11.02 Prisms and cylinders

Find the volume of the printed cylinder. Then find the volume of the printed cylinder if each coin was 3.2 \text{ mm} thick. Explain the process for finding the volume of the solid for a coin of any height.

If the volume of one of the circular pieces from the printer is 12.57 \text{ mm}^3, and the object has seven coins, we can multiply the volume of one of the coins by 7. We can apply this process to the object if each coin were a different thickness.

By knowing the volume of one of the coins in the printed object, we can multiply that by the height of the object, which is 7 \text{ coins}, or 7 \text{ mm}:12.57 \text{ mm}^3 \cdot 7= 87.99 \text{ mm}^3

If each circular piece printed was instead 3.2 \text{ mm} thick, we could find the volume of the object by multiplying the area of the base by 22.4 \text{ mm}.

If each circular piece printed was instead h \text{ mm} thick, we could find the volume of the object by multiplying the area of the base by 7h \text{ mm}.

The 3D printer creates an oblique cylinder using the same dimensions as the circular pieces from the first solid. What is the volume of the new object?

The volume of the new object is the same as the volume of the first printed stack of coins, 87.99 \text{ mm}^3, by Cavalieri's principle.

Since no settings for the dimensions of the stacks were changed and the only difference is an oblique cylindrical shape printed, the cross sections and volume of the new object should remain the same as the first stack of coins.

Find the volume of a 3D-printed cylindrical object if there was a stack of 12 coins, each 1 \text{ mm} thick with a surface area of 6\,358.5 \text{ mm}^2. Then, explain the process for finding the volume, V, of the solid for any number, n, of 1-millimeter thick, stacked coins with surface area B.

If we know the surface area of one of the coins, its height, and how many coins are in the stack, we can find the volume of the cylinder by multiplying the same way we approached part (a).

Since 12 coins create a stack with a total height of 12 \text{ mm}, 6\,358.5 \text{ mm}^2 \cdot 12 \text{ mm} = 76\,302.0 \text{ mm}^3.

If any coin has a thickness of 1 \text{ mm}, then the height of any stack of coins will be 1n=n. We can find the volume, V, by multiplying the surface area of one coin by the height of the coins, so V=Bn.

Note that the units for the volume of a three-dimensional solid must be in cubic units, so it makes sense that multiplying area by height will give us cubic millimeters as our units of measure.

The balls can be stacked 32 balls high and still leave extra room at the top for kids to jump in without spilling balls out. Explain how to find the number of balls needed to fill the pit.

Imagine the single layer of 64 balls added 32 times to fill the pit.

By multiplying a layer of 64 balls 32 times, the pit can hold 64 \text{ balls} \times 32 \text{ layers} = 2\,048 \text{ balls}.

During cleaning, the ball pit gets pushed slightly and the entire prism ends up leaning to the side, but the hexagonal shape is preserved. Explain how the volume of balls that fit inside the ball pit will change.

Recall that Cavalieri's principle states that if two 3D solids are the same height and have the same cross section, they will have the same volume.

Since the ball pit itself does not change, but instead becomes an oblique hexagonal prism, we can use Cavalieri's principle to determine that the same volume of balls from part (a) will fit in the ball pit after it is pushed during cleaning. This makes sense because the same number of balls will still be inside the pit.

Consider a hexagonally-shaped fish tank. Find the volume of the fish tank with the given dimensions.

Find the area of the bottom face of the tank, then think of the volume as stacking 1 \text{ in} of water 12 times to fill the tank.

In order to find the area of the base, we need to cut the hexagonal base into two triangles and a rectangle, then find the sum of the areas of each part.

For the base of each triangle, we have

For the rectangle, the area is 6 \text{ in} \times 5 \text{ in}= 30 \text{ in}^2.

The sum of the shapes that make up the hexagonal base of the fish tank is 7.5 \text{ in}^2 + 7.5 \text{ in}^2 + 30 \text{ in}^2 = 45 \text{ in}^2.

If 1 \text{ in} of water were to cover the base of the tank, we could add the area of the covered base 12 times, or by multiplying the area of the base by the height of the tank, 12 \text{ in}. So 45 \text{ in}^2 \times 12 \text{ in} = 540 \text{ in}^3.

We found the volume of the hexagonal prism by calculating the area of the base and multiplying it by the height of the prism.

We use this same process when calculating the volume of a cylinder, except we can relate the base of a cylinder, which is a circle, to a polygon with an infinite number of sides.

Find the density of the water in the fish tank from part (c) given that the water inside of it weighs 23.41 \text{ lbs}.

We calculated the volume of the tank as 540 \text{ in}^3, so we will use the formula for density given the mass of the water.

Therefore, the density of the water in the tank is 0.0434 \, \text{lbs}/\text{in}^3.

