Playground Design Teacher Guide

Unit

Playground Design

Subject

Engineering

Grade Level

ES 3-4

Activity Name(s)

Building a Bungee Jump

Building a Zip Line

Being Prepared

Both activities can be done individually, though at this age, working with a partner or small group will be more beneficial in nurturing collaboration, communication, and cooperation. Additionally, having a team to share ideas and jobs (such as holding sensors, releasing eggs, clicking the start and stop buttons on the graphs) makes things run more smoothly during the activities. At the 3rd and 4th grade level, it would be helpful to guide the groups in assigning team jobs so that everyone has ownership and responsibility in the activity, and so that the guidelines and expectations for behavior, respect, and participation are made clear for everyone in the group.

Before either activity, be sure to pre-teach the students about the sensors, proper use and care of them, and how to read the measurements and graphs produced. If the measurements and data are too confusing, then the activity will be overwhelming and somewhat meaningless to them. (And will require too much on-the-spot teaching during the activity from the teacher, which will not allow the students to be directing the discovery and investigation.)

Some students may be allergic to eggs! Plastic eggs filled with clay can be used as a substitution in both activities!

Materials Needed

 

Getting Started

Prior to the bungee activity, the teacher may want to attach a force sensor to a meter stick to show students how they should do this properly (as an example). Better yet, since these sensors are delicate and expensive, the teacher might want to attach the sensors to the meter sticks for the students already in order to avoid them not being properly secured, since the sensors will then be dangled upside-down and have heavy eggs dropped from them. A poorly attached sensor might come off the meter stick and fall to the ground.

The first part of the zip line activity goes through the steps of setting up the motion sensor so that the egg is "big" enough for the sensor to see. If students have never used a motion sensor before, these numerous steps might be confusing. The teacher might want to go through this portion of the activity as a whole class, or perhaps go through this part of the activity as a "preview" the day before. The direction and pictures are very clear, but when students are excited to get started with an activity or experiment, they might accidentally "zip" through this part of the set up, which will cause greater confusion and unreadable results and graphs later.

Make sure to closely monitor students during the use of both sensors. They are delicate and expensive! The measurements and graphs can be confusing to students, and this is the most important part of the activity, so it is vital that they find it meaningful. Point out the patterns, the peaks, the inclines, and other trends.

What Students Need to Know:

Students need an operational definition of "force". At this age, students commonly believe that "force" is a property of an object. By now, they should understand that pushes or pulls can change the motion of an object. But they may not understand speeding up or slowing down happens because a force is exerted on an object. To keep it simple, you can avoid the word "acceleration" by defining force in this way:  A force is a push or pull upon an object that causes a change in motion of the object. In these two activities, students will explore systems where multiple forces are acting on an object (gravity, friction, tension, spring force). By 5th grade, you can introduce the idea that some forces cancel each other out, so there is zero net force on the object. This concept is probably too sophisticated for students in Grades 3-4, however. 

Suggested Timeline

Bungee

You should allow two hours for the activity itself, with additional time for any pre-teaching of necessary science concepts or sensor usage.

Zip Line

You should allow two hours for the activity itself, with additional time for any pre-teaching of necessary science concepts or sensor usage/set-up.

Additional time to allow for student problem solving and collaboration, and time for them to redesign, rebuild, and reflect on their results.

Thinking about the Discovery Questions

This unit is motivated by the discovery questions:

These two lessons address the concepts of momentum, gravity, friction/resistance, force/motion (push/pull as a force), inertia of objects in relation to their mass.

With regards to teaching this unit teachers may think they need to give all directions and not let kids work it out (such as telling them how tight to make their zip line, how steady to hold the sensor, to be sure one fixed point of the zip is higher than the other, etc.). It is important that students are allowed to work out design problems with the teacher asking directed questions that may help the student focus on the design process and the concepts involved.

Misconceptions

Misconceptions about force and motion center around some critical understandings. Students at this grade level tend to think of force as a property of an object (i.e., "An object has force). It helps if they have a simple operational definition of "force", such as "A force is a push or pull on an object that causes a change in the motion of the object." In addition, research shows that students often hold the erroneous belief that a force acts only in the direction of motion. This activity provides an ideal opportunity to talk about opposing forces acting on the dropped egg and on the zip line rider. Students may confuse inertia with speed. They may think a school bus has less inertia because it is harder to move, but more mass actually means more inertia. At the same time they may believe that heavy things will be slow and light things will be fast. A misconception related to friction relates to the importance of friction in everyday activities. Students commonly believe that objects resist acceleration from their state of rest because of friction -- that is, they confound inertia with friction. Friction is a force --  without it we couldn't change direction or stop. Last, kids may believe that designing playground toys and equipment is nothing but fun & games. While playground designers DO have fun, they also pay close attention to safety. If someone makes the choice to jump off a swing-set and gets hurt, that is using the equipment inappropriately. However, if the swing-set was built poorly it could break or tangle someone in it. If a child who is properly using the equipment gets hurt, the designer is responsible for that injury. Play equipment such as a bungee jump/harness system allows a person to experience a thrill of leaping much higher or falling longer distances than would otherwise be possible using the elastic bungee cord to stretch and pull the rider safely along their thrilling ride. If that equipment were to fail, a very serious injury could result.

