A solar ready building is engineered and designed for solar installation, even if the solar installation does not happen at the time of construction. The solar ready design features, if considered early in the design process, are typically low or no cost. Attention to building orientation, available roof space, roof type, and other features is key to designing solar ready buildings.
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This presentation offers strategies for commissioning and ongoing comissioning of zero energy buildings.
A detailed two page case study on the Zero Energy Ready Turkey Foot Middle School.
"Turkey Foot is revolutionizing the way kids learn, all within a new building that uses half the energy of the previous school despite being twice the size. Turkey Foot leveraged the practices and experience on other high performance goals in the District."
A detailed two page case study on the Zero Energy Ready Redding School of the Arts in Redding, CA.
"In 2011, the charter school opened a new facility with an ambitious goal of zero net energy, while dedicating only 2% of the budget to renewable energy systems."
This case study describes a successful zero energy school project in Utah.
This case study details the successful achievement of Passive House performance and zero energy at the Friends School of Portland.
The Energy Lab at Hawai’i Preparatory Academy is the third building worldwide and the first K–12 school facility to achieve “Living” certification through the Living Building Challenge (LBC). This case study details how the project succeeded in these goals.
The Hood River Middle School Music and Science Building includes music and science classroom, music practice rooms, teacher offices, a greenhouse, an adjacent recycling and storage building, and outdoor spaces including an amphitheater and garden. The building is integrated with the school's progressive sustainability and permaculture curriculum. Students can track and create experiments using data from the buildings net zero energy system and rainwater harvesting system, and learn about the building's innovative and integrated use of materials and systems.
On the night of May 4, 2007 an EF5 tornado 1.7 miles wide ravaged Greensburg, Kansas, destroying 95% of the city's homes and businesses. In the wake of the disaster, it became apparent that changes would need to occur to sustain the town for future generations. The Greensburg School District selected BNIM Architects to provide comprehensive design services for new school facilities.
In direct alignment with the town's Sustainable Comprehensive Master Plan, the USD decided to rebuild to LEED Platinum. This decision led the way for the city, which later mandated that all public buildings attain a Platinum rating. This K–12 facility combines the resources of three rural community school districts into a single facility, thereby right-sizing at a regional scale.
This 150,000 SF, LEED Gold, Net Zero facility was built on a 17.5 acre site in the city of Irving, Texas. Project cost was $29,610,423, and construction commenced on May 14, 2010. The project opened its doors for school on August 24, 2011. The building is structural steel frame with a brick and metal panel veneer. There are large expanses of windows for daylight harvesting. There are two stories consisting of classrooms, library, cafeteria, auditorium, and gymnasium. The structure fits on a very tight site with building orientation critical to energy conservation; native landscaping and pervious paving round out the exterior. The school uses extensive shading to minimize solar heat gain and incorporates wind turbines as a part of its onsite renewable energy generation portfolio.