A soda can is to hold 12 fluid ounces. Find the dimensions that will minimize the amount of material used in its construction, assuming the thickness of the material is uniform?

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A soda can is to hold 12 fluid ounces. Find the dimensions that will minimize the amount of material used in its construction, assuming the thickness of the material is uniform?

I am Canadian so I don't know imperial measurements by the way !

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Answer 1 · 2018-03-16T15:49:23

$r=root(3)(341/(2pi))color(white)(88)$ and $color(white)(88)h=341/(pi(root(3)(341/(2pi)))^2$

Explanation:

I have converted fluid ounces to cubic centimetres.

$12 "flz"= 341 "cm"^3$ (1 d.p.)

We need the can to have a volume of $341cm^3$ and a minimum surface area.

If the can has a radius $bbr$ and height $bbh$ Then the surface area is given by:

$bb(S=2pir^2+2pirh)$

We can't differentiate this expression in the given form, because it contains two variables $bbr$ and $bbh$

But the volume given by:

$bb(V=pir^2h)$

needs to be $341cm^3$

$:.$

$pir^2h=341$

We can now find $bbh$ in terms of the radius $bbr$ :

$h=341/(pir^2)$

Substituting this into the surface area formula:

$S=2pir^2+2pir(341/(pir^2))$

Simplifying:

$S=2pir^2+2pir(341/(pir^2))=2pir^2+(pir682)/(pir^2)$

$->S=2pir^2+682/r$

Since we need to find the change in surface area as the radius changes, we need to differentiate this in respect of $bbr$ :

$(dS)/(dr)(2pir^2+682/r)=4pir-682/r^2$

Now we know that local maximum and minimum points have a gradient of zero. These therefore can be identified using our first derivative and equating this to zero.

$:.$

$4pir-682/r^2=0$

Solving for $bbr$

$r^3=341/(2pi)$

$r=root(3)(341/(2pi))$

$h=341/(pi(root(3)(341/(2pi)))^2)color(white)(88888)$ ( From above )

We know that if the second derivative is $>0$ for our value of $bbr$ then this is a minimum value.

$(d^2S)/(dr^2)=4pi+(2(682))/r^3$

Plugging in our value for $bbr$

$4pi+(2(682))/(root(3)(341/(2pi)))^3=4pi+(2(682))/(341/(2pi))$

This is greater than zero, so $r=root(3)(341/(2pi))$ and $h=341/(pi(root(3)(341/(2pi)))^2$

So a can with our given radius an height will have a minimum surface area.

Note: Dimensions will be in cm, since we converted volume into these units. $bbr$ and $bbh$ can be approximated in necessary, but I will leave them in their exact form.

Below is the graph of surface area in terms of radius and height. If you approximate the found values of $bbr$ you will see that this is the minimum value, and this give a surface area of $~~270.2cm^2$ .

Graph of $S=2pir^2+682/r$

enter image source here

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A soda can is to hold 12 fluid ounces. Find the dimensions that will minimize the amount of material used in its construction, assuming the thickness of the material is uniform?

I am Canadian so I don't know imperial measurements by the way !

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