Learning Objectives

NGSS

NSES

Discussion: Setting the Stage

Discussion: Formative Questions

Bungee Jump

Zip Line

Discussion: Wrapping Up

Additional Background

Friction is a force that acts on objects, slows down motion, and causes inefficiency. The zip line the students created, in order to operate smoothly, would need to overcome most of its friction. Force is a push or a pull, and many forces are acting on you all of the time. Usually you don't even realize that the force of gravity is acting on you, but it is, all of the time. If you are falling, it's pretty obvious that something is pulling you down but even if you are standing on the floor, perfectly still, the force of gravity is still pulling you down. And the really hard thing to understand is, if you are standing perfectly still on the floor, the floor is pushing up on you just as hard as gravity is pulling you down! Gravity is always pulling a load (such as the the egg) toward the center of the Earth. Each successive bounce of the rubber band bungee will have less height because the rubber band's elasticity is absorbing some of the egg's inertia and force.

Content Support for Teachers:  

For a refresher on forces, try The Physics Classroom free interactive online tutorials. This link takes you to "The Meaning of Force", a good overview of forces acting at a distance (such as gravity) and contact forces (such as friction, tension, spring force, and applied force.)  www.physicsclassroom.com/class/newtlaws/Lesson-2/Types-of-Forces

Analysis

Zip Line

  1. Is there a push and pull on the egg to make it move?

    Yes, the force of gravity. Teachers: As the rider continues down the zip line, a combination of resistive forces act to slow the rider down. The most significant of these resistive forces is friction. The rider also experiences air resistance. In addition, there is a tension force between the harness and the object that holds it to the line. 

  2. In testing your zip line, were any of your eggs cracked or broken? Why?

    Answers will vary, breaks may be due to poorly built harnesses, improperly held ends of the zip line, a zip lime that was too steep or too taught causing it to move too fast at the final impact.

  3. When your zip line worked the best, what did the position graph look like?

    Answers will very, but should include a description of the slope of the line, for example the graphed line was not steeply sloped and moved up and down just a little.

Bungee

  1. Describe the pattern on the graph.

    The graph of the first bounce should show the greatest force, with each subsequent bounce measuring less and less force, until the the egg comes to a still position.

  2. At what point in the ride does the egg feel the most force? A. When it reachers the lowest point of the first drop and is initially yanked back up in the opposite direction by the elasticity of the rubber band bungee to its highest rebound point. Q: In testing your egg bungee jump, were any of your eggs cracked or broken? Why?

    Answers will vary. Possible responses may include breaks do to poorly built harnesses, improper attachment of the harness to the bungee, a bungee that was too long causing it to hit the ground, or improper set up of the meter stick/chair/ sensor, causing the set up to jiggle or bounce during testing.

Further Investigation

Bungee

Students are going to need a safe way to build a bungee up to the ceiling. The teacher's assistance will definitely be needed. If the school has a stairwell that would work for this, that would be excellent. An engineering and problem solving opportunity arises in considering the length of the cord before and during the jump given the weight of the egg or eggs in the harness, the additional forces present with the higher drop, and any reinforcing needed to where the harness attaches to the bungee. Again, the teacher may want to ensure the sensor to properly used and protected, as dropped from this increased height will certainly damage or destroy it. Plastic eggs filled with clay may be preferable for this Further Investigation, unless numerous additional eggs are made available for trial and error purposes.

Zip Line

If numerous groups are working on the Further Investigation activity simultaneously, it may be appropriate to to coordinate their zip line courses so they do not intersect or tangle. If students have correctly figured out the correct "tightness" of a good zip line, and then have their longer zip lines use a similar dip at the end, then their eggs should not impact the end point with such great force as to crack or break the eggs (especially if their harnesses are still properly build!). It bears repeating, that if the teacher has opted to embrace the true engineering and design model, to involve student problem solving and collaboration, an an entire additional day to redesign, rebuild, and reflect is suggested.

A Further Investigation for these physical concepts, as well as the engineering concepts, covered in this unit could also extend to roller coasters. The teacher might want to consider using a simulation, such as the Energy Skate Park: http://phet.colorado.edu/en/contributions/view/3083