal stresses in this section that are perpendicular to the normal vector of cross section have no influence on normal stresses that are parallel to this section. Large bending considerations should be implemented when the bending radius \rho is smaller than ten section heights h: :\rho < 10 h. With those assumptions the stress in large bending is calculated as: : \sigma = \frac + \frac + y where :F is the normal
force In physics, a force is an influence that can change the motion of an object. A force can cause an object with mass to change its velocity (e.g. moving from a state of rest), i.e., to accelerate. Force can also be described intuitively as a p ...
:A is the section area :M is the bending moment :\rho is the local bending radius (the radius of bending at the current section) : is the area moment of inertia along the ''x''-axis, at the y place (see Steiner's theorem) :y is the position along ''y''-axis on the section area in which the stress \sigma is calculated. When bending radius \rho approaches infinity and y\ll\rho, the original formula is back: :\sigma = \pm \frac .


Timoshenko bending theory

In 1921,
Timoshenko Tymoshenko ( uk, Тимошенко, translit=Tymošenko), Timoshenko (russian: Тимошенко), or Tsimashenka/Cimašenka ( be, Цімашэнка) is a surname of Ukrainian origin. It derives from the Christian name Timothy, and its Ukrainian ...
improved upon the Euler–Bernoulli theory of beams by adding the effect of shear into the beam equation. The kinematic assumptions of the Timoshenko theory are: * normals to the axis of the beam remain straight after deformation * there is no change in beam thickness after deformation However, normals to the axis are not required to remain perpendicular to the axis after deformation. The equation for the quasistatic bending of a linear elastic, isotropic, homogeneous beam of constant cross-section beam under these assumptions is : EI~\cfrac = q(x) - \cfrac~\cfrac where I is the
area moment of inertia The second moment of area, or second area moment, or quadratic moment of area and also known as the area moment of inertia, is a geometrical property of an area which reflects how its points are distributed with regard to an arbitrary axis. The ...
of the cross-section, A is the cross-sectional area, G is the shear modulus, k is a shear correction factor, and q(x) is an applied transverse load. For materials with Poisson's ratios (\nu) close to 0.3, the shear correction factor for a rectangular cross-section is approximately : k = \cfrac The rotation (\varphi(x)) of the normal is described by the equation : \cfrac = -\cfrac -\cfrac The bending moment (M) and the shear force (Q) are given by : M(x) = -EI~ \cfrac ~;~~ Q(x) = kAG\left(\cfrac-\varphi\right) = -EI~\cfrac = \cfrac


Beams on elastic foundations

According to Euler–Bernoulli, Timoshenko or other bending theories, the beams on elastic foundations can be explained. In some applications such as rail tracks, foundation of buildings and machines, ships on water, roots of plants etc., the beam subjected to loads is supported on continuous elastic foundations (i.e. the continuous reactions due to external loading is distributed along the length of the beam)


Dynamic bending of beams

The dynamic bending of beams,Han, S. M, Benaroya, H. and Wei, T., 1999, "Dynamics of transversely vibrating beams using four engineering theories," ''Journal of Sound and Vibration'', vol. 226, no. 5, pp. 935–988. also known as flexural vibrations of beams, was first investigated by
Daniel Bernoulli Daniel Bernoulli FRS (; – 27 March 1782) was a Swiss mathematician and physicist and was one of the many prominent mathematicians in the Bernoulli family from Basel. He is particularly remembered for his applications of mathematics to mechan ...
in the late 18th century. Bernoulli's equation of motion of a vibrating beam tended to overestimate the natural frequencies of beams and was improved marginally by Rayleigh in 1877 by the addition of a mid-plane rotation. In 1921 Stephen Timoshenko improved the theory further by incorporating the effect of shear on the dynamic response of bending beams. This allowed the theory to be used for problems involving high frequencies of vibration where the dynamic Euler–Bernoulli theory is inadequate. The Euler-Bernoulli and Timoshenko theories for the dynamic bending of beams continue to be used widely by engineers.


Euler–Bernoulli theory

The Euler–Bernoulli equation for the dynamic bending of slender, isotropic, homogeneous beams of constant cross-section under an applied transverse load q(x,t) isThomson, W. T., 1981, Theory of Vibration with Applications : EI~\cfrac + m~\cfrac = q(x,t) where E is the Young's modulus, I is the area moment of inertia of the cross-section, w(x,t) is the deflection of the neutral axis of the beam, and m is mass per unit length of the beam.


