Shear and moment diagram for a simply supported beam with a concentrated load at midspan.(right)
A bending moment is the reaction induced in a structural element when an external force or moment is applied to the element causing the element to bend.^{[1]}^{[2]} The most common or simplest structural element subjected to bending moments is the beam. The example shows a beam which is simply supported at both ends. Simply supported means that each end of the beam can rotate, therefore each end support has no bending moment. The ends can only react to the shear load. Other beams can have both ends fixed, therefore each end support has both bending moment and shear reaction loads. Beams can also have one end fixed and one end simply supported. The simplest type of beam is the cantilever, which is fixed at one end and is free at the other end (neither simple or fixed). In reality, beam supports are usually neither absolutely fixed nor absolutely rotating freely.
The internal reaction loads in a crosssection of the structural element can be resolved into a resultant force and a resultant couple. For equilibrium, the moment created by external forces (and external moments) must be balanced by the couple induced by the internal loads. The resultant internal couple is called the bending moment while the resultant internal force is called the shear force (if it is transverse to the plane of element) or the normal force (if it is along the plane of the element).
The bending moment at a section through a structural element may be defined as "the sum of the moments about that section of all external forces acting to one side of that section". The forces and moments on either side of the section must be equal in order to counteract each other and maintain a state of equilibrium so the same bending moment will result from summing the moments, regardless of which side of the section is selected. If clockwise bending moments are taken as negative, then a negative bending moment within an element will cause "sagging", and a positive moment will cause "hogging". It is therefore clear that a point of zero bending moment within a beam is a point of contraflexure—that is the point of transition from hogging to sagging or vice versa.
Moments and torques are measured as a force multiplied by a distance so they have as unit newtonmetres (N·m), or poundfoot or footpound (ft·lb). The concept of bending moment is very important in engineering (particularly in civil and mechanical engineering) and physics.
Contents

Background 1

Computing the moment of force 2

Example 2.1

Sign conventions 2.2

Computing the bending moment 3

Example 3.1

Sign convention 3.2

See also 4

References 5

External links 6
Background
Tensile and compressive stresses increase proportionally with bending moment, but are also dependent on the second moment of area of the crosssection of a beam (that is, the shape of the crosssection, such as a circle, square or Ibeam being common structural shapes). Failure in bending will occur when the bending moment is sufficient to induce tensile stresses greater than the yield stress of the material throughout the entire crosssection. In structural analysis, this bending failure is called a plastic hinge, since the full load carrying ability of the structural element is not reached until the full crosssection is past the yield stress. It is possible that failure of a structural element in shear may occur before failure in bending, however the mechanics of failure in shear and in bending are different.
Moments are calculated by multiplying the external vector forces (loads or reactions) by the vector distance at which they are applied. When analysing an entire element, it is sensible to calculate moments at both ends of the element, at the beginning, centre and end of any uniformly distributed loads, and directly underneath any point loads. Of course any "pinjoints" within a structure allow free rotation, and so zero moment occurs at these points as there is no way of transmitting turning forces from one side to the other.
It is more common to use the convention that a clockwise bending moment to the left of the point under consideration is taken as positive. This then corresponds to the second derivative of a function which, when positive, indicates a curvature that is 'lower at the centre' i.e. sagging. When defining moments and curvatures in this way calculus can be more readily used to find slopes and deflections.
Critical values within the beam are most commonly annotated using a bending moment diagram, where negative moments are plotted to scale above a horizontal line and positive below. Bending moment varies linearly over unloaded sections, and parabolically over uniformly loaded sections.
Engineering descriptions of the computation of bending moments can be confusing because of unexplained sign conventions and implicit assumptions. The descriptions below use vector mechanics to compute moments of force and bending moments in an attempt to explain, from first principles, why particular sign conventions are chosen.
Computing the moment of force
Computing the moment of force in a beam.
An important part of determining bending moments in practical problems is the computation of moments of force. Let \mathbf{F} be a force vector acting at a point A in a body. The moment of this force about a reference point (O) is defined as^{[2]}

\mathbf{M} = \mathbf{r} \times \mathbf{F}
where \mathbf{M} is the moment vector and \mathbf{r} is the position vector from the reference point (O) to the point of application of the force (A). The \times symbol indicates the vector cross product. For many problems, it is more convenient to compute the moment of force about an axis that passes through the reference point O. If the unit vector along the axis is \mathbf{e}, the moment of force about the axis is defined as

