This lesson focuses on how engineers design tire treads to increase safety and reliability. Students are presented with the challenge of designing a new tire tread that will be safe when driving in rainy conditions.
- Learn about engineering design.
- Learn about planning and construction.
- Learn about teamwork and working in groups.
Age Levels: 8 – 18
Materials & Preparation
Build Materials (For each team)
Required Materials
- Paper
- Cardboard
- Clay (5″ x 10″ x 2″ block)
- Plastic knives or kid-safe clay carving tools
- Pencils
Testing Materials
- Water
- Measuring cup and spout
- Tape
- Divided basin (or three small containers) for testing and measuring the water that is gathered at the bottom, and on each side
- Tread depth measuring device (can be a ruler, or an actual tread measuring device)
Testing Materials & Process
Materials
- Water
- Measuring cup and spout
- Tape
- Divided basin (or three small containers) for testing and measuring the water that is gathered at the bottom, and on each side
- Tread depth measuring device (can be a ruler, or an actual tread measuring device)
Process
All “treads” are then tested by pouring two cups of water through the carved clay. The teacher may decide to do the testing, appoint a team of testers, or allow students to test their own designs. Note, the “tread” should be secured with tape at about a 25 degree angle, which will help make the tests of all teams more consistent.
Measure the water collected at the bottom container, as well as the water collected from the right and left side to determine the percentage that was pushed away to the side. Pouring through a spout may assist in making the flow of water at a speed so it doesn’t splash out.
Students keep track of the data and measurements on a student worksheet, while the teacher is responsible for pouring the water to ensure fair testing among all teams.
Engineering Design Challenge
Design Challenge
You are a team of engineers who have been given the challenge to develop a unique tire tread pattern out of clay that will route over 50% of incoming water to the sides of the tire to prevent hydroplaning. As a team, you’ll need to preserve at least 60% of the “tread” surface so that the tire will be able to grip the road firmly.
Criteria
- Tire tread must route over 50% of incoming water to the sides of the tire.
- Must preserve at least 60% of the tread surface.
Constraints
- Use only the materials provided.
Activity Instructions & Procedures
- Break class into teams of 2-3.
- Hand out the How the Rubber Meets the Road worksheet, as well as some sheets of paper for sketching designs.
- Discuss the topics in the Background Concepts Section. Instruct students to consider the path the water will take, and also how deeply they will need to carve into the clay for their test model. They first draw the design on paper and then transfer it – using a pencil – to a block of clay.
- Review the Engineering Design Process, Design Challenge, Criteria, Constraints and Materials.
- Provide each team with their materials.
- Explain that students must carve or shape a unique tire tread pattern out of clay that will route over 50% of incoming water to the sides of the tire to prevent hydroplaning. In addition, less than 40% of the surface material may be carved away in order to achieve this goal.
- Announce the amount of time they have to design and build (1 hour recommended).
- Use a timer or an on-line stopwatch (count down feature) to ensure you keep on time. (www.online-stopwatch.com/full-screen-stopwatch). Give students regular “time checks” so they stay on task. If they are struggling, ask questions that will lead them to a solution quicker.
- Students meet and develop a plan for their tire tread. Students then carve the tread in the clay using plastic instruments or kid-safe clay carving tools.
For younger students, you may choose to do the carving yourself, or perhaps do this lesson as a joint project with an older class – working together – and have the older students do the carving for the younger ones. - Student teams then present their plan to the class, explaining their predictions for how their design will work. They will present the depth of the new tread and their hypothesis for how efficiently their pattern will whisk water to the sides of the tire to prevent hydroplaning
- All “treads” are then tested by pouring two cups of water through the carved clay. The teacher may decide to do the testing, appoint a team of testers, or allow students to test their own designs. Note, the “tread” should be secured with tape at about a 25 degree angle, which will help make the tests of all teams more consistent. Measure the water collected at the bottom container, as well as the water collected from the right and left side to determine the percentage that was pushed away to the side. Pouring through a spout may assist in making the flow of water at a speed so it doesn’t splash out. Students keep track of the data and measurements on a student worksheet, while the teacher is responsible for pouring the water to ensure fair testing among all teams.
- As a class, discuss the student reflection questions.
- For more content on the topic, see the “Digging Deeper” section.
