An interactive k-12 engineering curriculum development on renewable sources and energy storage and in power systems

Jana Sebestik, Quanyan Zhu

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

The success of modernizing the U.S. electrical grid depends on research, engineering, and policy, but also, on the education and acceptance of electricity consumers. In this paper we introduce K-12 power engineering education curriculum material that focuses the benefits and challenges that come with integrating renewable resources and the impact of energy storage technology. The curriculum aims to provide information about current and future electricity generation and delivery systems and to engage students who may pursue careers in related industries. An interactive Java applet (see Fig. 1) and related lessons allow students to explore effects on the power system as communities demand more power and wind generation is added or increased. They can also investigate how the availability of large-scale energy storage allows for the efficient use of intermittent energy sources like wind and solar. The simulation helps students understand some of the complexities of the power grid of the future. The lessons allow students to compare residential, commercial and industrial demand and to consider how past behaviors allow power professionals to predict future use. Students can consider wind variability, transmission needs, system costs and CO2 emissions, and how the availability of energy storage may impact the system. The course materials have been used successfully in classrooms and in community events throughout the nation. During the past year, there were over 24,000 visits to the websites associated with the curriculum. Teachers from several states have adopted the materials for their classes. Power utilities and environmental groups are also interested in our materials for customer education. The materials are available from the project website.2 This paper provides examples of the materials and discusses the major engineering concepts associated with them. We also discuss our continuing efforts to disseminate these materials to educators around the world and outline future plans for further development and dissemination.

Original languageEnglish (US)
Title of host publication119th ASEE Annual Conference and Exposition
PublisherAmerican Society for Engineering Education
ISBN (Print)9780878232413
StatePublished - 2012
Event119th ASEE Annual Conference and Exposition - San Antonio, TX, United States
Duration: Jun 10 2012Jun 13 2012

Other

Other119th ASEE Annual Conference and Exposition
CountryUnited States
CitySan Antonio, TX
Period6/10/126/13/12

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Curricula
Energy storage
Students
Electricity
Education
Availability
Engineering research
Engineering education
Websites
Costs
Industry

ASJC Scopus subject areas

  • Engineering(all)

Cite this

Sebestik, J., & Zhu, Q. (2012). An interactive k-12 engineering curriculum development on renewable sources and energy storage and in power systems. In 119th ASEE Annual Conference and Exposition American Society for Engineering Education.

An interactive k-12 engineering curriculum development on renewable sources and energy storage and in power systems. / Sebestik, Jana; Zhu, Quanyan.

119th ASEE Annual Conference and Exposition. American Society for Engineering Education, 2012.

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Sebestik, J & Zhu, Q 2012, An interactive k-12 engineering curriculum development on renewable sources and energy storage and in power systems. in 119th ASEE Annual Conference and Exposition. American Society for Engineering Education, 119th ASEE Annual Conference and Exposition, San Antonio, TX, United States, 6/10/12.
Sebestik J, Zhu Q. An interactive k-12 engineering curriculum development on renewable sources and energy storage and in power systems. In 119th ASEE Annual Conference and Exposition. American Society for Engineering Education. 2012
Sebestik, Jana ; Zhu, Quanyan. / An interactive k-12 engineering curriculum development on renewable sources and energy storage and in power systems. 119th ASEE Annual Conference and Exposition. American Society for Engineering Education, 2012.
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