Top Banner

Impending Motion

testt
Three Regions of Static to Motion Transition quickk

The impending motion refers to the state of a body when it is on the verge of slipping. In such cases, the static friction has reached its upper limit and is given by the equation

Looking for other study material? arrow

\(\begin{array}{l}F=\mu _{s}N\end{array} \)
The direction of the frictional force is always opposite to the pending relative motion of the surfaces. If the applied force (P) increases then the frictional force (F) also increases, until F<FS(limiting static frictional force). When F = FS, then the body possesses an unstable equilibrium and will move.

To better understand the meaning of impending motion, let us look at the three regions of static to motion transition in the next section.

Three Regions of Static to Motion Transition

  • No Motion – It is the region up till the point of slippage or impending motion. The frictional force in this region is defined by the equations of equilibrium as the system is in equilibrium. When the motion is not impending, F<Fmax.
  • Impending Motion – It is the moment when the body is on the verge of slipping. Here, the static friction reaches its upper limit. For a given pair of surfaces in contact, the frictional force is given by the equation
    \(\begin{array}{l}F=F_{max}=\mu _sN\end{array} \)
  • Motion – In this state, the body starts to move in the direction of the applied force. Here, the frictional force drops to a lower value known as the kinetic friction. The frictional force is given by the equation
    \(\begin{array}{l}F=F_{max}=\mu _kN\end{array} \)

    The force will drop further with higher velocity.

In the next section, let us solve a problem related to impending motion.

Finding The Force For Impending Motion

Let us look at the example given below to understand how to find the force required to impend motion in an object.

Example: Determine the force necessary for impending motion up the plane. The coefficient of static friction is 0.2.

Impending Motion

Solution:

First, let us look at all the forces acting on the body and represent it in the free body diagram.

The free body diagram can be represented as follows:

Impending Motion

The force of gravity acting on the body can be found as follows:

Fg = mg

Substituting the values, we get

Fg = 100 kg × 9.8 m/s2 = 980 N

To maintain equilibrium, the sum of the horizontal forces should be zero and the sum of the vertical forces should be zero.

∑Fx = 0 and ∑Fy = 0

Let us look at the vertical component of forces to calculate the normal force

\(\begin{array}{l}\sum F_{y}=-F_g+N(\frac{12}{13})-F_s\frac{5}{13}=0\end{array} \)

Substituting the value of the force of gravity and the coefficient of static friction in the above equation, we get

\(\begin{array}{l}\sum F_{y}=-980+(\frac{12}{13})N-0.2N\frac{5}{13}=0\end{array} \)
\(\begin{array}{l}\frac{12}{13}N-0.2\frac{5}{13}N=980\end{array} \)
\(\begin{array}{l}N=\frac{980}{\frac{12}{13}-0.2\times\frac{5}{13}}=1158\,N\end{array} \)

The normal force is 1158 N

Now, to find the pushing force let us look at the horizontal forces

\(\begin{array}{l}-N\frac{5}{13}-F_s\frac{12}{13}+F=0\end{array} \)
\(\begin{array}{l}F=N\frac{5}{13}+\mu N\frac{12}{13}\end{array} \)
\(\begin{array}{l}F=N\frac{5}{13}+\mu N\frac{12}{13}\end{array} \)

Substituting the values we get,

\(\begin{array}{l}F=1158\frac{5}{13}+(0.2\times 1158)\frac{12}{13}=659\,N\end{array} \)

Hence, the force required for impending motion is F = 659 N.

Stay tuned to BYJU’S to learn more about static friction and its laws with the help of interactive video lessons.

Test your knowledge on Impending motion
Quiz Image

Put your understanding of this concept to test by answering a few MCQs. Click ‘Start Quiz’ to begin!

Select the correct answer and click on the “Finish” button
Check your score and answers at the end of the quiz

Congrats!

Visit BYJU’S for all Physics related queries and study materials

Your result is as below

0 out of 0 arewrong
0 out of 0 are correct
0 out of 0 are Unattempted
PHYSICS Related Links
Si Unit Of Surface Tension Derivation Of Equation Of Motion By Calculus Method
Scalar Quantity Examples What Is Dimensional Analysis
Types Of Thermometer Physics Uniform Speed
Resistors In Series And Parallel Define Buoyant
Potential Physics Refraction Of Sound

Comments

Leave a Comment

Your Mobile number and Email id will not be published.

*

*