Optional Extension Activity
- Visit a local tire store as a class and explore the different tire treads and applications. Have the store explain the importance of tire pressure with regard to safety and performance.
- Organize a tracing experience, where either the teacher or adult volunteers trace different tire treads to show in the classroom.
Student Reflection (engineering notebook)
- Did you succeed in creating a “tread” that could route over 50% of incoming water to the sides of the tire to prevent hydroplaning?
- If you did not reach the goal, what would your team have done differently?
- How did your predictions for your tread performance vary from your actual results?
- Did you test your “tread” more than once? If so, how do you think that averaging your test scores impacted your overall results?
- What was the most significant design different of your “tread” as compared to those of the other student teams?
- Describe a feature of another teams’ “tread” that you thought was particularly inventive. Why?
- What impact do you think the depth of the pattern have on your teams’ outcome.
- Do you think you would have been able to complete this project easier if you were working alone? Explain…
- How do you think engineers test tire tread designs in the real world? Consider computers, test driving tracks, and other options. And, also discuss how making a prototype might, or might not, be useful.
Time Modification
The lesson can be done in as little as 1 class period for older students. However, to help students from feeling rushed and to ensure student success (especially for younger students), split the lesson into two periods giving students more time to brainstorm, test ideas and finalize their design. Conduct the testing and debrief in the next class period.
Engineering Design Process
Background Concepts
Why Tread Matters
Tire tread is critical to the safe operation of a car, motorcycle, or bicycle. Engineers design tire tread to achieve a balance between safety, comfort, noise, vibration, and strength. There are many factors to consider in tire design including materials used. In this lesson, we’ll focus closely on the tread design.
Engineers work in teams to come up with design for tread (or the patterns of grooves on the exterior of the tire) that will have top traction. The tires need to hold on to the pavement or road surface in a range of weather and road surface conditions. They need to grip the road as a car turns or comes to a quick stop.
An important aspect of tread design is how the tire pushes water away from the tire so that more of the tire surface is touching the road and not hydroplaning. Hydroplaning is when a layer of water manages to get between the tire and the road — the water can actually push the car off the road leading to loss of control and possible accidents. Some engineers develop tread designs with center channels and v-shaped grooves to flush water out the back and sides of the tire. But the range of shapes and patterns of possible designs are really limitless.
Engineers then use a variety of tools to design and test tire tread design, including computer programs that allow them to virtually carve patterns in the tire and then perform tests in virtual rainstorms or snowstorms. They also ultimately test actual tires in all sorts of real weather conditions.
Testing Tire Tread
For a family car or truck, it is important to check the depth of the tread frequently. Even the best engineered tread design becomes less effective as the tire experiences wear. Tire tread depth measurement tools are an important tool to gauge safety. Some people use a coin for this task. Recently, tire manufacturers have started building in tread wear indicators so consumers can quickly see if they need to replace the tire. These indicators can look like little raised sections (at approximately 1.6 mm or 1/16″) that are found at the bottom on the deepest tire grooves. When these seem to be even with the exterior of the tire, it’s time to get new tires!
Dig Deeper
Internet Connections
Recommended Reading
-
-
- Tire and Wheel Technology (ISBN: 0768003717)
- A Rubber Tire (How It’s Made) (ISBN: 0836862953)
-
Writing Activity
Write an essay or a paragraph about how material science and engineering has impacted tire performance over the last hundred years.
