In 6th, 7th, and 8th grade, we saw how to solve real world problems with prisms and cylinders. This lesson will build on some of that knowledge and our work with nets in 6th grade to solve more mathematical problems and learn about a principle that we can use as another tool for solving problems.
Explore the applet by moving the sliders and checking the boxes.
Move the slider to change the stack of slabs. Will the volume of the stack change? How do you know?
Move the slider to change the solid. What are two features of the solids that remain the same when moving the slider?
Will the volume of the solids change? How do you know?
Recall that a right prism is a figure with two congruent, parallel, polygonal bases that are connected by rectangular faces. Cylinders are similar, but the bases are circles instead of polygons, and so they are joined by a curved surface instead of rectangles.
When a prism or cylinder becomes oblique, its volume will remain the same as long as its height and cross section remain the same. This leads to Cavalieri's principle.
The following three figures each reach the same perpendicular height h and have the same base area B, so by Cavalieri's principle we know that they have the same volume:
Notice that it is the perpendicular height that is important, rather than the slant height, even if the solids are not right prisms/cylinders.
A 3D printer is printing an object of stacked coins by stacking circular pieces with a thickness of 1 \text{ mm} and an area of 12.57 \text{ mm}^2. The volume of one of the circular pieces is 12.57 \text{ mm}^3.
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.
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?
Find the volume of a 3D-printed cylindrical object if there was a stack of 12 coins, each 1 \text{ mm} thick, where the area of the top face of a coin is 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 base area B.
Consider a hexagonal child's ball pit. A layer of 64 balls will cover just the bottom of the ball pit.
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.
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.
Consider a hexagonally-shaped fish tank. Find the volume of the fish tank with the given dimensions.
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}.
Find the density of a cube with side length 4 \text{ ft} and weight 300 \text{ lbs}.
A company is designing a new filter for its air purifiers using a computer program. The designer maps out the 2D shape on a coordinate plane, then rotates the shape about the x-axis.
Sketch the filter after its revolution about the x-axis and label its dimensions.
What is the volume of the air filter?
The volume, V, of a prism or cylinder is calculated using the formula V=Bh, where B represents the area of the base and h represents the height of the prism.
We can use Cavalieri's principle to justify that if two three-dimensional figures have the same height and the same cross-sectional area at every level, then they have the same volume.
Drag the sliders and check the boxes to explore the applet.
Create a triangular prism by changing N to 3 and dragging the sliders to close the net. How can you use the net to find the surface area of the prism?
What happens as you drag the N slider to its largest value?
A net is a diagram of the faces of a three-dimensional figure arranged in such a way that the diagram can be folded to form the three-dimensional figure. We can find the surface area of a net by calculating the sum of the lateral faces and the bases.
Note that even some solids with curved faces, such as cylinders, have nets consisting of flat, two-dimensional shapes. Additionally, a solid can be represented with multiple different, equivalent nets.
The surface area of a cylinder can be calculated identically; by adding the area of two circular bases to the product of the circumference and the perpendicular height between bases.
We can find the lateral area of a prism or a cylinder by ignoring the bases.
Consider the can of tuna shown below:
Draw the net of the can of tuna and label its dimensions.
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.
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.
Yuki is decorating a wedding cake with some icing. He wants to cover the outer facing surface of the cake with a layer of icing that is an eighth of an inch thick.
Determine how much icing Yuki will need to decorate the cake.
We can calculate the surface area of any prism or cylinder using the formula