Missraquel -

| Resource | Estimated Capacity | Annual Generation (MWh) | % of Town’s Demand | |----------|-------------------|--------------------------|--------------------| | Solar PV (rooftop) | 2 MW | 2,400 | 25 % | | Community Solar Farm | 3 MW | 3,600 | 38 % | | Wind Turbines | 1 MW | 2,600 | 27 % | | Battery Storage | 2 MWh | — | — | | Existing Grid (coal) | 1 MW | 1,200 | 10 % |

A student raised her hand. “Photons hit the silicon, knocking electrons loose, creating a current,” she replied. missraquel

Miss Raquel’s story spread to neighboring towns, inspiring a regional network of teachers, students, and civic leaders. They shared data, pooled resources, and built a that could balance supply and demand across county lines. The ripple effect showed that an informative story—grounded in science, community, and hope—can indeed power real change. | Resource | Estimated Capacity | Annual Generation

Using the anemometer, they recorded an average wind speed of 7 m/s on the hill—well above the cut‑in speed. Miss Raquel sketched a possible 500 kW turbine design, estimating that a cluster of three could supply roughly 1 MW of power, enough for about 800 homes. The town’s biggest hurdle was intermittency: solar doesn’t work at night, wind can be calm. Miss Raquel introduced the concept of energy storage, focusing on lithium‑ion batteries and emerging technologies like flow batteries. They shared data, pooled resources, and built a

“Wind energy works on a simple principle,” she said, “the kinetic energy of moving air turns blades, which spin a shaft connected to a generator. The generator converts mechanical energy into electricity, usually three‑phase AC.”

Mayor Patel asked, “What about cost?”