Design a 50 Year Energy Plan

What is Our Plan?

Grades:
9-12
Unit:
50 Year Energy Plan
Lesson Number:
6
Description:

With all the pieces in place, this Unit’s final lesson asks students to code a spreadsheet that calculates and mathematically predicts the environmental impacts of different energy sources and strategies over a 50 year timespan. Divided into five...

Energy Content:
Batteries & Storage,
Biomass Energy,
Electrical Grid (Transmission & Distribution),
Hydropower,
Solar Photovoltaic,
Sources of Energy,
Wind Energy
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More Details Less Details
Learning Goal(s):
1. Students utilize their knowledge of energy’s impact on global systems as well as the process of energy generation in order to inform their development of a 50-year Energy Plan divided into decades. 
Pedagogy & Practice:
Engineering Design,
Group Work/Collaboration,
Place-Based Learning,
Project-Based Learning
NGSS Science and Engineering Practices:
5: Using Mathematics and Computational Thinking,
6: Constructing Explanations and Designing Solutions,
7: Engaging in Argument from Evidence
Author:
Bradford Hill
Relevant NGSS PE:
HS-ESS3-2,
HS-ETS1-1,
HS-ETS1-3,
HS-ETS1-4
Other Subjects Covered:
ELA: Writing,
Math: Graphing & Representation,
Social Sciences: Analysis,
Social Sciences: Geography
Estimated Activity Length:
5 hours

Part 2 - Lesson 3: Solar Energy

Grades:
6-12
Unit:
A Community Powered by Renewable Energy
Lesson Number:
6
Description:

Students will work with local government staff or another local energy professional to propose a way to create enough solar power energy to supply the annual energy needs for a real building. Students will be provided with on-site options, and will...

Energy Content:
Electrical Energy,
Electrical Grid (Transmission & Distribution),
Electricity Generation,
Smart Grid,
Solar Photovoltaic
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More Details Less Details
Learning Goal(s):
1.Students will conduct an experiment to determine how electrical output changes as solar panels as the azimuth and tilts are incrementally changed.2.Students will conduct an experiment to determine how electrical output changes as solar panels are shaded.3.Students will work with the staff from your city or town to calculate the amount of potential electrical energy that can be collected from solar panels based upon the location and size of the system.4.Students will use existing solar data to determine the number of solar panels required to power the building in question.
Pedagogy & Practice:
Engineering Design,
Group Work/Collaboration,
Hands-on Materials,
Multiple Learning Styles,
Place-Based Learning,
Project-Based Learning,
Research-Primary
NGSS Science and Engineering Practices:
3: Planning and Carrying Out Investigations,
4: Analyzing and Interpreting Data,
5: Using Mathematics and Computational Thinking,
8: Obtaining, Evaluating, and Communicating Information
Author:
Jonathan Strunin
Relevant NGSS PE:
HS-ETS1-1,
HS-ETS1-2,
HS-ETS1-3,
HS-ETS1-4
Other Subjects Covered:
Math: Geometry,
Math: Graphing & Representation,
Math: Measurement,
Math: Ratios & Proportions,
Social Sciences: Economics
Estimated Activity Length:
6 hours
Car Charger Schematic

Designing a Solar Phone Charger

Grades:
7-12
Unit:
Off the Grid
Lesson Number:
7
Description:

This is the culminating activity for the unit “Off the Grid.” Students will be given some restricted parameters around which to design a solar powered battery operated phone (or other USB device) charger . They will charge the AA battery packs that have...

Energy Content:
Circuitry,
Electrical Energy,
Solar Photovoltaic
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More Details Less Details
Learning Goal(s):
1. Students will be able to design a device that can charge a phone with 4 hours of sun a day. 2. Students will use collected data and be able to support their design – i.e. the data will show that the unit will produce enough energy to charge a phone given it receives 4 hours of sun a day. 3. Students will also be able to calculate efficiency from their power calculations. 4. Students will be able to compare efficiencies of their circuit to others tested in this unit. 5. Students can calculate how much energy 4 hours of sunlight can produce on the solar modules they will use.
Pedagogy & Practice:
Engineering Design
NGSS Science and Engineering Practices:
2: Developing and Using Models,
4: Analyzing and Interpreting Data,
5: Using Mathematics and Computational Thinking,
6: Constructing Explanations and Designing Solutions,
7: Engaging in Argument from Evidence
Author:
Brett McFarland
Relevant NGSS PE:
HS-ETS1-2,
HS-ETS1-3,
HS-PS3-1,
HS-PS3-3
Other Subjects Covered:
Math: Addition, Subtraction, Multiplication, Division,
Math: Measurement
Estimated Activity Length:
5 hours

Part 3 – Lesson 1: A Plan for Renewable Energy Goals

Grades:
6-12
Unit:
A Community Powered by Renewable Energy
Lesson Number:
7
Description:

Students will utilize their home energy audits from Part 1, the information they gathered from the wind and solar assessments in Part 2, and the knowledge they gained from the solar project in Part 2 to devise a plan for your city or town to meet renewable...

Energy Content:
Electrical Energy,
Electrical Grid (Transmission & Distribution),
Solar Photovoltaic,
Sources of Energy,
Wind Energy
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More Details Less Details
Learning Goal(s):
1.Students will utilize previously acquired information about energy needs to create a renewable energy proposal for their city or town.2.Students will perform a solar energy audit on their homes and use class averages to calculate the amount of renewable energy that can be generated on residential properties.3.Students will assess where commercial and local government solar projects can occur within the city or town to meet the energy needs for non-residential consumers.4.Students will determine potential locations for larger scale wind and solar farms to augment the remaining energy needs of the community.5.Students will prepare a comprehensive renewable energy plan that totals the calculations for potential residential, commercial, and agency renewable energy generation.6.Students will prepare a brief PowerPoint presentation that summarizes their comprehensive plans that will be presented to a panel of elected officials or local experts/stakeholders.
Pedagogy & Practice:
21st Century Skills Development,
Engineering Design,
Field Work,
Group Work/Collaboration,
Hands-on Materials,
Multiple Learning Styles,
Phenomena-Driven Instruction,
Place-Based Learning,
Project-Based Learning,
Research-Primary
NGSS Science and Engineering Practices:
1: Asking Questions and Defining Problems,
2: Developing and Using Models,
3: Planning and Carrying Out Investigations,
4: Analyzing and Interpreting Data,
5: Using Mathematics and Computational Thinking,
6: Constructing Explanations and Designing Solutions,
7: Engaging in Argument from Evidence,
8: Obtaining, Evaluating, and Communicating Information
Author:
Jonathan Strunin
Relevant NGSS PE:
MS-ETS1-1,
MS-ETS1-2,
MS-ETS1-3,
MS-ETS1-4,
HS-ESS3-2,
HS-ESS3-4,
HS-ETS1-1,
HS-ETS1-2,
HS-ETS1-3,
HS-ETS1-4
Other Subjects Covered:
Environmental Sciences,
CTE: Career & Technical Education,
Math: Addition, Subtraction, Multiplication, Division,
Math: Geometry,
Math: Ratios & Proportions,
Social Sciences: Civics,
Social Sciences: Geography
Estimated Activity Length:
4 hours

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