www.TeachEngineering.org: Free Curriculum for K-12

Contributed by: Integrated Teaching and Learning Program, College of Engineering, University of Colorado at Boulder

Colorado Math
- a. Use flexible and efficient methods of computing including standard algorithms to solve three- or four-digit by one-digit multiplication or division problems (Grade 4) [2009]
- f. Select an appropriate tool and unit for measuring length, weight, and capacity (Grade 4) [2009]
Colorado Science
- a. Identify and describe the variety of energy sources (Grade 4) [2009]
- d. Use multiple resources - including print, electronic, and human - to locate information about different sources of renewable and nonrenewable energy (Grade 4) [2009]
International Technology Education Association-ITEA STL Standards Technology
- D. Follow step-by-step directions to assemble a product. (Grades 3 - 5) [2000]
- C. Energy comes in different forms. (Grades 3 - 5) [2000]

Does this curriculum meet my state's standards?

Each group needs:

1 empty, clean two-liter plastic soda bottle (ask students to bring from home or collect from recycling center)
1 pair of scissors
tape
6-8 large index cards (4 x 6-inch size works)
pen or marker
wooden dowel, ~¾-inch (2 cm) diameter (to fit into the bottle opening with a little room to turn) and longer than the length of the soda bottle; dowel can be re-used (Alternative: If large-enough dowels are not available, use smaller dowels and drill holes into the bottle cap big enough to accept the dowel and allow it to spin.)
timer, clock or watch (to count seconds elapsed)
string

For the entire class to share:

Source of water
Pouring container (to hold ~ 2 liters water)
Sink (or outside area that can get wet)

dam:	A barrier constructed across a waterway to control the flow or raise the level of water.
design:	To plan out in systematic, often graphic form. To create for a particular purpose or effect. For example, to design a power plant.
energy:	The ability to do work.
engineering design:	The process of devising a system, component or process to meet desired needs. (Source: ABET)
hydropower:	Generating power from the movement of water. Also called hydroelectric power.
hydroelectric power plant:	A power plant that uses water turbines to generate electricity.
hydroelectricity:	Electricity produced by the energy of moving water.
kinetic energy:	The energy of motion. For example, a spinning top, a falling object and a rolling ball all have kinetic energy.
mechanical energy:	Energy that can be used to do work. It is the sum of an object's kinetic and potential energy.
model:	A small object, usually built to scale, that represents another, often larger object.
power plant:	A complex of structures, machinery, and associated equipment for generating electric energy.
potential energy:	Potential energy is the energy stored by an object as a result of its position. For example, a roller coaster at the top of a hill, or water being held behind a dam.
prototype:	A first attempt or early model of a new product or creation. May be revised many times in the process of testing and refining.
renewable energy:	Energy made from sources that can be regenerated. Sources include solar, wind, geothermal, biomass, ocean and hydro (water).
reservoir:	A natural or artificial pond or lake used for the storage and regulation of water.
rotational rate:	How fast something turns. A measure of speed indicated by the number of turns that take place during a period of time. For example, 100 revolutions per minute.
turbine:	A machine in which the kinetic energy of a moving fluid is converted into mechanical energy by causing a series of buckets, paddles or blades on a rotor to rotate.
waterwheel:	A wheel that rotates by direct action of water; used to generate power or do work. The wheel often includes buckets, paddles or blades to catch the water. A simple turbine.

Waterwheel Worksheet

Pre-Activity Assessment

Exploratory Discussion: As a class, discuss the following topics:

Define hydropower as a class. (Answer: Power from the movement of water.)
Describe how hydropower is used in everyday life.
Discuss the advantages of using renewable energy sources.

Voting: To warm up the class, ask the following true/false questions and have students vote by holding thumbs up for true and thumbs down for false. Tally the votes and write the totals on the board. Give the right answer.

