Centre of Mass and Conservation of Linear Momentum
1.0 Introduction
2.0 Position of centre of mass of continuous bodies
2.1 Rod
2.2 Semicircular ring
2.3 Semicircular disc
2.4 Solid sphere
2.5 Hemispherical Shell
2.6 Rectangular Plate
2.7 Square Plate
2.8 Circular Plate
2.9 Solid Cone
2.10 Hollow Cone
2.11 Questions
2.12 Centre of mass of a rigid complex bodies
3.0 Centre of mass of the remaining portion
4.0 Laws of conservation of linear momentum
5.0 Variable Mass
6.0 Impulse
7.0 Collision
8.0 Types of collision
9.0 Newton's law of restitution
10.0 Head on elastic and inelastic collision
11.0 Collision in two dimension
12.0 Oblique collision
2.9 Solid Cone
2.2 Semicircular ring
2.3 Semicircular disc
2.4 Solid sphere
2.5 Hemispherical Shell
2.6 Rectangular Plate
2.7 Square Plate
2.8 Circular Plate
2.9 Solid Cone
2.10 Hollow Cone
2.11 Questions
2.12 Centre of mass of a rigid complex bodies
Consider a uniform solid cone of radius $R$ and height $H$, whose centre is at the origin of a cartesian co-ordinate (for simplicity).
Volume of the solid cone $(V) = \frac{1}{3}\pi {R^2}H\quad ...(i)$
Mass per unit volume $({\lambda _V}) = \frac{{3M}}{{\pi {R^2}H}}\quad ...(ii)$
Consider an infinitesimal small element in the shape of a cylinder of mass $dm$, radius $r$ and infinitesimal small thickness $dy$.
Point $P$, which is the centre of the infinitesimal small cylinder, and is at a vertical distance $y$ from the origin.
Co-ordinate of the centre of mass of the cylinder is at point $P$ i.e. $(0,y)$.
So, the position vector of the centre of mass $(COM)$ of point $P$ is ${\overrightarrow r _P} = y\widehat j$
Note: The small section at point $P$ is infinitesimally small, so the centre of mass of that section is assumed to be at point $P$ only.
Volume of the cylinder is, $$dV = \left( {\pi {r^2}} \right)dy\quad ...(iii)$$ Also, $$\begin{equation} \begin{aligned} dm = {\lambda _V}.\;dV \\ dm = {\lambda _V}\pi {r^2}dy\quad ...(iv) \\\end{aligned} \end{equation} $$
Therefore, the centre of mass $(COM)$ of the solid cylinder is given by, $${\overrightarrow r _{COM}} = \frac{{\int {{{\overrightarrow r }_P}dm} }}{{\int {dm} }} = \frac{{\int {ydm} }}{{\int {dm} }}\widehat j\quad ...(v)$$
From equation $(iv)$ & $(v)$ we get, $$\begin{equation} \begin{aligned} {\overrightarrow r _{COM}} = \frac{{\int {y{\lambda _V}\pi {r^2}dy} }}{{\int {{\lambda _V}\pi {r^2}dy} }}\widehat j \\ {\overrightarrow r _{COM}} = \frac{{\int {y{r^2}dy} }}{{\int {{r^2}dy} }}\widehat j\quad ...(vi) \\\end{aligned} \end{equation} $$
Relation between $r$ & $y$
As we know that $\Delta AOB$ & $\Delta APQ$ are similar.
Mathematically, $$\Delta AOB \approx \Delta APQ$$ Therefore, $$\frac{H}{R} = \frac{{H - y}}{r}$$ So, $$r = \frac{{R(H - y)}}{H}\quad ...(vii)$$
From equation $(vi)$ & $(vii)$ we get, $${\overrightarrow r _{COM}} = \frac{{{{\int {y\left[ {\frac{{R(H - y)}}{H}} \right]} }^2}dy}}{{{{\int {\left[ {\frac{{R(H - y)}}{H}} \right]} }^2}dy}}\widehat j$$
Integrating for the solid cone from point $O$ to $A$,
At point $O$, $y=0$ & at point $A$, $y=H$, so the limit becomes,
$$\begin{equation} \begin{aligned} {\overrightarrow r _{COM}} = \frac{{{{\int\limits_0^H {y\left[ {\frac{{R(H - y)}}{H}} \right]} }^2}dy}}{{{{\int\limits_0^H {\left[ {\frac{{R(H - y)}}{H}} \right]} }^2}dy}}\widehat j \\ {\overrightarrow r _{COM}} = \frac{{\left[ {\frac{{{y^2}{H^2}}}{2} + \frac{{{y^4}}}{4} - \frac{{2H{y^3}}}{3}} \right]_0^H}}{{\left[ {{H^2}y + \frac{{{y^3}}}{3} - H{y^2}} \right]_0^H}}\widehat j \\ {\overrightarrow r _{COM}} = \frac{H}{4}\widehat j \\\end{aligned} \end{equation} $$
So, the centre of mass $(COM)$ of the uniform solid cone is $\left( {0,\frac{H}{4}} \right)$.