Most Shared Curriculum

One way to conserve energy in a building is to use adequate insulation to help keep hot or cool air inside or outside of the structure. Inefficient heating and cooling of buildings is a leading residential and industrial source of wasteful energy use. In this activity, student groups conduct a scientific experiment to help an engineering team determine which type of insulation conserves the most energy—a comparison of newspaper, wool, aluminum foil and thin plastic. They learn about different kinds of insulation materials and that insulation prevents the transfer of heat, electricity or sound. Student teams collect data and make calculations, then compare and discuss their results. A student worksheet is provided.

Students design, build, and test mousetrap cars as they apply the Engineering Design Process (EDP) in this individual engineering design challenge. After researching design ideas, students build and test their mousetrap car prototypes (first model). Students then iterate (modify) their design and make any necessary modifications. While students work individually to make their mousetrap cars, they should collaborate with their peers to share information and make suggestions on how to improve and/or fix each other’s initial constructions. Students test their cars in a friendly class Mousetrap Car Competition to determine which car design travels the farthest distance (Note: students can also test which car travels a set distance the fastest).

Students design and build small catapults to launch candy pieces.

In this lesson, students are introduced to the five types of renewable energy resources by engaging in various activities to help them understand the transformation of energy (solar, water and wind) into electricity. Students explore the different roles engineers who work in renewable energy fields have in creating a sustainable environment – an environment that contributes to greater health, happiness and safety.

Students act as structural engineers and learn about forces and load distributions as they follow the steps of the engineering design process to design and build small-scale bridges using wooden tongue depressors and glue. Teams brainstorm ideas that meet the size and material design constraints and create prototype bridges of the most promising solutions. They test their bridges to see how much weight they can hold until they break and then determine which have the highest strength-to-weight ratios. They examine the prototype failures to identify future improvements. This activity is part of a unit in which multiple activities are brought together for an all-day school/multi-school concluding “engineering field day” competition.

Kindergartners measure each others' heights using large building blocks as the unit of measure. For their measurement technique, they tally how many blocks high each student is. Then they display the collected data in bar graphs made from from paper cut-outs of miniature building blocks glued on paper, which helps them see how bar graphs look like the various student heights they observe. Doing this establishes an important foundation for both creating and interpreting graphs in future years, as well as prepares students for the associated activity when they visit a second- and a fourth-grade class to measure those older students' heights. They also measure adults in the school community. Creating bar graphs from this additional data enables students to compare the different age groups to foresee how they may grow taller. Through this introduction to graphing lesson and its associated activity, students develop the concepts and vocabulary to describe, in a non-ambiguous way, how height changes as children age.

Students perform one of the first steps that environmental engineers do to determine water quality—sampling and analysis. Student teams measure the electrical conductivity of four water samples (deionized water, purified water, school tap water and a salt-water solution) using teacher-made LED-conductivity testers and commercially available electrical conductivity meters. They use multimeters to also measure the resistance of the samples. They graph their collected data to see the relationship between the conductivity and resistance. Then, all students measure the conductivity of tap water samples brought to school from their homes; they organize and average their data by sub areas within their local school district to see if house location has any relationship to the water conductivity in their community.

Students continue to explore the story of building a pyramid, learning about the simple machine called a pulley. They learn how a pulley can be used to change the direction of applied forces and move/lift extremely heavy objects, and the powerful mechanical advantages of using a multiple-pulley system. Students perform a simple demonstration to see the mechanical advantage of using a pulley, and they identify modern day engineering applications of pulleys. In a hands-on activity, they see how a pulley can change the direction of a force, the difference between fixed and movable pulleys, and the mechanical advantage gained with multiple / combined pulleys. They also learn the many ways engineers use pulleys for everyday purposes.

Students begin to make sense of the phenomenon of electricity through learning about circuits. Students use the disciplinary core idea of using evidence to construct an explanation as they learn that charge movement through a circuit depends on the resistance and arrangement of the circuit components. Students also explore the disciplinary core ideas and crosscutting concepts of energy and energy transfer in the context of energy from a battery. In one associated hands-on activity, students build and investigate the characteristics of series circuits. In another activity, students design and build flashlights.

In this hands-on activity, students investigate different methods—aeration and filtering—for removing pollutants from water. Working in teams, they design, build and test their own water filters—essentially conducting their own "dirty water projects." A guiding data collection worksheet is provided.

Civil engineers design structures such as buildings, dams, highways and bridges. Student teams explore the field of engineering by making bridges using spaghetti as their primary building material. Then they test their bridges to see how much weight they can carry before breaking.

Students test whether the color of a material affects how much heat it absorbs. They leave ice cubes placed in boxes made of colored paper (one box per color; white, yellow, red and black) in the sun, and predict in which colored box ice cubes melt first. They record the order and time required for the ice cubes to melt.

Working as engineering teams, students design and create model beam bridges using plastic drinking straws and tape as their construction materials. Their goal is to build the strongest bridge with a truss pattern of their own design, while meeting the design criteria and constraints. They experiment with different geometric shapes and determine how shapes affect the strength of materials. Let the competition begin!

Students learn about civil engineers and work through each step of the engineering design process in two mini-activities that prepare them for a culminating challenge to design and build the tallest straw tower possible, given limited time and resources. First they examine the profiles of the tallest 20 towers in the world. Then in the first mini-activity (one-straw tall tower), student pairs each design a way to keep one straw upright with the least amount of tape and fewest additional straws. In the second mini-activity (no "fishing pole"), the pairs determine the most number of straws possible to construct a vertical straw tower before it bends at 45 degrees—resembling a fishing pole shape. Students learn that the taller a structure, the more tendency it has to topple over. In the culminating challenge (tallest straw tower), student pairs apply what they have learned and follow the steps of the engineering design process to create the tallest possible model tower within time, material and building constraints, mirroring the real-world engineering experience of designing solutions within constraints. Three worksheets are provided, for each of two levels, grades K-2 and grades 3-5. The activity scales up to school-wide, district or regional competition scale.

Students investigate how sound travels through string and air. First, they analyze the sound waves with a paper cup attached to a string. Then, they combine the string and cup with a partner to model a string telephone. Finally, they are given a design challenge to redesign the string telephone for distance. They think about their model as it compares a modern telephone and the impact the invention of the telephone has had on society.