-
Curriculum Alignment
Alignment to Curriculum Frameworks
Note: Lesson plans in this series are aligned to one or more of the following sets of standards:
-
-
- S. Science Education Standards (http://www.nap.edu/catalog.php?record_id=4962)
- S. Next Generation Science Standards (http://www.nextgenscience.org/)
- International Technology Education Association’s Standards for Technological Literacy (http://www.iteea.org/TAA/PDFs/xstnd.pdf)
- S. National Council of Teachers of Mathematics’ Principles and Standards for School Mathematics (http://www.nctm.org/standards/content.aspx?id=16909)
- S. Common Core State Standards for Mathematics (http://www.corestandards.org/Math)
- Computer Science Teachers Association K-12 Computer Science Standards (http://csta.acm.org/Curriculum/sub/K12Standards.html)
-
National Science Education Standards Grades K-4 (ages 4 – 9)
CONTENT STANDARD A: Science as Inquiry
As a result of activities, all students should develop
-
-
- Understanding about scientific inquiry
-
CONTENT STANDARD B: Physical Science
As a result of the activities, all students should develop an understanding of
-
-
- Properties of objects and materials
-
CONTENT STANDARD E: Science and Technology
As a result of activities, all students should develop
-
-
- Abilities of technological design
-
CONTENT STANDARD F: Science in Personal and Social Perspectives
As a result of activities, all students should develop understanding of
-
-
- Science and technology in local challenges
-
CONTENT STANDARD G: History and Nature of Science
As a result of activities, all students should develop understanding of
-
-
- Science as a human endeavor
-
National Science Education Standards Grades 5-8 (ages 10 – 14)
CONTENT STANDARD A: Science as Inquiry
As a result of activities, all students should develop
-
-
- Understandings about scientific inquiry
-
CONTENT STANDARD B: Physical Science
As a result of their activities, all students should develop an understanding of
-
-
- Properties and changes of properties in matter
- Motions and forces
-
CONTENT STANDARD E: Science and Technology
As a result of activities in grades 5-8, all students should develop
-
-
- Abilities of technological design
- Understandings about science and technology
-
CONTENT STANDARD F: Science in Personal and Social Perspectives
As a result of activities, all students should develop understanding of
-
-
- Natural hazards
- Risks and benefits
- Science and technology in society
-
National Science Education Standards Grades 9-12 (ages 14-18)
CONTENT STANDARD A: Science as Inquiry
As a result of activities, all students should develop
-
-
- Abilities necessary to do scientific inquiry
-
CONTENT STANDARD B: Physical Science
As a result of their activities, all students should develop understanding of
-
-
- Motions and forces
- Interactions of energy and matter
-
CONTENT STANDARD E: Science and Technology
As a result of activities, all students should develop
-
-
- Abilities of technological design
- Understandings about science and technology
-
CONTENT STANDARD F: Science in Personal and Social Perspectives
As a result of activities, all students should develop understanding of
-
-
- Science and technology in local, national, and global challenges
-
Next Generation Science Standards Grades 3-5 (Ages 8-11)
Engineering Design
Students who demonstrate understanding can:
-
-
- 3-5-ETS1-1.Define a simple design problem reflecting a need or a want that includes specified criteria for success and constraints on materials, time, or cost.
- 3-5-ETS1-2.Generate and compare multiple possible solutions to a problem based on how well each is likely to meet the criteria and constraints of the problem.
- 3-5-ETS1-3.Plan and carry out fair tests in which variables are controlled and failure points are considered to identify aspects of a model or prototype that can be improved.
-
Next Generation Science Standards Grades 6-8 (Ages 11-14)
Engineering Design
Students who demonstrate understanding can:
-
-
- MS-ETS1-1 Define the criteria and constraints of a design problem with sufficient precision to ensure a successful solution, taking into account relevant scientific principles and potential impacts on people and the natural environment that may limit possible solutions.
- MS-ETS1-2 Evaluate competing design solutions using a systematic process to determine how well they meet the criteria and constraints of the problem.
-
Standards for Technological Literacy – All Ages
The Nature of Technology
-
-
- Standard 3: Students will develop an understanding of the relationships among technologies and the connections between technology and other fields of study.
-
Technology and Society
-
-
- Standard 7: Students will develop an understanding of the influence of technology on history.
-
Principles and Standards for School Mathematics (ages 6 – 18)
Data Analysis and Probability Standards
Instructional programs from prekindergarten through grade 12 should enable all students to:
-
-
- formulate questions that can be addressed with data and collect, organize, and display relevant data to answer them.
- develop and evaluate inferences and predictions that are based on data.
-
Common Core State Standards for School Mathematics Grades 3-14 (ages 8-10)
Measurement and data
-
-
- Solve problems involving measurement and estimation.
- Math.Content.3.MD.A.2Measure and estimate liquid volumes and masses of objects using standard units of grams (g), kilograms (kg), and liters (l).1 Add, subtract, multiply, or divide to solve one-step word problems involving masses or volumes that are given in the same units, e.g., by using drawings (such as a beaker with a measurement scale) to represent the problem.2
- Understand ratio concepts and use ratio reasoning to solve problems.
