This Module, a DEC-recommended resource, offers information on how to set up effective inclusive early childhood classroom environments for young children. It also provides details about the interrelated physical, social, and temporal components of those environments, as well as adaptations to help teachers meet the needs of children with disabilities (est. completion time: 1 hour).

An engineering and design lesson for middle school (our 7th grade standards).

In the aftermath of a natural disaster, can you engineer a device that will keep medicine within a 40-60°F range using natural resources from the biome you live in, and/or debris created by the disaster for three days, until the Red Cross can arrive?

You are a team of relief workers in __________________after a major earthquake/tsunami has occurred. Your team lead as just told you about a young women with diabetes has been injured and needs insulin to be delivered __________ miles away (no open roads). Your team will need to research, design, and build a portable device to keep the insulin between _____ and ______ °(F/C) for _____ days. Once you return you will present the effectiveness of your device to your lead and a team other relief workers showing your both your design/device and explaining the process.

Students learn about factors that engineers take into consideration when designing buildings for earthquake-prone regions. Using online resources and simulations available through the Earthquakes Living Lab, students explore the consequences of subsurface ground type and building height on seismic destruction. Working in pairs, students think like engineers to apply what they have learned to sketches of their own building designs intended to withstand strong-magnitude earthquakes. A worksheet serves as a student guide for the activity.

Students learn about the engineering design process and how it is used to engineer products for everyday use. Students individually brainstorm solutions for sorting coins and draw at least two design ideas. They work in small groups to combine ideas and build a coin sorter using common construction materials such as cardboard, tape, straws and fabric. Students test their coin sorters, make revisions and suggest ways to improve their designs. By designing, building, testing and improving coin sorters, students come to understand how the engineering design process is used to engineer products that benefit society.

Students learn about applied forces as they create pop-up-books the art of paper engineering. They also learn the basic steps of the engineering design process.

Simple machines are devices with few or no moving parts that make work easier. Students are introduced to the six types of simple machines the wedge, wheel and axle, lever, inclined plane, screw, and pulley in the context of the construction of a pyramid, gaining high-level insights into tools that have been used since ancient times and are still in use today. In two hands-on activities, students begin their own pyramid design by performing materials calculations, and evaluating and selecting a construction site. The six simple machines are examined in more depth in subsequent lessons in this unit.

Students learn about the process of reverse engineering and how this technique is used to improve upon technology. Students analyze push-toys and draw diagrams of the predicted mechanisms inside the toys. Then, they disassemble the toys and draw the actual inner mechanisms. By understanding how the push-toys function, students make suggestions for improvement, such as cost effectiveness, improved functionality, ecological friendliness and any additional functionality they determine is an improvement.

In this service-learning engineering project, students follow the steps of the engineering design process to design an assistive eating device for a client. More specifically, they design a prototype device to help a young girl who has a medical condition that restricts the motion of her joints. Her wish is to eat her favorite food, pizza, without getting her nose wet. Students learn about arthrogryposis and how it affects the human body as they act as engineers to find a solution to this open-ended design challenge and build a working prototype. This project works even better if you arrange for a client in your own community.

Students begin by reading Dr. Seuss' "The Lorax" as an example of how overdevelopment can cause long-lasting environmental destruction. Students discuss how to balance the needs of the environment with the needs of human industry. Student teams are asked to serve as natural resource engineers, city planning engineers and civil engineers with the task to replant the nearly destroyed forest and develop a sustainable community design that can co-exist with the re-established natural area.

Students will review their knowledge of tension and focus on tensile loads and failure caused by them.

Students are introduced to the five fundamental loads: compression, tension, shear, bending and torsion. They learn about the different kinds of stress each force exerts on objects.

Students use the engineering design process to solve a real-world problem shoe engineering! Working in small teams, they design, build and test a pair of wearable platform or high-heeled shoes, taking into consideration the stress and strain forces that it will encounter from the shoe wearer. They conclude the activity with a "walk-off" to test the shoe designs and discuss the design process.

This project will be focused on designing, constructing and evaluating different containers to determine the optimal design for heat retention. After students have constructed their designs and collected and shared data, students will evaluate the class data to create an optimal design for our culminating event: warming ooey, gooey chocolate chip cookies to perfection! Through this activity, students will learn about energy transfer, engineering design process, data collection, graphing, rate of change, optimization, surface area and proportions. The students will test the effectiveness of their design using Vernier Probes to gather quantitative data and graphing the rate of temperature change. They will then create a poster presentation to share their data to the class. Students will use their mathematical skills to quantitatively analyze the strength and weaknesses of their designs while enjoying some delicious, toasty, warm cookies.

Working individually or in groups, students explore the concept of stress (compression) through physical experience and math. They discover why it hurts more to poke themselves with mechanical pencil lead than with an eraser. Then they prove why this is so by using the basic equation for stress and applying the concepts to real engineering problems.

This tool has all of the features of jamboard and many MORE.

You will need to sign up to prove you are an educator or student to get a free account.

This works for collaboration, lessons, projects, assignments, etc.

"Figma and FigJam are design and collaboration software used by professional designers, engineers, and makers of all kinds. Use them to ideate, create, and share work—all free, as a student or teacher."

This site will give you a quick run down of how to use Figjam and then it provides 20 great ideas for using Figjam in the classroom - including the templates to get started!

There is even a video to keep it very easy!

Tutorials are linked at the bottom of the site as well.

"APERÇU
Construisez une fleur mécanique qui s'ouvre lorsqu'il y a de la lumière. Cette fleur utilise quelques mouvements mécaniques intéressants dont un câble push-pull pour convertir le mouvement de rotation en un mouvement linéaire pour une tige flexible. Ensuite, le mouvement est reconverti en points de pivotement rotatifs pour ouvrir et fermer les pédales. L'utilisation des clips de reliure signifie également que vous êtes libre de créer vos propres pétales de fleurs.

COMPÉTENCES + OBJECTIFS
Construction

Construire le projet en suivant les instructions d'assemblage
Menuiserie
Principes de base de la menuiserie et quincaillerie
Art + Design
Créer et concevoir vos propres pétales de fleurs
Codage"

"Cette construction est utile de deux manières : propulser des objets et tambouriner sur des surfaces. Le concept global vise à augmenter l'inertie du servo en faisant rapidement claquer le collier de serrage pour faire pivoter le bras. La mécanique de cette construction est modelée d'après une pédale utilisée dans une batterie.

L'aspect de propulsion est simplement amusant. Lancez des pièces de monnaie, des boutons et des balles de ping-pong. Lors de l'utilisation de la fonction d'enregistrement d'animation de l'Animate Shield, des rythmes peuvent être enregistrés et bouclés, y compris le réglage de la vitesse.

COMPÉTENCES + OBJECTIFS
Construction
-Construire le projet en suivant les instructions d'assemblage
Musique
-Animer un rythme
Menuiserie
-Principes de base de la menuiserie et quincaillerie
Codage
-Apprendre à utiliser des retards dans le code pour contrôler le timing du mouvement
& Plus !

** Des kits sont disponibles à l'achat sur makestuffmove.com **"

During this engineering design/build project, students investigate many different solutions to a problem. Their design challenge is to find a way to get school t-shirts up into the stands during home sporting events. They follow the steps of the engineering design process to design and build a usable model, all while keeping costs under budget.