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Torque Generation
Storyboard

The torque is generated by a force applied at a certain distance from the axis of rotation. Forces on a point on the axis of rotation only lead to translation and do not induce changes in rotation or torque.

The shortest distance between the point that attacks the force and the axis is called the arm and this is always perpendicular to the axis. A force parallel to the arm only generates shaft translation so that only the forces perpendicular to the arm generate torque.

Finally it is seen that the torque is greater the greater the arm and the greater the force perpendicular to the arm.

>Model

ID:(1416, 0)


Force and Torque
Definition

As we have seen, torque plays a role analogous to force in the case of rotation:

$F\longleftrightarrow T$



To establish the equations of motion, we can recall how force was defined in terms of momentum:

$F=\displaystyle\frac{\Delta p}{\Delta t}$



and how torque was defined:

$T=\displaystyle\frac{\Delta L}{\Delta t}$



We can establish a relationship between the two to describe the generation of torque based on force:

Hence, we must first define what the equivalent of Momentum is in the context of rotation.

ID:(325, 0)


Center of mass (CM) concept
Image

If one considers the distribution of mass in space, it should always be possible to identify a point where the force exerted by the mass on one side is equal to the force generated on the other side:

This concept implies that for any orientation of an object, a point of support can be located, at which the object is in balance. Each of these points corresponds to a vertical line. By repeating this process with different orientations of the object, it eventually becomes evident that the vertical lines intersect at a particular point within the object. This point is referred to as the center of mass (CM). In essence, the center of mass is the unique point within the object where, regardless of its orientation, equilibrium is always achieved.

ID:(323, 0)


Definition of the center of mass (CM)
Note

One can define the center of mass as the point at which all the vertical lines drawn through points where the system is in equilibrium intersect:

ID:(11603, 0)


Path of a body with translation and rotation
Quote

Any object that both translates and rotates does so in a manner that:

• its translational motion can be described as if all the mass were concentrated at its center of mass,
• its rotation occurs around the center of mass as if it were not undergoing translation.

ID:(11604, 0)


Torque, right hand rule
Exercise

The orientation of torque can be determined using the right-hand rule: if you point your fingers in the direction of the radius and rotate in the direction of the force,

ID:(11602, 0)


Torque Generation
Storyboard

The torque is generated by a force applied at a certain distance from the axis of rotation. Forces on a point on the axis of rotation only lead to translation and do not induce changes in rotation or torque. The shortest distance between the point that attacks the force and the axis is called the arm and this is always perpendicular to the axis. A force parallel to the arm only generates shaft translation so that only the forces perpendicular to the arm generate torque. Finally it is seen that the torque is greater the greater the arm and the greater the force perpendicular to the arm.

Variables

Symbol
Text
Variable
Value
Units
Calculate
MKS Value
MKS Units
$F$
F
Force
N
$d_1$
d_1
Force - axis distance (arm) 1
m
$d_2$
d_2
Force - axis distance (arm) 2
m
$F_1$
F_1
Force 1
N
$F_2$
F_2
Force 2
N
$F_g$
F_g
Gravitational Force
N
$m_g$
m_g
Gravitational mass
kg
$r$
r
Radius
m
$T$
T
Torque
N m

Calculations


First, select the equation:   to ,  then, select the variable:   to 
Symbol
Equation
Solved
Translated

Calculations

Symbol
Equation
Solved
Translated

 Variable   Given   Calculate   Target :   Equation   To be used


Equations

In the case of a balance, a gravitational force acts on each arm, generating a torque

equation=4431

If the lengths of the arms are $d_i$ and the forces are $F_i$ with $i=1,2$, the equilibrium condition requires that the sum of the torques be zero:

equation=10754

Therefore, considering that the sign of each torque depends on the direction in which it induces rotation,

$d_1F_1-d_2F_2=0$



which results in

equation.

Si se deriva en el tiempo la relaci n para el momento angular

equation=1072

para el caso de que el radio sea constante

$T=\displaystyle\frac{dL}{dt}=r\displaystyle\frac{dp}{dt}=rF$



por lo que

equation

Examples

The gravitational Force ($F_g$) is based on the gravitational mass ($m_g$) of the object and on a constant reflecting the intensity of gravity at the planet's surface. The latter is identified by the gravitational Acceleration ($g$), which is equal to $9.8 m/s^2$.

Consequently, it is concluded that:

kyon

As we have seen, torque plays a role analogous to force in the case of rotation:

$F\longleftrightarrow T$



To establish the equations of motion, we can recall how force was defined in terms of momentum:

$F=\displaystyle\frac{\Delta p}{\Delta t}$



and how torque was defined:

$T=\displaystyle\frac{\Delta L}{\Delta t}$



We can establish a relationship between the two to describe the generation of torque based on force:

image=322

Hence, we must first define what the equivalent of Momentum is in the context of rotation.

Since the relationship between angular momentum and torque is

equation=1072

its temporal derivative leads us to the torque relationship

kyon

The body's rotation occurs around an axis in the direction of the torque, which passes through the center of mass.

If a bar mounted on a point acting as a pivot is subjected to the force 1 ($F_1$) at the force - axis distance (arm) 1 ($d_1$) from the pivot, generating a torque $T_1$, and to the force 2 ($F_2$) at the force - axis distance (arm) 2 ($d_2$) from the pivot, generating a torque $T_2$, it will be in equilibrium if both torques are equal. Therefore, the equilibrium corresponds to the so-called law of the lever, expressed as:

kyon

If one considers the distribution of mass in space, it should always be possible to identify a point where the force exerted by the mass on one side is equal to the force generated on the other side:

image

This concept implies that for any orientation of an object, a point of support can be located, at which the object is in balance. Each of these points corresponds to a vertical line. By repeating this process with different orientations of the object, it eventually becomes evident that the vertical lines intersect at a particular point within the object. This point is referred to as the center of mass (CM). In essence, the center of mass is the unique point within the object where, regardless of its orientation, equilibrium is always achieved.

One can define the center of mass as the point at which all the vertical lines drawn through points where the system is in equilibrium intersect:

image

Any object that both translates and rotates does so in a manner that:

• its translational motion can be described as if all the mass were concentrated at its center of mass,
• its rotation occurs around the center of mass as if it were not undergoing translation.

image

The orientation of torque can be determined using the right-hand rule: if you point your fingers in the direction of the radius and rotate in the direction of the force,

image

>Model

ID:(1416, 0)