- Math.Content.6.RP.A.3cFind a percent of a quantity as a rate per 100 (e.g., 30% of a quantity means 30/100 times the quantity); solve problems involving finding the whole, given a part and the percent.
-
Standards for Technological Literacy – All Ages
Design
-
-
- Standard 9: Students will develop an understanding of engineering design.
- Standard 10: Students will develop an understanding of the role of troubleshooting, research and development, invention and innovation, and experimentation in problem solving.
-
Abilities for a Technological World
-
-
- Standard 11: Students will develop abilities to apply the design process.
- Standard 13: Students will develop abilities to assess the impact of products and systems.
-
The Designed World
-
-
- Standard 18: Students will develop an understanding of and be able to select and use transportation technologies.
-
-
Related Engineering Fields and Degrees
Student Worksheet
You are a team of engineers who have been given the challenge to develop a unique tire tread pattern out of clay that will route over 50% of incoming water to the sides of the tire to prevent hydroplaning. As a team, you’ll need to preserve at least 60% of the surface of the “tread” so that the tire will be able to grip the road firmly.
Step 1: Meet as a team and discuss the problem you need to solve. Then develop and agree on a pattern you will use for your tread. You may each want to come up with a simple idea, and then select the best aspects of each design to develop a group pattern. Draw the pattern in the box below, and be sure to indicate not only the shape of the grooves, but also how deep your grooves will be carved into the “tire.”
Step 2: Transfer your team’s design to the clay block using a pencil.
Step 3: Carve your design plan into the clay block provided to you, using plastic utensils or kid-safe clay tools.
Step 4: Use the table below to predict how your tread will perform in the water test.
Predicted average results Amount of water in middle/bottom container %: Amount of water in left container %: Amount of water in right container %: Step 5: As a group, present your engineering teams’ plan to the class. Explain why you chose the patter you did, and explain what you think will happen when you test your design. Be specific and anticipate the percentage of water that will end up flowing to the left and right containers instead of flowing straight through to the bottom container. Also explain how you decided on the depth of the grooves and whether they are a consistent depth throughout the design.
Step 6: Testing time! Your teacher will have set up a testing station for the treads. Your teacher will decide if you will test your own treads, or if a team of “testers” will be appointed to do the work. The testers will pour water through the top of the tire and then you’ll measure and record how much water ended up being pushed to the left or right container as opposed to being gathered in the bottom container. Your tire “tread” will be held using tape at about a 25 degree angle, so the flow of water will be consistent from team to team. Measure the water collected at the bottom container, as well as the water collected from the right and left side to determine the percentage that was pushed away to the side.
Step 7: Mark your results in the box below. You may try your test up to three if you didn’t get the results you wanted on the first try — but you’ll have to average your results. Include both the actual amounts of water gathered and the percentage of all water for each container.
Test 1 Test 2 Test 3 Average of completed tests Amount of water in middle/bottom container Amt: %:
Amt: %:
Amt: %:
%: Amount of water in left container Amt: %:
Amt: %:
Amt: %:
%: Amount of water in right container Amt: %:
Amt: %:
Amt: %:
%: Total water gathered Amt: Amt: Amt:
Step 8: Complete the following evaluation/reflection questions and present your findings to the class.-
-
- Did you succeed in creating a “tread” that could route over 50% of incoming water to the sides of the tire to prevent hydroplaning?
-
-
-
- If you did not reach the goal, what would your team have done differently?
-
-
-
- How did your predictions for your tread performance vary from your actual results?
-
-
-
- Did you test your “tread” more than once? If so, how do you think that averaging your test scores impacted your overall results?
-
-
-
- What was the most significant design different of your “tread” as compared to those of the other student teams?
-
-
-
- Describe a feature of another teams’ “tread” that you thought was particularly inventive. Why?
-
-
-
- What impact do you think the depth of the pattern have on your teams’ outcome.
-
-
-
- Do you think you would have been able to complete this project easier if you were working alone? Explain…
-
-
-
- How do you think engineers test tire tread designs in the real world? Consider computers, test driving tracks, and other options. And, also discuss how making a prototype might, or might not, be useful.
-
-