Free vibrations

For the situation where there is no transverse load on the beam, the bending equation takes the form : EI~\cfrac + m~\cfrac = 0 Free, harmonic vibrations of the beam can then be expressed as : w(x,t) = \text
hat(x)~e^ A hat is a head covering which is worn for various reasons, including protection against weather conditions, ceremonial reasons such as university graduation, religious reasons, safety, or as a fashion accessory. Hats which incorporate mecha ...
\quad \implies \quad \cfrac = -\omega^2~w(x,t) and the bending equation can be written as : EI~\cfrac - m\omega^2\hat = 0 The general solution of the above equation is : \hat = A_1\cosh(\beta x) + A_2\sinh(\beta x) + A_3\cos(\beta x) + A_4\sin(\beta x) where A_1,A_2,A_3,A_4 are constants and \beta := \left(\cfrac~\omega^2\right)^


Timoshenko–Rayleigh theory

In 1877, Rayleigh proposed an improvement to the dynamic Euler–Bernoulli beam theory by including the effect of rotational inertia of the cross-section of the beam. Timoshenko improved upon that theory in 1922 by adding the effect of shear into the beam equation. Shear deformations of the normal to the mid-surface of the beam are allowed in the Timoshenko–Rayleigh theory. The equation for the bending of a linear elastic, isotropic, homogeneous beam of constant cross-section under these assumptions isRosinger, H. E. and Ritchie, I. G., 1977, ''On Timoshenko's correction for shear in vibrating isotropic beams,'' J. Phys. D: Appl. Phys., vol. 10, pp. 1461–1466. : \begin & EI~\frac + m~\frac - \left(J + \frac\right)\frac + \frac~\frac \\ pt= & q(x,t) + \frac~\frac - \frac~\frac \end where J = \tfrac is the
polar moment of inertia The second polar moment of area, also known (incorrectly, colloquially) as "polar moment of inertia" or even "moment of inertia", is a quantity used to describe resistance to torsional deformation (deflection), in cylindrical (or non-cylindrical) ...
of the cross-section, m = \rho A is the mass per unit length of the beam, \rho is the density of the beam, A is the cross-sectional area, G is the shear modulus, and k is a shear correction factor. For materials with Poisson's ratios (\nu) close to 0.3, the shear correction factor are approximately : \begin k &= \frac \quad \text\\ pt &= \frac \quad \text \end


Free vibrations

For free, harmonic vibrations the Timoshenko–Rayleigh equations take the form : EI~\cfrac + m\omega^2\left(\cfrac + \cfrac\right)\cfrac + m\omega^2\left(\cfrac-1\right)~\hat = 0 This equation can be solved by noting that all the derivatives of w must have the same form to cancel out and hence as solution of the form e^ may be expected. This observation leads to the characteristic equation : \alpha~k^4 + \beta~k^2 + \gamma = 0 ~;~~ \alpha := EI ~,~~ \beta := m\omega^2\left(\cfrac + \cfrac\right) ~,~~ \gamma := m\omega^2\left(\cfrac-1\right) The solutions of this quartic equation are : k_1 = +\sqrt ~,~~ k_2 = -\sqrt ~,~~ k_3 = +\sqrt ~,~~ k_4 = -\sqrt where : z_+ := \cfrac ~,~~ z_-:= \cfrac The general solution of the Timoshenko-Rayleigh beam equation for free vibrations can then be written as : \hat = A_1~e^ + A_2~e^ + A_3~e^ + A_4~e^


Quasistatic bending of plates

The defining feature of beams is that one of the dimensions is much ''larger'' than the other two. A structure is called a plate when it is flat and one of its dimensions is much ''smaller'' than the other two. There are several theories that attempt to describe the deformation and stress in a plate under applied loads two of which have been used widely. These are * the Kirchhoff–Love theory of plates (also called classical plate theory) * the Mindlin–Reissner plate theory (also called the first-order shear theory of plates)


Kirchhoff–Love theory of plates

The assumptions of Kirchhoff–Love theory are * straight lines normal to the mid-surface remain straight after deformation * straight lines normal to the mid-surface remain normal to the mid-surface after deformation * the thickness of the plate does not change during a deformation. These assumptions imply that : \begin u_\alpha(\mathbf) & = - x_3~\frac = - x_3~w^0_ ~;~~\alpha=1,2 \\ u_3(\mathbf) & = w^0(x_1, x_2) \end where \mathbf is the displacement of a point in the plate and w^0 is the displacement of the mid-surface. The strain-displacement relations are : \begin \varepsilon_ & = - x_3~w^0_ \\ \varepsilon_ & = 0 \\ \varepsilon_ & = 0 \end The equilibrium equations are : M_ + q(x) = 0 ~;~~ M_ := \int_^h x_3~\sigma_~dx_3 where q(x) is an applied load normal to the surface of the plate. In terms of displacements, the equilibrium equations for an isotropic, linear elastic plate in the absence of external load can be written as : w^0_ + 2~w^0_ + w^0_ = 0 In direct tensor notation, : \nabla^2\nabla^2 w = 0


