We have that $$\frac{\mathrm dV}{\mathrm dt} = 4 \pi r^2\cdot \frac{\mathrm dr}{\mathrm dt} =60$$
which implies $$\frac{\mathrm dr}{\mathrm dt} =\frac{60}{4 \pi r^2}$$
We know that $A = 4 \pi r^2$, and so we also have
$$\frac{\mathrm dA}{\mathrm dt} = 8\pi r\cdot \frac{\mathrm dr}{\mathrm dt} $$
Plug in what we found for $\frac{\mathrm dr}{\mathrm dt}$ and plug in $r=4$ to get
$$\frac{\mathrm dA}{\mathrm dt} = 8\pi r\cdot \bigg( \frac{60}{4 \pi r^2}\bigg) $$
$$\frac{\mathrm dA}{\mathrm dt} = \frac{120}r = \frac{120}4$$
$$\frac{\mathrm dA}{\mathrm dt} = 30$$
First, let $t$ be time in seconds, $r(t)$ be the radius in inches at time $t$ seconds, $h(t)$ be the height in inches at time $t$ seconds, and $V(t)$ be the volume in cubic inches at time $t$ seconds, and let $t_0$ be the time at which the radius is $2$ inches.
What do we know? The volume is increasing at a rate of $3$ cubic inches per second, so $$\frac{\text dV}{\text dt}(t) = 3$$ for all $t$. Height is two-thirds the radius, so $$h(t) = \frac{2}{3}r(t)$$ for all $t$. The radius is $2$ inches at time $t_0$, so $$r(t_0) = 2$$
What do we want? We are asked how fast the radius is changing (with respect to time) at the instant where the radius is $2$ inches, so we want to find $\frac{\text dr}{\text dt}(t_0)$.
What do we need? We have a relationship between $h$ and $r$, but in terms of rates, we only have information about $\frac{\text dV}{\text dt}$. So, we need some relationship between $V$ and $r$, $h$, or both. Since the shape is a cone, we can can use the formula for the volume of a cone, $$V(t) = \frac{1}{3}\pi h(t)r(t)^2$$ Substituting our relationship between $r$ and $h$, we get $$V(t) = \frac{2}{9}\pi r(t)^3$$ Differentiating this gives us $$\frac{\text dV}{\text dt}(t) = \frac{2}{3}\pi r(t)^2\frac{\text dr}{\text dt}(t)$$
Now that we have all the information, we just need to put it together. Plugging in $t=t_0$ will give us the relationship when the radius is $2$ inches, $$\frac{\text dV}{\text dt}(t_0) = \frac{2}{3}\pi r(t_0)^2\frac{\text dr}{\text dt}(t_0)$$ However, we know that $\frac{\text dV}{\text dt}(t) = 3$ for all $t$, and in particular at $t=t_0$, so we have $$\frac{\text dV}{\text dt}(t_0) = 3$$ We also know that $r(t_0) = 2$ by definition of $t_0$. This means that our equation reduces to $$3 = \frac{2}{3}\pi\cdot 2^2 \frac{\text dr}{\text dt}(t_0)$$ which we can solve to determine the value $$\frac{\text dr}{\text dt}(t_0) = \frac{9}{8}\pi$$
In terms of the original problem, $\frac{\text dr}{\text dt}(t_0) = \frac{9}{8}\pi$ can be interpreted as the salt pile's radius increasing at a rate of $\frac{9}{8}\pi$ inches per second when the radius is $2$ inches.
Best Answer
Start off with the formula for the volume of a cube
And we know that the sides are increasing at a rate of $s_t=2$. Furthermore, the question gives us the fact that the area of the base is ten inches squared. Therefore $s=\sqrt{10}$. Differentiate the first equation with respect to $t$ to get$$V_t=3s^2 s_t$$And plug in the knowns to get$$V_t=3\left(\sqrt{10}\right)^22=60$$