True or False: Hydropower dams reduce the production of pollution. (Answer: True)
True or False: Hydropower dams are inexpensive to build. (Answer: False. They can be very expensive to build.)
True or False: Hydropower dams do not interfere with natural wildlife. (Answer: False. Dams can disrupt migratory fish patterns and spawning habits, especially for species like salmon. This can have devastating effects on both the fish population and people whose livelihoods depend on these fish. Change in water levels can also fatally affect other wildlife and plants.)

Activity-Embedded Assessment

Question/Answer: Ask the students how waterwheels (hydromills) and windmills are similar (Answer: Both have "vanes" and a turbine shaft, and both generate renewable energy.)

Design Decisions: As a class, design the parameters for your experiment, including determining standard methods to ensure experimental consistency in the following:

How to count the rotations (turns) of the waterwheel
How to keep the flow rate of the water onto the waterwheel constant

Worksheet: Have the student teams record measurements, calculate averages and answer questions on the worksheet. Review their answers to gauge their mastery of the subject.

Post-Activity Assessment

Concluding Discussion: Ask the students and discuss as a class:

What happened to the waterwheel as you poured water on it?
What patterns do we see in the results? Why do teams have different average rates of rotation? What conclusions can we draw?
To improve your waterwheel, how might you re-design your water catchers to work better?
What happened to the rate of rotation when we added weight?
How would engineers use this understanding to design hydroelectric power plants? (Answer: Engineers would learn about the different paddle or blade designs to see how well they moved the weight. The better the blade design, the faster the waterwheel turned and moved the weight upwards. They would use this information to design a turbine that generated the most electricity from the turning wheel.)
How might we have altered the experiment or our methods to make a better experiment?

Engineering Design Project: Divide the class into groups and inform them that they are engineering teams working for H₂O Solutions, an engineering design company that specializes in waterwheels and water energy. The city has asked them to use what they have learned in this activity to design a more efficient waterwheel. Tell the teams that they can include whatever resources (e.g., time, materials) that they want in their design. Ask them to sketch their new design. Have teams present their designs to the rest of the class.

Ask students to describe, in general terms, how hydropower works. They can use information from the demonstration/activity to support their ideas.
Ask the students to brainstorm how they think they could make their waterwheel more efficient if they had additional resources (materials, time).
Among all teams, ask students to decide which new design is the best and why?

Engineering Application: Have students reflect on the following engineering applications for hydropower. This assignment is suitable for a class discussion or a journal entry.

To use a river or stream for hydropower, what type of river conditions do engineers require? (Answer: It must be fast-moving water.)
What are some reasons why engineers construct hydroelectric power plants? (Possible answers: To produce electricity. To make use of a renewable energy source [water]. To produce electricity without polluting or producing greenhouse gases.)
Why do engineers construct dams for large hydroelectric power systems? (Answer: The dam holds a great deal of water in one place to supply the kinetic energy required to turn the turbine blades.)
How was the waterwheel you made similar to what happens in a hydroelectric power plant? (Answer: Water dropped from a container to spin the blades just like water runs from a dam to spin the blades of a turbine. The spinning waterwheel was used to do work just like the spinning blades of turbines make electricity, which we use to do work.)

Re-Design Practice: Have the students list on their worksheet any design or fabrication changes they would make to their waterwheel to make it work better.

For lower grades, conduct this activity as a class demonstration, or build the waterwheel as a class project.
For lower grades, it may be too much to ask students to calculate the rate of rotation. If so, just have them measure time and rotations, and discuss what happens when you add weight on the string.
For upper grades, have students compile all the data from the teams and calculate class averages, and the range, median and mode for the various composite sets of data.
For more advanced students, have them evaluate the waterwheel as an energy source. They could measure the amount of water required to turn the waterwheel a certain number of turns with a gram load. Place a large bucket under the waterwheel to capture the water. See how many turns it takes to lift an object a given distance by turning the string around the bottle of the neck. Finally, compare this idea to real energy costs. (The percent efficiency can be calculated by dividing the weight of the object by the weight of the water required to raise the object the same distance the water fell — about one foot — then multiply the result by 100.)
For more advanced students, have them explore different waterwheel variables, such as the type, shape and material of the turbine, number and position of fins on the turbine, etc.