6 item(s) found.
Willow Creek Elementary
The two-story, 108,000 ft2 Willow Creek Elementary School was built in response to increased enrollments at the elementary school level. The school opened for the 2009-2010 academic year and features 44 classrooms, a cafeteria, gymnasium, library, computer labs, art, and music classrooms for an estimated 700 students.
The $22.1 million school was designed by AEM Architects, Inc., which also designed the nearby Tilden Elementary Center in Hamburg, PA with CarbonCast High-Performance Insulated Wall Panels. The Tilden school was completed in 2007.
Willow Creek was built in proximity to other Fleetwood facilities and takes the place of an older block and brick structure. According to AEM project architect Justin H. Istenes, the insulated wall panels were chosen for the school because “precast is built to last. The owners toured High’s Denver plant and the Tilden school while it was under construction, and were satisfied they were getting better value with precast insulated wall panels.”
Hamburg Elementary School (Tilden)
An outstanding thermal performance was achieved at Hamburg Elementary school (Tilden) with CarbonCast walls. Amid skyrocketing energy costs and heightened public awareness of green construction practices, more building owners are seeking environmentally friendly solutions without incurring higher costs.
Tilden Elementary Center in Hamburg, PA, is no exception. The school for kindergarten through fifth-grade students will save on heating and cooling costs with innovative precast high performance insulated wall panels engineered, manufactured, and erected by High Concrete Group.
High Concrete’s 10”-thick precast exterior walls on the 110,000-square foot project delivers R-15 performance. They use three inches of continuous XPS insulation (“ci” as defined in ASHRAE Building Energy Code 90.1-2007) sandwiched between a 4” interior wythe and a 3” exterior wythe. C-GRID carbon fiber shear grid connects the two wythes. With relatively low thermal conductivity, the carbon fiber prevents thermal transfer, virtually eliminating hot and cold spots on the interior wall preserving comfort for students.
High’s precast walls helped keep the project on schedule and under budget, both of which are critical for a public school. The project was completed in June 2008—in plenty of time for teachers to welcome students for the first day of school.
Reading K-12 School
The Reading Community Schools made the decision to combine its three individual schools into one school that would house 15,000 students. The owners worked with an architect to design the school with a traditional look using brick and limestone trim. The architect, Earl Crossland, was able to achieve that look using precast concrete.
Academy of World Languages
The strikingly attractive building features several complementary finishes within each panel. Exposed aggregate provides bold texture and an earthiness that befits the school’s wooded surroundings. A subtle, uniform sandblast finish appears alongside an acid etched treatment that deepens colors for contrast and imparts a stone-like appearance. Horizontal lines of vibrant ruby red tiles below crimson-framed windows add contrast across the façade, while vertical lines of blue tiles almost make the seam between panels an aesthetic feature. Finally, insets of alternating yellow and blue tile provide a visual counterpoint to the exterior light fixtures directly above them. Overall, it’s a colorful, vibrant exterior that reflects the energy and discovery of learning.
Merrill praised the aesthetic versatility of precast. “It allowed us to play with colors and textures, maintaining a simple yet still attractive building,” he said. “We were able to gain economies through repetitive patterning and use scale and massing to keep the building interesting and not overwhelming to the kids.”
The benefits extended to the interior walls as well. The precast sandwich wall panels were prefinished on the inside with paint filler and institutional grade paint. Durable concrete will withstand decades of heavy use and abuse from energetic children. Furthermore, the prefinished interior eliminated the expense and time that a field-constructed interior would have entailed.
Villanova University Pedestrian Bridge
This collegiate pedestrian bridge harmonizes with a collegiate campus that has been around for years. The environment of a college tends to develop around them, causing a need to adapt. Taking something that was, “a necessity and turning it into an asset” was an added benefit to the Architect. Ultimately plastic and versatile, precast concrete helps designers realize their vision even when it’s not the hero in the visual. In this project, harmony, and consistency with the campus aesthetic was a high priority to both the University and the designers. To achieve this goal, the design included a fieldstone veneer to the exterior of the precast bridge following erection except for the architectural panels over the road. The panels over the existing road had the fieldstone applied by the precast manufacturer to the panel prior to being transported to the location. This helps cut down road closure time and boost efficiency.
Ohio State University Chiller Plant
Recent trends in chiller plant design that have been to use eye-catching enclosures, often glass boxes, to allow mechanical systems to be visible from outside. However, this presents the problem of cooling the chiller plant. At Ohio State University in Columbus, Ohio, a new ten-story plant uses precast concrete panels with a series of openings that allow a view inside, while keeping the interior temperature consistent and the energy use regulated.
The plant building is more than just a concrete box with openings, however. Conceived as a “House for Energy,” the envelope showcases the energy-efficient chiller equipment inside and records the sun’s energy on the exterior.
The LEED Silver Certified building features a high-polish finish and “fins” of diachronic glass that cast colored light rays across the concrete surface. The result is a dynamic façade that changes with the time of day, season, and location of the observer.
The chiller housed at the new plant facility provides chilled water production and distribution to the medical center area of the campus. The plant encloses the equipment used to maintain 12,500 tons of chilled water, with a plan to increase that capacity to 30,000 tons. Emergency power installed at the plant increases the reliability of the water production and distribution in the event of a power outage.