M = \mathbf{e}\cdot\mathbf{M} = \mathbf{e}\cdot(\mathbf{r} \times \mathbf{F})
where \cdot indicates the vector dot product.
Example
The adjacent figure shows a beam that is acted upon by a force F. If the coordinate system is defined by the three unit vectors \mathbf{e}_x, \mathbf{e}_y, \mathbf{e}_z, we have the following

\mathbf{F} = 0\,\mathbf{e}_x  F\,\mathbf{e}_y + 0\,\mathbf{e}_z \quad \text{and} \quad \mathbf{r} = x\,\mathbf{e}_x + 0\,\mathbf{e}_y + 0\,\mathbf{e}_z \,.
Therefore,

\mathbf{M} = \mathbf{r}\times\mathbf{F} = \left\begin{matrix}\mathbf{e}_x & \mathbf{e}_y & \mathbf{e}_z \\ x & 0 & 0 \\ 0 & F & 0 \end{matrix}\right = Fx\,\mathbf{e}_z \,.
The moment about the axis \mathbf{e}_z is then

M_z = \mathbf{e}_z\cdot\mathbf{M} = Fx \,.
Sign conventions
The negative value suggests that a moment that tends to rotate a body clockwise around an axis should have a negative sign. However, the actual sign depends on the choice of the three axes \mathbf{e}_x, \mathbf{e}_y, \mathbf{e}_z. For instance, if we choose another right handed coordinate system with \mathbf{E}_x = \mathbf{e}_x, \mathbf{E}_y = \mathbf{e}_z, \mathbf{E}_z = \mathbf{e}_y, we have

\mathbf{F} = 0\,\mathbf{E}_x + 0\,\mathbf{E}_y F\,\mathbf{E}_z \quad \text{and} \quad \mathbf{r} = x\,\mathbf{E}_x + 0\,\mathbf{E}_y + 0\,\mathbf{E}_z \,.
Then,

\mathbf{M} = \mathbf{r}\times\mathbf{F} = \left\begin{matrix}\mathbf{E}_x & \mathbf{E}_y & \mathbf{E}_z \\ x & 0 & 0 \\ 0 & 0 & F \end{matrix}\right = Fx\,\mathbf{E}_y \quad \text{and} \quad M_y = \mathbf{E}_y\cdot\mathbf{M} = Fx \,.
For this new choice of axes, a positive moment tends to rotate body clockwise around an axis.
Computing the bending moment
In a rigid body or in an unconstrained deformable body, the application of a moment of force causes a pure rotation. But if a deformable body is constrained, it develops internal forces in response to the external force so that equilibrium is maintained. An example is shown in the figure below. These internal forces will cause local deformations in the body.
For equilibrium, the sum of the internal force vectors is equal to the applied external force and the sum of the moment vectors created by the internal forces is equal to the moment of the external force. The internal force and moment vectors are oriented in such a way that the total force (internal + external) and moment (external + internal) of the system is zero. The internal moment vector is called the bending moment.^{[1]}
Though bending moments have been used to determine the stress states in arbitrary shaped structures, the physical interpretation of the computed stresses is problematic. However, physical interpretations of bending moments in beams and plates have a straightforward interpretation as the stress resultants in a crosssection of the structural element. For example, in a beam in the figure, the bending moment vector due to stresses in the crosssection A perpendicular to the xaxis is given by

\mathbf{M}_x = \int_A \mathbf{r} \times (\sigma_{xx} \mathbf{e}_x + \sigma_{xy} \mathbf{e}_y + \sigma_{xz} \mathbf{e}_z)\, dA \quad \text{where} \quad \mathbf{r} = y\,\mathbf{e}_y + z\,\mathbf{e}_z \,.
Expanding this expression we have,