Mindlin–Reissner theory of plates

The special assumption of this theory is that normals to the mid-surface remain straight and inextensible but not necessarily normal to the mid-surface after deformation. The displacements of the plate are given by : \begin u_\alpha(\mathbf) & = - x_3~\varphi_\alpha ~;~~\alpha=1,2 \\ u_3(\mathbf) & = w^0(x_1, x_2) \end where \varphi_\alpha are the rotations of the normal. The strain-displacement relations that result from these assumptions are : \begin \varepsilon_ & = - x_3~\varphi_ \\ \varepsilon_ & = \cfrac~\kappa\left(w^0_- \varphi_\alpha\right) \\ \varepsilon_ & = 0 \end where \kappa is a shear correction factor. The equilibrium equations are : \begin & M_-Q_\alpha = 0 \\ & Q_+q = 0 \end where : Q_\alpha := \kappa~\int_^h \sigma_~dx_3


Dynamic bending of plates


Dynamics of thin Kirchhoff plates

The dynamic theory of plates determines the propagation of waves in the plates, and the study of standing waves and vibration modes. The equations that govern the dynamic bending of Kirchhoff plates are : M_ - q(x,t) = J_1~\ddot^0 - J_3~\ddot^0_ where, for a plate with density \rho = \rho(x), : J_1 := \int_^h \rho~dx_3 ~;~~ J_3 := \int_^h x_3^2~\rho~dx_3 and : \ddot^0 = \frac ~;~~ \ddot^0_ = \frac The figures below show some vibrational modes of a circular plate. File:Drum vibration mode01.gif, mode ''k'' = 0, ''p'' = 1 File:Drum vibration mode02.gif, mode ''k'' = 0, ''p'' = 2 File:Drum vibration mode12.gif, mode ''k'' = 1, ''p'' = 2


See also

* Bending moment *
Bending Machine (flat metal bending) A bending machine is a forming machine tool (DIN 8586). Its purpose is to assemble a bend on a workpiece. A bend is manufactured by using a bending tool during a linear or rotating move. The detailed classification can be done with the help of the ...
* Brake (sheet metal bending) *
Brazier effect The Brazier effect was first discovered in 1927 by Brazier. He showed that when an initially straight tube was bent uniformly, the longitudinal tension and compression which resist the applied bending moment also tend to flatten or ovalise the cro ...
* Bending of plates *
Bending (metalworking) Bending is a manufacturing process that produces a V-shape, U-shape, or channel shape along a straight axis in ductile materials, most commonly sheet metal.Manufacturing Processes Reference Guide, Industrial Press Inc., 1994. Commonly used equ ...
*
Continuum mechanics Continuum mechanics is a branch of mechanics that deals with the mechanical behavior of materials modeled as a continuous mass rather than as discrete particles. The French mathematician Augustin-Louis Cauchy was the first to formulate such m ...
*
Contraflexure In solid mechanics, a point along a beam under a lateral load is known as a point of contraflexure if the bending moment about the point equals zero. In a bending moment diagram, it is the point at which the bending moment curve intersects with ...
* Deflection (engineering) *
Flexure bearing A flexure bearing is a category of flexure which is engineered to be compliant in one or more angular degrees of freedom. Flexure bearings are often part of compliant mechanisms. Flexure bearings serve much of the same function as conventional ...
*
List of area moments of inertia The following is a list of second moments of area of some shapes. The second moment of area, also known as area moment of inertia, is a geometrical property of an area which reflects how its points are distributed with respect to an arbitrary axis ...
*
Pipe bending Tube bending is any metal forming processes used to permanently form pipes or tubing. Tube bending may be form-bound or use freeform-bending procedures, and it may use heat supported or cold forming procedures. Form bound bending procedures l ...
* Shear and moment diagram * Shear strength *
Sandwich theory Sandwich theoryPlantema, F, J., 1966, Sandwich Construction: The Bending and Buckling of Sandwich Beams, Plates, and Shells, Jon Wiley and Sons, New York.Zenkert, D., 1995, An Introduction to Sandwich Construction, Engineering Materials Advisory S ...
* Vibration *
Vibration of plates The vibration of plates is a special case of the more general problem of mechanical vibrations. The equations governing the motion of plates are simpler than those for general three-dimensional objects because one of the dimensions of a plate is ...


References


External links


Flexure formulae

Beam stress & deflection, beam deflection tables
{{Topics in continuum mechanics Statics Elasticity (physics) Structural system Deformation (mechanics)