Lesson 12

Filling Containers

12.1: Which One Doesn’t Belong: Solids (5 minutes)

Warm-up

The purpose of this warm-up is for students to compare different objects that may not be familiar and think about how they are similar and different from objects they have encountered in previous activities and grade levels. To allow all students to access the activity, each object has one obvious reason it does not belong. Encourage students to move past the obvious reasons (e.g., Figure A has a point on top) and find reasons based on geometrical properties (e.g., Figure D when looked at from every side is a rectangle). During the discussion, listen for important ideas and terminology that will be helpful in upcoming work of the unit.

Launch

Arrange students in groups of 2. Display the image for all to see. Ask students to indicate when they have noticed one object that does not belong and can explain why. Give students 2 minutes of quiet think time and then time to share their thinking with their partner.

Student Facing

These are drawings of three-dimensional objects. Which one doesn’t belong? Explain your reasoning.

Four different, three-dimensional shapes labeled A, B, C, and D.  Shape "A" is a cone; Shape "B" is a sphere; Shape "C" is a cylinder; Shape "D" is a rectangular prism.

 

 

Student Response

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Activity Synthesis

Ask students to share one reason why a particular object might not belong. Record and display the responses for all to see. After each response, ask the rest of the class if they agree or disagree. Since there is no single correct answer to the question of which one does not belong, attend to students’ explanations and ensure the reasons given are correct. During the discussion, prompt students to explain the meaning of any terminology they use, such as diameter, radius, vertex, edge, face, or specific names of the figures: sphere, cylinder, cone, rectangular prism.

12.2: Height and Volume (20 minutes)

Activity

In this activity, students investigate how the height of water in a graduated cylinder is a function of the volume of water in the graduated cylinder. Students make predictions about how the graph will look and then test their prediction by filling the graduated cylinder with different amounts of water, gathering and graphing the data (MP4).

Launch

Arrange students in groups of 3–4. Be sure students know how to measure using a graduated cylinder. If needed, display a graduated cylinder filled to a specific measurement for all to see and demonstrate to students how to read the measurement. Give each group access to a graduated cylinder and water.

Give groups 8–10 minutes to work on the task, follow with a whole-class discussion.

For classrooms with access to the digital materials or those with no access to graduated cylinders, an applet is included here. Physical measurement tools and an active lab experience are preferred.

Speaking: MLR8 Discussion Supports. Display sentence frames to support small-group discussion. For example, “I think ____ , because _____ .” or “I (agree/disagree) because ______ .”
Design Principle(s): Support sense-making; Optimize output for (explanation)

Student Facing

Use the applet to investigate the height of water in the cylinder as a function of the water volume.

  1. Before you get started, make a prediction about the shape of the graph.

  2. Check Reset and set the radius and height of the graduated cylinder to values you choose.

  3. Let the cylinder fill with different amounts of water and record the data in the table.

     
  4. Create a graph that shows the height of the water in the cylinder as a function of the water volume.
  5. Choose a point on the graph and explain its meaning in the context of the situation.

Student Response

For access, consult one of our IM Certified Partners.

Launch

Arrange students in groups of 3–4. Be sure students know how to measure using a graduated cylinder. If needed, display a graduated cylinder filled to a specific measurement for all to see and demonstrate to students how to read the measurement. Give each group access to a graduated cylinder and water.

Give groups 8–10 minutes to work on the task, follow with a whole-class discussion.

For classrooms with access to the digital materials or those with no access to graduated cylinders, an applet is included here. Physical measurement tools and an active lab experience are preferred.

Speaking: MLR8 Discussion Supports. Display sentence frames to support small-group discussion. For example, “I think ____ , because _____ .” or “I (agree/disagree) because ______ .”
Design Principle(s): Support sense-making; Optimize output for (explanation)

Student Facing

Your teacher will give you a graduated cylinder, water, and some other supplies. Your group will use these supplies to investigate the height of water in the cylinder as a function of the water volume.

  1. Before you get started, make a prediction about the shape of the graph.
     
  2. Fill the cylinder with different amounts of water and record the data in the table.
    volume (ml)                        
    height (cm)
  3. Create a graph that shows the height of the water in the cylinder as a function of the water volume.
    A blank coordinate plane.
  4. Choose a point on the graph and explain its meaning in the context of the situation.
     

Student Response

For access, consult one of our IM Certified Partners.

