91Ó°ÊÓ

a) Angular velocity of disk A,${\mathrm{Ó\neg }}_A=9.5\text{rad/s}$

b) Angular acceleration of disk B,${\mathrm{Î\pm }}_B=2.2{\text{rad/s}}^2$${\mathrm{Î\pm }}_B=2.2{\text{rad/s}}^2$

The study of the rotational motion of the body is given as the angular form of kinematics. The angular entities like displacement, velocity, and acceleration are related to the linear kinematics by a radial value. Further, using this radial theorem, we can observe the relatable kinematic equations in angular form.

Formulae:

The angular displacement of a body in rotational motion analogy to 2^nd law of kinematic equations, $\mathrm{θ}={\mathrm{Ó\neg }}_{0}t+\frac{1}{2}\mathrm{Î\pm }{t}^2$ (i)

where,${\mathrm{Ó\neg }}_0$is the initial angular velocity of the body,$t$is the angular acceleration of the body,is the time of motion.

The roots of a quadratic equation$a{x}^2+bx+c=0$ , $x=\frac{−bÂ\pm \sqrt{b^2−4ac}}{2a}$ (ii)

Using equation (i), the angular displacement of the disk A can be given as:

(As the angular velocity is constant, that implies no angular acceleration)

${\mathrm{θ}}_A={\mathrm{Ó\neg }}_{A}t$………………………… (I)

And, for disc B using second kinetic equation in rotational motion,

Using equation (i), the angular displacement of the disk B can be given as:

(As the angular acceleration is constant, that implies no angular velocity)

${\mathrm{θ}}_B=\frac{1}{2}{\mathrm{Î\pm }}_B{t}^2$………………………… (II)

AS per our requirement for both the angular displacements to be equal, we get the reference time using the above equations as follows:

$\begin{array}{c}{\mathrm{θ}}_A={\mathrm{θ}}_B\\ {\mathrm{Ó\neg }}_{A}t=\frac{1}{2}{\mathrm{Î\pm }}_B{t}^2\\ (9.5\text{rad/s})t=\frac{1}{2}\left(2.2{\text{rad/s}}^2\right)t^2\\ (9.5\text{rad/s})=\left(1.1{\text{rad/s}}^2\right)t\\ t=\frac{(9.5)}{\left(1.1\right)}\text{s}\\ =8.6\text{ s}\end{array}$

Therefore, the time at which reference lines of two disks momentarily have the same angular displacement$\mathrm{θ}$ is.$8.6\text{ s}$

Now, the change in the angular displacement of the two disks can be given using equations (I) and (II) as follows:

${\mathrm{θ}}_A−{\mathrm{θ}}_B={\mathrm{Ó\neg }}_{A}t−\frac{1}{2}{\mathrm{Î\pm }}_B{t}^2$

And, the reference line of both the disks will be aligned if the following condition is satisfied:

${\mathrm{θ}}_A−{\mathrm{θ}}_B=2\mathrm{π}\text{n}$

Thus, equating above two equations, we get the reference time as follows:

$\begin{array}{c}{\mathrm{Ó\neg }}_{A}t−\frac{1}{2}{\mathrm{Î\pm }}_B{t}^2=2\mathrm{Ï€}n\\ (9.5\text{rad/s})t−\frac{1}{2}\left(2.2{\text{rad/s}}^2\right)t^2=2\mathrm{Ï€}\text{n}\\ \left(1.1{\text{rad/s}}^2\right)t^2−(9.5\text{rad/s})t+2\mathrm{Ï€}\text{n}=0\end{array}$

Thus, the root values can be given using equation (ii) as follows:

(for the coefficients values as:$a=1.1,b=−9.5,c=2\mathrm{π}n$)

$t_n=\frac{\left(9.5\right)Â\pm \sqrt{{\left(9.5\right)}^2−8\mathrm{Ï€}\left(1.1\right)\left(n\right)}}{2\left(1.1\right)}$

Thus at,$n=0$ we get the reference time for the positive root value as:

$\begin{array}{c}{t}_0=\frac{\left(9.5\right)+\sqrt{{\left(9.5\right)}^2−8\mathrm{π}\left(1.1\right)\left(0\right)}}{2\left(1.1\right)}\\ =\left[\frac{\left(9.5\right)+\left(9.5\right)}{2.2}\right]\text{s}\\ =\left(\frac{9.5}{1.1}\right)\text{s}\\ =8.6\text{s}\end{array}$

Similarly, the reference time for the negative root value as:

$\begin{array}{c}{t}_0=\frac{\left(9.5\right)−\sqrt{{\left(9.5\right)}^2−8\mathrm{π}\left(1.1\right)\left(0\right)}}{2\left(1.1\right)}\\ =\left[\frac{\left(9.5\right)−\left(9.5\right)}{2.2}\right]\text{s}\\ =0\text{s}\end{array}$

Again, on further calculations, we can see that the reference time values remain same for$n=1,2,3$as$t_1=8.6\text{s}\&t_2=0\text{ s}$:

Therefore, for the two reference time values, the reference lines of both disks are momentarily aligned.