\mathbf{M}_x = \int_A \left(y\sigma_{xx}\mathbf{e}_z + y\sigma_{xz}\mathbf{e}_x + z\sigma_{xx}\mathbf{e}_y  z\sigma_{xy}\mathbf{e}_x\right)dA =: M_{xx}\,\mathbf{e}_x + M_{xy}\,\mathbf{e}_y + M_{xz}\,\mathbf{e}_z\,.
We define the bending moment components as

\begin{bmatrix} M_{xx} \\ M_{xy} \\M_{xz} \end{bmatrix} := \int_A \begin{bmatrix} y\sigma_{xz}  z\sigma_{xy} \\ z\sigma_{xx} \\ y\sigma_{xx} \end{bmatrix}\,dA \,.
The internal moments are computed about an origin that is at the neutral axis of the beam or plate and the integration is through the thickness (h)
Example
Computing the bending moment in a beam.
In the beam shown in the adjacent figure, the external forces are the applied force at point A (F\mathbf{e}_y) and the reactions at the two support points O and B (\mathbf{R}_O = R_O\mathbf{e}_y and \mathbf{R}_B = R_B\mathbf{e}_y). The reactions can be computed using balances of forces and moments about point A, i.e.,

R_O + R_B  F = 0 \quad \text{and} \quad \mathbf{r}_A\times\mathbf{R}_O + \mathbf{r}_B\times\mathbf{R}_B = \mathbf{0} \,.
If L is the length of the beam, we have

\mathbf{r}_A = x_A\mathbf{e}_x \quad \text{and} \quad \mathbf{r}_B = (Lx_A)\mathbf{e}_x \,.
If we solve for the reactions we have

R_O = \left(1  \frac{x_A}{L}\right) F \quad \text{and} \quad R_B = \frac{x_A}{L}\,F \,.
Looking at the free body diagram of the part of the beam to the left of point X, the total moment of the external forces about the point X is

\mathbf{M} = (\mathbf{r}_X\mathbf{r}_A)\times\mathbf{F}  \mathbf{r}_X\times\mathbf{R}_O = \left[(x_Ax)\mathbf{e}_x\right]\times\left(F\mathbf{e}_y\right)  \left(x\mathbf{e}_x\right)\times\left(R_O\mathbf{e}_y\right) \,.
If we compute the cross products, we have

\mathbf{M} = \left\begin{matrix}\mathbf{e}_x & \mathbf{e}_y & \mathbf{e}_z \\ x_A  x & 0 & 0 \\ 0 & F & 0 \end{matrix}\right  \left\begin{matrix}\mathbf{e}_x & \mathbf{e}_y & \mathbf{e}_z \\ x & 0 & 0 \\ 0 & R_0 & 0 \end{matrix}\right = F(xx_A)\,\mathbf{e}_z R_0x\,\mathbf{e}_z = \frac{F x_A}{L}(Lx)\,\mathbf{e}_z \,.
For this situation, the only nonzero component of the bending moment is

\mathbf{M}_{xz} = \left[\int_z\int_{h/2}^{h/2} y\,\sigma_{xx}\,dy\,dz\right]\mathbf{e}_z \,.
For the sum of the moments at X about the axis \mathbf{e}_z to be zero, we require

\mathbf{M} + \mathbf{M}_{xz} = \mathbf{0} \quad \text{or} \quad \frac{F x_A}{L}(Lx) + M_{xz} = 0 \quad \text{or} \quad M_{xz} =\frac{F x_A}{L}(Lx) \,.
At x = x_A, we have M_{xz} = Fx_A(Lx_A)/L.
Sign convention
In the above discussion, it is implicitly assumed that the bending moment is positive when the top of the beam is compressed. That can be seen if we consider a linear distribution of stress in the beam and find the resulting bending moment. Let the top of the beam be in compression with a stress \sigma_0 and let the bottom of the beam have a stress \sigma_0. Then the stress distribution in the beam is \sigma_{xx}(y) = y\sigma_0. The bending moment due to these stresses is

M_{xz} = \left[\int_z\int_{h/2}^{h/2} y\,(y\sigma_0)\,dy\,dz\right] = \sigma_0\,I
where I is the area moment of inertia of the crosssection of the beam. Therefore the bending moment is positive when the top of the beam is in compression.
Many authors follow a different convention in which the stress resultant M_{xz} is defined as

\mathbf{M}_{xz} = \left[\int_z\int_{h/2}^{h/2} y\,\sigma_{xx}\,dy\,dz\right]\mathbf{e}_z \,.
In that case, positive bending moments imply that the top of the beam is in tension. Of course, the definition of top depends on the coordinate system being used. In the examples above, the top is the location with the largest ycoordinate.
See also
References
External links

Stress resultants for beams

Bending Moment Calculator online
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