Brought to you with support from
Over sixty years ago the original Wilshire Grand Hotel opened as the Hotel Statler, thanks to the City of Los Angeles, which issued the largest single building permit in their history for the construction of the $15 million project. That landmark legacy continues today, as the new 1,100-foot-tall Wilshire Grand tower lays claim to being the tallest building in Los Angeles, the tallest building in California, and the tallest building west of the Mississippi River.
- Facade Manufacturer
StandardVision (facade lighting); C.R. Laurence (glass entrance systems supplier); Viracon (cladding); Schuff Steel (structural steel); Conco (concrete) - Architects
AC Martin - Facade Installer
Turner Construction (general contractor) - Facade Consultants
Benson Industries (facade consultant); Heitmann & Associates, Inc. (facade consultant); Thornton Tomasetti (structural engineering); Brandow & Johnston (engineer of record); Glumac (MEP Engineer) - Location
Los Angeles, CA - Date of Completion
2017 - System
curtain wall, with integrated LED - Products
custom LED
The tower formally breaks from a 1974 ordinance requiring towers to have flat roofs for helicopter rescue in the event of fire. A tapered form was permitted due to advances in fire safety and building technology, such as a reinforced concrete central core that exceeds the city’s current fire code.
The facade features a fully integrated, centrally controlled experiential LED lighting developed by StandardVision. The linear fixtures were custom made per floor, and installed throughout each of the tower’s 73 floors. One centrally controlled system ties the entire system together. This allows possibility for the facade for incorporate full motion video, artwork, accent lighting, and brand signage as desired.
All linear accent lighting was integrated into the glazing panels, and the fixtures were pre-installed in the facade contractor’s shop prior to site delivery. This unitized approach minimized staging time on-site and allowed for a smooth installation workflow. Joshua Van Blankenship, vice president of media platforms for StandardVision, said this was one of the biggest challenges of the project. Another technical challenge was to ensure lighting occurred seamlessly despite traveling over expansion joints in the facade and encountering over 200 parametrically controlled panel widths.
“Resolving these two factors with Benson [the facade contractor] allowed us to save tens of thousands of man-hours in exterior installation, and focus our budget on providing the technology solution the architect wanted without a single SV change order,” he said.
Penetrations through the building envelope were reduced to a singular point per floor level. A small kick plate access hatch offers accessibility from the interior. This utility space houses LED drivers for the fixtures and wiring for the system. The detailing and design coordination of this moment in the facade went through rigorous proof of concept water-testing to ensure performance. Van Blankenship credits a close design-build relationship between documentation and fabrication teams at Benson and StandardVision for the success of the integrated lighting system.
“Our designers in L.A. were regularly working these shifted-hours to have time to overlap with Benson’s Singapore team, and by the end of the process, we were incredibly efficient in defining how our respective scopes were going to relate.” he said. “Throughout this entire process AC Martin, Turner and Rosendin (the electrical contractors) were great partners in helping to make this hybrid system work.”
Wilshire Grand’s lighting system highlights a robust curtainwall system that was optimized for California’s seismic loads and solar gain. Thornton Tomasetti developed a parametric facade panelization model that consolidated and synchronized information in required for architectural documentation and specialty construction. Concurrently, Glumac developed energy models and shading studies throughout the design process to study building envelope performance. The models take into account shade from DTLA’s surrounding context cast onto the tower, proposing a series of varied fin depths along the south facade. This level of study saved curtain wall material while maximizing the shading potential of the building envelope. California’s Title 24 energy code limits glazing to 40 percent window-to-wall ratio (WWR), but with these advanced parametric modeling and analysis tools, the design teams were able to demonstrate a larger WWR of 50 percent could still outperform California code baseline through careful specification of glazing material, insulation values, and shading schemes.