Activity Synthesis

Select groups to share the graph for the third question and display it for all to see. Consider asking students the following questions:

  • “What do you notice about the shape of your graph?”
  • “What is the independent variable of your graph? Dependent variable?”
  • “How does this graph differ from what you predicted the shape would be?”
  • “For the last question, what point did you choose, and what does that point mean in the context of this activity?”
  • “What would the endpoint of the graph be?” (There is a maximum possible volume for the cylinder. Once it’s filled, any extra water will spill out and not raise the water height.)
A coordinate plane with three lines graphed.

Ask students to predict how the graph would change if their cylinder had double the diameter. After a few responses, display this graph for all to see:Explain that each line represents the graph of a cylinder with a different radius. One cylinder has a radius of 1 cm, another has a radius of 2 cm, and another has a radius of 3 cm. Have students consider which line must represent which cylinder. Ask, “how did the slope of each graph change as the radius increased?” (As the radius is larger, the slope is less steep. This is because for a cylinder with a larger base, the same volume of water will not fill as high up the side of the cylinder.)

12.3: What Is the Shape? (10 minutes)

Activity

In the previous activity, students were given a container and asked to draw the graph of the height as a function of the volume. In this activity, students are given the graph and asked to draw a sketch of the container that could have generated that height function. Since students have worked on the two previous activities, they have an idea of what the data for a graduated cylinder and a graduated cylinder with twice the diameter looks like and can use that information to compare to while working on this task.

Launch

Arrange students in groups of 2. Give students 3–5 minutes of quiet work time and then time to share their drawings with their partner. Follow with a whole-class discussion.

If time is short, consider having half of the class work on the first question and the other half work on the second question and then complete the last question as part of the Activity Synthesis.

Representation: Internalize Comprehension. Begin by providing students with a range of different sized containers or students to test to determine if their volume and height could be represented by the given graphs.
Supports accessibility for: Conceptual processing
Reading, Writing, Conversing: MLR1 Stronger and Clearer Each Time. Use this routine to provide students with a structured opportunity to revise and refine their response to the last question. Ask students to meet with 2–3 partners for feedback. Provide students with prompts for feedback that will help students strengthen their ideas and clarify their language (e.g., “Why do you think...?”, “What in the graph makes you think that?”, “Can you give an example?”, etc.). Students can borrow ideas and language from each partner to strengthen their final version.
Design Principle(s): Optimize output (for explanation)

Student Facing

  1. The graph shows the height vs. volume function of an unknown container. What shape could this container have? Explain how you know and draw a possible container.
    Coordinate plane, horizontal, volume in milliliters, 0 to 100 by tens, vertical, height in centimeters, 0 to 14 by twos. Line segments from origin to 40 comma 9, then on to 100 comma 12.
  2. The graph shows the height vs. volume function of a different unknown container. What shape could this container have? Explain how you know and draw a possible container.
    Coordinate plane, horizontal, volume in milliliters, 0 to 100 by tens, vertical, height in centimeters, 0 to 14 by twos. Line segments connect origin to 10 comma 9, to 50 comma 12, to 80 comma 14.
  3. How are the two containers similar? How are they different?

Student Response

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Student Facing

Are you ready for more?

The graph shows the height vs. volume function of an unknown container. What shape could this container have? Explain how you know and draw a possible container.

A graph, horizontal axis, volume in milliliters, vertical graph, height in centimeters. Graph starts at the origin, as x increases, y increases steeply before slowing down.

Student Response

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Activity Synthesis

Select students to share the different containers they drew. Display their drawings and the graph for all to see. Ask students to explain how they came up with their drawing and refer to parts in the graph that determined the shape of their container.

Lesson Synthesis

Lesson Synthesis

Have students make their own graph showing the height and volume of a container. Tell students to use 2–5 lines for their container. Once the graphs are made, have students swap with a partner and try to draw the shape of their partner’s container. Ask a few groups to share their graphs and container drawings.

12.4: Cool-down - Which Cylinder? (5 minutes)

Cool-Down

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Student Lesson Summary

Student Facing

When filling a shape like a cylinder with water, we can see how the dimensions of the cylinder affect things like the changing height of the water. For example, let's say we have two cylinders, \(D\) and \(E\), with the same height, but \(D\) has a radius of 3 cm and \(E\) has a radius of 6 cm.
 

Two cylinders. Cylinder D, height, h, radius 3 centimeters. Cylinder E, height, h, radius, 6 centimeters.

If we pour water into both cylinders at the same rate, the height of water in \(D\) will increase faster than the height of water in \(E\) due to its smaller radius. This means that if we made graphs of the height of water as a function of the volume of water for each cylinder, we would have two lines and the slope of the line for cylinder \(D\) would be greater than the slope of the line for cylinder \(E\).