Rounding to a specified number of decimal places may be appropriate depending on the situation. We could round to two decimal places in this problem, but because the decimal itself is relatively small, rounding to three decimal places will give us a more precise answer.

Note that the density is calculated by dividing the mass (in pounds) by the volume (in cubic inches), and so the density has units of mass per volume - in this case, pounds per cubic inch.

Sketch the filter after its revolution about the x-axis and label its dimensions.

The object will be the shape of a cylinder with another cylinder hollowed out from the center.

What is the volume of the air filter?

Calculate the volume of the large cylinder as if it was solid. Then subtract the volume of the hollowed out cylinder in the center of the filter, which was created by revolving the 2D shape about the x-axis.

The cylindrical air filter has a radius of 3 \text{ feet}, so the area of one of its bases is A=\pi \cdot 3^2 \approx 28.27 \text{ ft}^2. To find the volume of the solid, we can multiply the area of the base by the height of the cylinder, so 28.27 \text{ ft}^2 \cdot 3 \text{ ft} = 84.81 \text{ ft}^3.

The cylindrical center of the air filter has a radius of 1 \text{ foot}, so the area of one of its bases is A=\pi \cdot 1^2 \approx 3.14 \text{ ft}^2. To find the volume of the cylindrical center, we can multiply the area of the base by the height of the cylinder, so 3.14 \text{ ft}^2 \cdot 3 \text{ ft} = 9.42 \text{ ft}^3.

The volume of the filter is calculated by finding the difference between the volume of the large, solid cylinder and the volume of the center cylinder. The filter's volume is 84.81 \text{ ft}^3 - 9.42 \text{ ft}^3 = 75.39 \text{ ft}^3.

Since \pi is an irrational number, we needed to make decisions about how to round it in our calculations. We should take the units we're working with and prractical considerations into account. Since the measurements are in feet and cubic feet, rounding to the hundredths place is reasonable, and likely within the capabilities of a computer design program and necessary level of accurate measurements for an air filter. We could also opt not to round, and instead use calculator software at each step, which uses more exact calculations of \pi, which will result in a more precise solution.

Once we make the decision to round to the hundredths place, that becomes the limit of our level of precision, and our final solution should not be given with more than two decimal placements.

Draw the net of the can of tuna and label its dimensions.

The net of a cylinder will have two circular bases and a rectangle for its lateral face.

Find the area of each part of the net and find the total surface area of tin that a company must produce per can of tuna.

We have enough information from the can of tuna to find the area of each of the circular bases. The diameter of each base, is 2.75 \text{ in} so we use half the diameter for the radius, 1.375 \text{ in}. However, we will need the length of the can in order to find the area of the lateral face. We can calculate the length of the can by finding the circumference of a circular base.

First, calculate the area of each base:

The area of each base is 5.940 \text{ in}^2.

Then, calculate the circumference of a base to find the length of the can's lateral side:

The length of the can is 8.639 \text{ in}.

Now, the area of the lateral side, which is a rectangle, is found by multiplying the length and width of the can. So, the area of the lateral side is 8.639 \text{ in} \times 1.125 \text{ in} = 9.719 \text{ in}^2.

Finally, we can find the surface area of the tuna can by adding the area of each base to its lateral side: 5.94 \text{ in}^2 + 5.94 \text{ in}^2 + 9.719 \text{ in}^2 = 21.599 \text{ in}^2.

While we could have used fractions throughout the problem, converting the given dimensions to decimals may be easier to work with.

We rounded the decimals to 3 places, since the fractions we are using are exact to 3 decimal places. We may also want to keep that level of precision because the company will want to be as precise as possible when producing each can.

The formula for finding the surface area of a prism or cylinder is SA= 2B + Ph, where SA represents surface area, B represents the area of the base, P represents the perimeter of the base, and h represents the height of the prism or cylinder. Explain what each part of the formula for surface area represents, and relate it to finding the surface area for the can of tuna.

We explain why variables are multiplied and added a certain way, then relate it back to the can of tuna.

The surface area formula is the sum of two products.

The first product is twice the area of the base. This makes sense because each prism or cylinder will have two identical bases, so their areas should be added together, or in this formula multiplied by 2. The can of tuna had circular bases, so we used the Area formula for a circle to find the Base area.

The second product is the result of multiplying the perimeter of the base and the height of the prism or cylinder. This is the area of the rectangular lateral side, since the perimeter of the base is also the width of the rectangle and the height of the prism is the height of the rectangle. For the can of tuna, the base was circular, so we used the formula for the Circumference of a circle as the perimeter.

By calculating the sum of these products, we have found the combined areas of each part of the net, which is the surface area of the entire can of tuna.